{{#Wiki_filter:ATTACHMENT A REVISE APPENDIX A TECHNICAL SPECIFICATIONS BY REMOVING THE PAGES IDENTIFIED BELOW AND INSERTING THE ENCLOSED PAGES.REMOVE INSERT 3.3.3.1-5 3.14-1 3.14-2 3.14-3 3.14-4 3.14-5 3.14-6 3.14-7 3.14-8 3.14-9 3.14-10 4.15-1 4.15-2 4.15-3, 4.15-4 4.15-5 6.2-3 6.5-4 L J.1-5 3.14-1 4.15-1 6.2-3 6.5-4 9204290437 92042i PDR ADOCK 05000244 P PDR

TABLE OF CONTENTS PAGE 2.0 3.0 DEFINITIONS SAFETY LIMITS AND LIMITING SAFETY SYSTEM SETTINGS 2.1 Safety Limit, Reactor Core 2.2 Safety Limit, Reactor Coolant System Pressure 2.3 Limiting Safety System Settings, Protective Instrumentation LIMITING CONDITIONS FOR OPERATION 2~1 1 2~1 1 2~2 1 2~3 1 3.0 3.1 3.2 3.3 3.4 3.5 3.6 3.7 3.8 3.9 3.10 3.11 3.12 3.13 3.14 3.15 3.16 Applicability Reactor Coolant System 3.1.1 Operational Components 3.1.2 Heatup and Cooldown 3.1.3-Minimum Conditions for Criticality 3.1.4 Maximum Coolant Activity 3.1.5 Leakage 3.1.6 Maximum Reactor Coolant Oxygen, Fluoride, and.Chloride Concentration Chemical and Volume Control System Emergency Core Cooling System, Auxiliary Cooling Systems, Air Recirculation Fan Coolers, Containment Spray and Charcoal Filters Turbine Cycle Instrumentation System Containment System Auxiliary Electrical Systems Refueling Plant Effluents Control Rod and Power Distribution Limits Fuel Handling in the Auxiliary Building Movable In-Core Instrumentation Shock Suppressors (Snubbers)

Deleted Overpressure Protection System Radiological Environmental Monitoring 3.0-1 3~1 1 3~1 1 3.1-5 3.1-19 3~1 21 3.1-25 3~1 3 1 3~2 1 3~3 1 3.4-1 3.5-1 3.6-1 3~7 1 3.8-1 3.9-1 3.10-1 3~1 1 1 3~1 2 1 3 a 1 3 1 3.14-1 3.15-1 3.16-1 4.0 SURVEILLANCE REQUIREMENTS 4.1 4.2 4.3 4'4.5 4.6 4.7 Operational Safety Review Inservice Inspection Reactor Coolant: System Containment Tests Safety Injection, Containment Spray and Iodine Removal Systems Tests Emergency Power System Periodic Tests Main Steam Stop Valves 4.1-1 4.2-1 4.3-1 4.4-1 4.5-1 4.6-1 4.7-1 Amendment No.Proposed TABLE OF CONTENTS (CONT'D)4.8 4.9 4.10 4.11 4.12 4.13 4.14 4.15 4.16 Auxiliary Feedwater System Reactivity Anomalies Environmental Radiation Survey Refueling Effluent Surveillance Radioactive Material Source Leakage Test Shock Suppressors (Snubbers)

Deleted Overpressure Protection System PAGE 4.8-1 4.9-1 4.10-1 4.11-1 4.12-1 4.13-1 4.14-1 4.15-1 f 4.16-1 5.0 6.0 DESIGN FEATURES 5.1 Site 5.2 Containment Design Features 5.3 Reactor Design Features 5.4 Fuel Storage 5.5 Waste Treatment Systems ADMINISTRATIVE CONTROLS 5.1-1 5.2-1 5.3-1 5.4-1 5.5-1 6.1 6.2 6.3 6.4 6.5 6.6 6.7 6.8 6.9 6.10 6.11 6.12 6.13 6.14 6.15 6.16 6.17 Responsibility Organization 6.2.1 Onsite and Offsite Organization 6.2.2 Facility Staff Station Staff Qualification Training Review and Audit 6.5.1 Plant Operation Review Committee (PORC)6.5.2 Nuclear Safety Audit and Review Board.(NSARB)5.5.3 Quality Assurance Group Reportable Event Action Safety Limit Violation Procedures Reporting Requirements 6.9.1 Routine Reports 6.9.2 Unique Reporting Requirements Record, Retention Radiation Protection Program Deleted High Radiation Area Deleted Offsite Dose Calculation Manual Process Control Program Major Changes to Radioactive Waste Treatment Systems 6.1-1 6.2-1 6.2-1 6.2-2 6.3-1 6.4-1 6.5-1 6.5-1 6.5-5 6.5-11 6.6-1 6.7-1 6.8-1 6.9-1 6.9-1 6.9-3 6.10-1 6.11-1 6.13-1 6.15-1 6.16-1 6+17-1 Amendment No.Proposed  

1.10 Hot Channel Factors F, Heat Flux Hot Channel Factor, is defined as the maximum local heat flux on the surface of a fuel rod divided.by the average fuel rod heat flux allowing for manufacturing tolerances on fuel pellets and rods.F~, Nuclear Heat Flux Hot Channel Factor, is defined as the maximum local fuel rod linear power density divided by the average fuel rod linear power density assuming nominal fuel pellet and rod dimensions.

F~, Engineering Heat Flux Hot Channel factor, is defined, as the ratio between F~and F~and is the allowance on heat flux required for manufacturing tolerances.

F , Nuclear Enthalphy Rise Hot Channel Factor, is defined as the ratio of the integral of linear power along the rod on which minimum DNBR occurs to the average rod power.1.11 (DELETED)Amendment No.Proposed 3.14 (DELETED)INTENTIONALLY LEFT BLANK Amendment No.3.14-1 Proposed 4.15 (DELETED)INTENTIONALLY LEFT BLANK Amendment No.Proposed (DELETED)ge Adequate shift coverage shall be maintained without routine heavy use of overtime.Administrative procedures shall be developed and implemented to limit the working hours of unit staff who perform safety-related functions including senior reactor operators, reactor operators, health physicists, auxiliary operators, and key maintenance personnel.

Changes to the guidelines for the administrative procedures shall be submitted to the NRC for review.Amendment No.Pd,+,+6.2-3 Proposed, C ld 1' RESPONSIBILITIES (Continued) k.Review of the Plant Security Plan and shall submit recommended changes to the Chairman of the Nuclear Safety Audit and Review Board.Review of the Radiation Emergency Plan and shall submit recommended.

changes to the Chairman of the Nuclear Safety Audit and Review Board.Review of implementing procedures for the Plant Security Plan and the Radiation Emergency Plan and proposed changes thereto.Review of all Reportable Events.Review of the Fire Protection Program and Implementing Procedures and submittal of recommended Program changes to the Chairman of the Nuclear Safety Audit and Review Board (NSARB).AUTHORITY 6.5.1.7 The PORC shall: a 0 b.Recommend in writing to the Plant Manager, Ginna Station approval or disapproval of items considered.

under 6.5.1.6(a) through (d)and (1)above.Render determinations in writing with regard to whether or not each item considered, under 6.5.1.6(a) through (d)and (1)above constitutes an unreviewed safety question as defined in 10 CFR Section 50.59.Amendment No.4, 32 6.5-4 Proposed t l J,'<I' TABLE j.'ETAILED TECHNICAL SPECIFICATION CHANGES LOCATION DESCRIPTION OF CHANGE REASON FOR CHANGE page 1-5 para 1.11 page 3.14-1 thru 3.14-4, para's 3.14 thru 3.14.7.1 page 3'4-5 thru 3.14"6 page 3.14-7 thru 3.4-8, Table 3'4-1 page 3.14-9 thru 3'4-10 Table~~3.14-2 page 4.15-1 thru, 4.15-4 para's 4.15 thru 4.15.7 page 4.15-5 Delete"Fire Suppression Water System" definition Delete"Fire Suppression Systems" in its entirety Delete fire suppression system"Basis" in its entirety Delete"Table 3.14-1, Fire Detection Instruments" in its entirety Delete"Table 3.14-2 Fire Service Water Hose Reel Location" in its entirety Delete"Fire Suppression System Test" in its entirety Delete fire suppression system test"Basis" in its entirety These changes are made in accordance with the guidance provided in Generic Letters 86-10 and 88-12'ire Protection and Fire Brigade staffing requirements are being removed from Technical Specification (TS)and incorporated into the UFSAR and plant procedures.

This change also adds administrative control to TS consistent to those for other programs implemented by the license condition.

page 6.2-3, para 6.2.2.(f)Delete fire brigade staffing requirement indicated in para.f including"*" portion at bottom of page page 6.5-4 para 6.5.1.6(l) 6.5.1.7 a.and b.Add"Review of the Fire Protection Program and Implementing procedures and submittal of recommended program changes to the Nuclear Safety Audit and Review Board" ATTACHMENT B Revise Facility Operating License by removing the paragraph identified below and inserting the enclosed pages.Remove Insert (5)Pursuant to the Act of 10 CFR Parts 30 and 70, to possess, but not separate, such byproduct and special nuclear material as may be produced by the operation of the facility.This license shall be deemed.to contain and is subject to the conditions specified in the following Commission ,regulations in 10 CFR Part 20, Section 30.34 of Part 30, Section 40.41 of Part 40, Sections 50.54 and 50.59 of Part 50, and Section 70.32 of Part 70;and is subject to all applicable provisions of the Act and rules, regulations and orders of the Commission now or hereafter in effect;and is subject to the additional conditions specif ied below: (1)Maximum Power Level RGGE is authorized to operate the facility at, steady-state power level up to a maximum of 1520 megawatts (thermal).

(2)Technical S ecifications The Technical Specifications contained in Appendix A are hereby incorporated in the license.The licensee shall operate the facility in accordance with the Technical Specifications.

(3)Fire Protection (a)The licensees shall implement and maintain in effect all fire protection features described in the licensee's submittals referenced in and as approved or modified by the NRC's Fire Protection Safety Evaluation (SE)dated February 14, 1979 and SE supplements dated December 17, 1980,'ebruary 6, 1981, June 22, 1981, February 27, 1985 and March 21, 1985.or configurations subsequently approved by the NRC, subject to provision (b)below.(b)The licensee may make changes to the approved fire protection program without prior approval of the Commission only if those changes would not adversely affect the ability to achieve and maintain safe shutdown in the event of a fire.  

(c)Deleted (4)Secondar Water Chemistr Nonitorin Pro ram The licensee shall implement a secondary water chemistry monitoring program to inhibit steam generator tube degradation.

This program shall be described.

in the plant procedures and shall include: (a)Identification of a sampling schedule for the critical parameters and control points for these parameters;(b)Identification of the procedures used to measure the values of the critical parameters;(c)Identification of process sampling points;(d)Procedure for the recording and management of data;(e)Procedures defining corrective actions for off control point chemistry conditions; and (f)A procedure identifying (i)the authority responsible for the interpretation of the data, and (ii)the sequence and timing of administrative events required to initiate corrective action.(5)S stems Inte rit The licensee shall implement a program to reduce leakage from systems outside containment that would or could contain highly radioactive fluids during a serious transient or accident to as low as reasonably achievable levels.This program shall include the following:

I ATTACHMENT C Discussion The purpose of the proposed change to.the license and Amendment to the, Technical Specifications is to incorporate the Ginna Fire Protection Program into the Updated Final Safety Analysis Report (UFSAR)as encouraged by Generic Letter 86-10, Implementation of Fire Protection Requirements, and Generic Letter 88-12, Removal of Fire Protection Requirements from Technical Specifications.

This generic letter also encouraged licenses'o apply for an amendment to their operating licenses (1)to replace current license conditions regarding fire protection with a new standard condition and.(2)to remove unnecessary fire protection Technical Specifications (TS).From 1986 to 1988 the NRC staff gained experience with implementation of Generic Letter 86-10 for new operating licenses.In addition, lead-plant proposals for this license change were submitted and approved for the Callaway, , Wolf Creek, and Perry nuclear plants.On this basis, the Commission staff developed additional guidance in Generic Letter 88-12, Removal of Fire Protection Requirements from Technical Specifications, for preparation of a license amendment request to implement Generic Letter 86-10.This license amendment submittal requests removal of the applicable portions of Fire Protection from the Technical Specifications (TS)and'incorporates them into the UFSAR and plant procedures.

Specifically, the following sections are removed.: 1.11 DEFINITION

-Fire Suppression Water System 3-.14 3.14.1 3.14.2 3.14.3 3.14.4 3.14.5 3.14.6 3.14.7 4.15 4.15.1 4.15.2 4.15.3a 4.15.3b 4.15.4 4.15.5 LIMITING CONDITIONS FOR OPERATION-Fire Suppression System Fire Detection Instruments Fire Suppression Water System Spray and/or Sprinkler Systems Halon Systems Fire Hose Stations Fire Barrier Penetration Seals Yard Hydrant-Southeast Corner SURVEILLANCE REQUIREMENT

-Fire Suppression System Test Fire Detection Instruments Fire Suppression Water System Spray Systems Sprinkler Systems Halon Syst: em Fire Hose Stations

4.15.6 4.15.7 Penetration Seals Yard Fire Hydrant-Southeast Corner 6.2.2(f)Administrative Controls/Organization

-Eire Brigade The following section is added to the Technical Specifications:

Administrative Controls/Review and Audit-PORC Review of the Fire Protection Program and Implementing Procedures Table 1 of Attachment A depicts the specific Technical Specification changes.In addition to the requirements being added to the UFSAR as proposed Tables 9.5-1, 9.5-2 and 9.5-3, a proposed.new Table 9.5-4 entitled Spray/Sprinkler System Operability has been added for clarity.Details are provided, in Attachment D.The Fire Protection Program will be incorporated.

into the.Updated Final Safety Analysis Report (UFSAR)either by references or description.

This will include the fire protection and post-fire safe shutdown systems, fire hazard analysis, commitments to Appendix A to Branch Technical Position (BTP)APCSB 9.5-1, descriptions of the methodology for assuring safe plant shutdown following a fire, and the Nuclear Regulatory Commissions Safety Evaluation Reports.Descriptions of the methodology for assuring safe plant shutdown following a fire are described in the UFSAR Sections 7.4 and 9.5 and plant procedures; these requirements remain unchanged.

Commitments to Appendix A to BTP APCSB 9.5-1, and to 10 CFR 50, Appendix R remain unchanged.

Administrative controls have been enhanced.by the changes to Section 6.5.1.6(l), and 6.5.1.7a.and b.of the Technical Specifications.

Technical controls are governed by the Ginna Quality Assurance Program Appendix D.Fire Brigade staffing requirements have been incorporated verbatim into the UFSAR from the Technical Specifications.

Administrative requirements for the Fire Protection technical staff remain unchanged.

Surveillance Requirements associated with fire detection systems, fire suppression systems, fire barriers, yard.hydrant and the administrative controls that address fire brigade staffing were relocated from the Technical Specifications and incorporated into the UFSAR without altering their intent or requirements.

The Limiting Conditions for Operation (LCO)for the fire protection system will be incorporated.

into.plant.procedures without.alteration of intent.Existing administrative controls related to fire protection audits are retained in the Technical Specifications under the requirement in 6.5.2.8(g).  

*I A All operational conditions, remedial actions, and test requirements included in the Technical Specifications for these systems, as well as the fire brigade staffing requirements of the Fire Protection Program will be incorporated.

into the UFSAR and plant procedures.

The remedial actions will be incorporated into plant procedures, including shutdown currently required by Technical Specification 3.0.1 if an LCO and its'associated Action Requirement cannot be met.Also, changes subsequent to this amendment will be subject to the new standard license condition as described in Section F of GL 86-10.Proposed UFSAR Tables 9.5-1 thru 9..5-4 tabulate the fire protection system requirements currently included in the Technical Specifications with the exception of the Limiting Condition for Operation (LCO)for the fire protection system which will be incorporated into plant procedures.

UFSAR Table 9.5-1 is TS table 3.14-2 Fire Service Water Hose Reel Location;UFSAR Table 9.5-2 is a tabular arrangement of the Fire Protection System Requirements; UFSAR Table 9.5-3 is TS Table 3.14-1 Fire Detection Instruments; UFSAR Table 9,.5-4 Spray/Sprinkler System Operability is a new table and is provided for clarity.These tables and.plant procedures will maintain the existing requirements without change.=The standard fire protection license condition has been included as a proposed change to the 1icense.The current fire protection license conditions 2.C.(3)(b)and.(c)have been removed.Proposed Section 2.C.(3)(b) now conforms to the guidance provided in Generic Letter 86-10 stated as follows: RGRE may make changes to the approved fire protection program without prior approval of the Commission only if those changes would not adversely affect the ability to achieve and maintain safe shutdown in the event of a fire.Section 2.C.(3)(a) has also been updated to include Safety Evaluation Reports dated.February 27, 1985 and.March 21, 1985.Administrative controls in Technical Specification 6.5.1.6(l) have been augmented to support the fire protection program.This is accomplished by delegating the Plant Operations Review Committee (PORC)responsibility for review of the fire protection program and implementing procedures and submittal of recommended program changes to the Nuclear Safety Audit and Review Board (NSARB).Justification for Chan es These proposed changes are made without altering the intent of the license condition, fire brigade staffing requirements or the requirements of the fire protection portion of the Technical Specifications.

After the relocation of fire protection system requirements from the Technical Specifications, events which may be potentially reportable would still be evaluated relative to the criteria of 10CFR50.72, 10CFR50.73 and 10CFR21 on an individual basis.A reportability determination would be made based on this J 4 4t'lr evaluation process.Events involving significant degradation of the fire protection system would be reportable.

Therefore, the proposed change will not result in loss of regulatory control.S stems Affected This change has no effect on any plant systems.Fire protection requirements in the Technical Specifications are removed and incorporated into the UFSAR and plant procedures without alteration of their intent or requirements.

Administrative controls in the Technical Specifications are enhanced.to support the fire protection program and to ensure conformance.

Based on the above discussion and the following significant hazard evaluation, RG&E has determined that the changes to the license and Technical Specification do not involve an unreviewed safety question, do not reduce the margin of safety nor involve a significant hazard consideration.

Si nificant Hazards Evaluation This evaluation covers the deletions of Technical.

Specifications 3.14, 4.15, 6.2.2(f), the section Bases for 3.14 and 4.15, the corresponding Definition Section 1.11, Table 3.14-1 Fire Detection Instruments, Table 3.14-2 Fire Service Water Hose Reel Location, and relocation of these requirements to the Updated Final Safety Analysis Report and plant procedures.

Detail changes are listed in Table 1 of Attachment A.The Limiting Conditions for Operation (LCO)for the fire protection system will be incorporated into plant procedures.

In addition, a proposed, new UFSAR Table 9.5-4, Spray/Sprinkler System Operability, has been added to provide clarity on these systems.The addition of Technical Specification 6.5.1.6(l) and revisions to License Conditions 2.C.(3)have also been proposed.The following discussion addresses these changes and their significant hazard evaluation.

1.Technical Specification 3.14, 4.15, 6.5.1.6(l), 6.5.1.7a.and b., 1.11, Table 3.14-1, Table 3.14-2, and new UFSAR Table 9.5-4~a~These changes do not involve a significant increase in the probability or consequences of an accident previously evaluated.

The accident analysis assumes that a design basis accident does not occur simultaneously with a fire.The fire hazard analysis does not solely rely on automatic fire suppression systems and/or fire detection systems as fire-rated assemblies; manual fire suppression and redundant safe shutdown trains are also available.

No change to the requirements have been made.These changes simply relocate the fire detection instrumentation, fire suppression water system and its definition, spray and/or sprinkler systems, halon systems, fire hose station, fire barrier penetration fire seals, yard fire hydrant, the existing fire protection tables, and applicable bases and places them into the UFSAR and plant procedures without altering their intent.Implementing procedures provide the administrative controls over the requirements.

The proposed new Table 9,.5-4 to the UFSAR adds clarity by providing identification of the spray/sprinkler systems by plant location, system identifying number and system flow type (automatic, manual or pre-action).

This information is derived from and duplicates that which is currently included.in implementing procedures.

Because no requirements are being changed, there will be no increase in the probability or radiological consequences of an accident previously evaluated.

Review of the Fire Protection Program, its implementation, and revisions will be the responsibility of the Plant Operations Review Committee (PORC).PORC shall be responsible for reviewing changes to fire protection requirements and submitting recommended program changes to the Nuclear Safety Audit and Review Board (NSARB).These changes do not create the possibility of a new or different kind of accident from any previously evaluated.

The proposed change does not alter the intent of the requirements; but rather, relocates them from the Technical Specifications to the UFSAR and plant procedures.

No modifications are being made to any plant system, structure or component which may be relied upon for safe shutdown.Operational, maintenance, and procedural requirements are not decreased.

The fire protection program is covered by the R.E.Ginna Quality Assurance Program.Plant procedures continue to provide the specific instructions for implementing the LCO, action, and surveillance requirements.

Since approval of this amendment will transfer Technical Specification requirements to the UFSAR and implementing procedures for the Fire Protection Program, we believe that subsequent changes to the Fire Protection Program should be promptly included as part of the UFSAR as well as the affected implementing procedure.

We expect to implement this process such that the UFSAR and implementing procedures are in agreement within a reasonably prompt time frame.

c~These changes do not involve a significant reduction in the margin of safety.No change is being proposed for the requirements themselves.

Plant procedures continue to provide specific instructions necessary for implementation of the requirements consistent with that currently in place.Fire protection reporting requirements would still be made relative to the criteria of 10 CFR 50.72, 10 CFR 50.73 and, 10 CFR 21 on an individual basis.Therefore the proposed changes would not result in.a reduction of regulatory requirements.

The proposed Technical Specification 6.5.1.6(l) delegates PORC with responsibility for review of the Fire Protection Program and submittal of recommended program changes to NSARB.Consequently, the appropriate level of controls over the change process under 10CFR50.59 will be implemented..

2.Technical Specification 6.2.2(f), Site Fire Brigade Requirements, has been deleted from Technical Specifications and transferred to plant procedures and the UFSAR.New Technical Specification 6.5.1.6(l), PORC Responsibilities,, has been proposed as an addition.a)These changes do not involve a significant increase in the probability or consequences of an accident previously evaluated.

No changes to the requirements have been made.These changes simply remove the site fire brigade, requirements from the Technical Specifications and places them into plant procedures and the UFSAR without altering them.Review of the Fire Protection Program and its revisions will be the responsibility of PORC.PORC shall be responsible for reviewing changes to fire protection requirements and submitting recommended.

program changes to the NSARB.This will ensure that implementing procedures contain the proper level of administrative control over the Fire Protection Program and that subsequent changes are appropriately evaluated under 10CFR50.59.

b)These changes do not create the possibility of a new or different kind of accident from any previously evaluated.

The proposed change does not alter the requirements.

Plant procedures will continue to provide the specific instructions for implementing the administrative requirements.

The number and qualifications of the Fire Brigade members has not changed.c)These changes do not involve a significant reduction in the margin of safety.No change is being proposed for the requirements.

Plant procedures will continue to provide the specific instructions necessary for implementation of the requirements consistent with that currently in place.

Fire Protection Program reporting requirements will still be made relative to the criteria of 10 CFR 50.72, 10 CFR 50.73 and.10 CFR 21 on an individual basis, therefore the proposed change will not result in a reduction of regulatory requirements.

The proposed Technical Specification 6..5-.1.6(l)delegates PORC with responsibility for review of the Fire Protection Program and submittal of recommended program changes to NSARB.Consequently, the appropriate level of controls over the change process under 10CFR50.59 will be implemented,.

3.License conditions 2.C.(3)(a),(b)and (c), Fire Protection, have been revised in accordance with the guidance provided.in Section F of Generic Letter 86-10, Implementation of Fire Protection Requirements, and as clarified in Generic Letter 88-12, Removal of Fire Protection Requirements from Technical Specifications.

Specifically, 2.C.(3)(a) has been updated to include Safety Evaluation Reports dated February 27, 1985 and March 21, 1985.Sections 2.C.(3)(b) and (c)have been removed and.a new section 2.C.(3)(b) has been proposed.which allows changes to be made to the approved Fire Protection Program only if those changes would not adversely affect the ability to achieve.and maintain safe shutdown in the event of a fire.a)This change does not involve a significant increase in the probability or consequences of an accident previously evaluated.

The change in license conditions from those previously incorporated into the license to the one presented in Generic Letter 86-10 and 88-12 does not result in any change in technical requirements of the change process.Previously, changes to the Fire Protection Program that decreased the level of fire protection in the plant could.only be made with prior commission approval utilizing the license amendment process (10 CFR 50.90).The proposed.license condition allows the licensee to make changes to the approved fire protection program under the provisions of 10 CFR 50.59 without prior approval of the Commission and only if those changes would not adversely affect the ability to achieve and maintain safe shutdown in the event of a fire.The original license condition also required that the licensee maintain an auditable record of all changes made to the fire protection program that do not require prior Commission approval.The proposed.license condition does not specifically levy this requirement; but, since the Fire Protection Program and the former Tech Specs are now incorporated into the UFSAR, their changes fall under 10

,re CW<4 C f.a 1 CFR 50.59, and section 10 CFR 50.59 (b)contains the same record keeping requirements.

The current license condition required an annual report to 0he Commission on all changes to the Fire Protection Program made without prior approval.The same annual reporting requirements are imposed by 10 CFR 50.59(b)(2) and, 10 CFR 50.71(e).This change does not create the possibility of a new or different kind of accident from any previously evaluated.

The proposed standard license conditions do not involve any significant change in requirements and conform to the guidance in Generic Letters 86-10 and 88-12.Any change being made will still require an evaluation pursuant to 10 CFR 50.59 to determine the existence of any unreviewed safety question.Transfer of technical requirements for the limiting conditions for operation, and surveillance of Fire Protection Systems and components ensures implementation of the 10CFR50.59 process.This change does not involve a significant reduction in the margin of safety.A standard license condition is implemented.

This requires that no change can be made to the fire protection program that will adversely affect the ability to achieve and maintain safe shutdown in the event of a fire without prior commission approval.Therefore the license condition does not involve any significant change in requirements and follows the guidance in Generic Letters 86-10 and 88-12.Fire Protection Program reporting requirements will still be made relative to the criteria of 10 CFR 50.72, 10 CFR 50.73 and 10 CFR 21 on an individual basis, therefore the proposed change will not result in a reduction of regulatory requirements.

ATTACHMENT D PROPOSED CHANGES TO THE UPDATED FlNAL SAFETY ANALYSlS REPORT The entire Section 9.5.1 Fire Protection Systems is included although not all sections required a change.New sections which are being transferred from Technical Specifications are appropriately annotated.

as to the Technical Specification section from which they came.(Refer to Attachment E.)

GINNA/UFSAR Chapter 9 AUXILIARY SYSTEMS TABLE OF CONTENTS (Continued)

Section and Title~ae~I~~~~~~~Collection System~~~~\~and Exhaust~a~~~~9.5.1.2.4 Other Design Considerations 9.5.1.2.4.1 Smoke Removal 9.5.1.2.4.2 Breathing Equipment 9.5.1.2.4.3 Control Building Ventilation 9.5.1.2.4.4 Reactor Coolant Pump Motor Oil 9.5.1.2.4.5 Floor Drains and Curbs 9.5.1.2.4'.6 Lighting Systems 9.5.1.2.4.7 Communications 9.5.1.2.4.8 Electrical Cable Insulation 9.5.1.2.4.9 Fire Barriers 9.5.1.2.4.10 Electrical Cable Penetrati.ons 9.5.1.2.4.11 Pipi.ng and Duct Penetrations 9.5.1.2.4.12 Cable Separation 9.5.1.2.4.13 Spray Shields 9.5.1.2.4.14 Construction Joints 9.5.1.2.5 Administrative Controls 9.5.1.2.5.1 Organization 9.5.-1.2.5.g9 Fire Brigade Training 9.5.1.2.5.jf4 Control of Combustibles 9.5.1.2.5.$

5 Control of Ignition Sources 9.5.l.2.5.$6 Fire-Fighting Procedures 9.5.1.2.5.$

7 Quality Assurance 9.5.1.j4 Safe Shutdown Capability 9.5.1.f41 Safe Shutdown Requirements 9.5.1.p.2 Alternative Shutdown Capabili.ty 9.5.1.P.3 Shutdown From Outside the Control Room 9.5.2 Communications Systems 9'.2.1 Public Address System 9.5.2.2 Telephone Systems 9'.2.3 Radio Systems 9.5.2.4 Offsite Communications 9'.2.5 Emergency Communications With the NRC 9.5.3 Lighting Systems 9.5.4 Diesel Generator Fuel Oil Storage and Transfer System 9.5.5 Diesel Generator Cooling System 9.5.6 Diesel Generator Starting System 9.5.7 Diesel Generator Lubrication System 9.5.8 Diesel Generator Combustion Air Intake References for Section 9.5 9.5-12 9.5-12 9,5-12 9.5-13 9.5-13 9.5-13 9.5-14 9.5-14 9.5-14 9.5-15 9.5-15 9.5-16 9.5-17 9.5-17 9.5-17 9.5-17 9.5-17 9.5-18 9.5-18 9.5-19 9.5-19 9.5-20 9.5-20 9.5-20 9.5-21 9.5-22 9.5-22 9.5-23 9.5-23 9.5-24 9.5-24 9.5-26 9.5-26 9.5-27 9.5-28 9.5-29 9.5-30 9.5-30 9.5-31Fire 8 rig ac!e Opere,gil'!'y a~d Sovveillance.

9-ix REV 7 12/91  

~I ll 4 P 1 GINNA/UFSAR Chapter 9 AUXILIARY SYSTEHS LIST OF TABLES (Continued)

Table 9.3-10 Title Parameters Used in the Calculation of Reactor Coolant Fission Product Activities

~Pa e 9.3-73 9.3-11 9.4-1 Tritium Production in the Reactor Coolant........9.3-74 Containment Ventilation System, Principal Component'ata Summary.........................9.4-35 9.5-1 Fire Service Water Hose Reel Locations..........9.5-33 0 feraSili~/q,5<$Fq~y~~g Syrinkjer S)st~oyemLili)y 9-xi REV 6 12/90 GINNA/UFSAR 9.5 OTHER AUXILIARY SYSTEMS 9.5.1 FIRE PROTECTION SYSTEMS 9.5.1.1 Desi n Criterio 9.5.1.1.1 General Design Criterion.

3 The design criterion used during the licensing of Ginna Station was General Design Criterion 3 (GDC 3), included in the Atomic Industrial Forum (AIF)version of proposed criteria issued by the AEC for comment on July 10, 1967.The criterion was as follows: Criterion:

The facility is designed so that the probability of fires and explosions and the potential consequences of such events does not result in undue risk to the health and safety of the public.Noncombustible and fire resistant materials shall be used throughout the facility wherever necessary to preclude such risk, particularly in areas containing critical portions of the facility such as containment, control room, and components of engineered safety features (AIF-GDC 3).With respect to this criterion, fire prevention in all areas of the plant was provided by structure and component design which optimized the containment of combustible materials and maintained exposed combustible materials below their ignition temperature in the design atmosphere.

Fire control requires the capability to isolate or remove fuel from an igniting source, to reduce the combustible temperature below the ignition point, to exclude the oxidant, and to provide a combination of the three basic control means.The latter two means were fulfilled by providing fixed or portable fire-fighting equipment of capacities proportional to the energy that might credibly be released by fire.Ginna Station was designed on the basis of limiting the use of combustible materials in construction and of using fire-resistant materials to the greatest extent possible.The fire protection system was designed to have the capability to extinguish any probable combination of simultaneous fires which might have occurred at the station.The system was designed in accordance with the standards of the 9.5-1 REV 6 12/90 GINNA/UFSAR National Fire Protection Association (NFPA)and was based generally on the recommendations of the Nuclear Energy Property Insurance Association.

Procedures were developed for fighting fires in all the plant areas and were included in the Plant Emergency (now designated"Site Contingency")Procedures.

.Fire prevention was controlled by administrative methods to prevent accumula-tions of combustible materials and to practice good safety methods.Periodic practice exercises were employed to ensure that plant personnel were familiar with the proper corrective procedures.

Fire detection and fire fighting systems of appropriate capacity and capability were provided in the original design to minimize the adverse effects of fire on structures, systems, and components important to safety.Sensing devices included both ionization chambers and temperature detectors.

Fire-fighting equipment included automatic water deluge in appropriate areas.A Halon 1301 total flooding system was installed.

Appropriate hoses and portable fire fighting equipment were provided and placed throughout the plant.The design of the fire protection system was reviewed in 1972 on the basis of 1 GDC 3 of Appendix A to 10 CFR 50 which was promulgated after the licensing of Ginna Station.It was determined that the requirements of GDC 3 were appropriately met by the plant design.9.5.1.1.2 Branch Technical Position 9.5-1 In May 1976, the NRC Branch Technical Position 9.5-1 was published for comment as Regulatory Guide 1.120, and in August 1976, Appendix A to Branch Technical Position 9.5-1 was published for use by plants docketed prior to July 1, 1976.The design of the fire protection system was reviewed against the criteria of the Branch Technical Position in a submittal to the NRC in February 1977.The submittal included a fire hazards analysis and several proposed design modifications in compliance with the regulatory guidance.A safety evaluation report was issued by the NRC in February 1979 with supplements in December 1980," February 1981, and June 1981.9.5-2 REV 6 12/90 GINNA/UFSAR Automatic smoke detection systems are, provided in all plant locations containing safety-related equipment and/or concentrations of combustible materials.

In addition, automatic preaction sprinklers or automatic water spray nozzles are installed for all cable trays where large concentrations of cable trays exist.All areas with flammable liquids are protected by a detection system and an automatic water suppression system.The relay room is protected by a detection system, an automatic Halon system, and three manual water spray systems.Flamemastic, a fire-retardant coating, has'been applied in locations containing concentrations of cable trays such as in the vault below emergency diesel generator 1B and at the entrances of the cable tunnel from the intermediate building, air handling room, and auxiliary building.New cables which meet IEEE-383 have also been added in various locations.

These cables do not need to be coated with Flamemastic.

Manual fire-fighting equipment exists at the station in the form of manual hose stations and portable extinguishers

~Should any manual hose station be out of service, the location and spacing of other hose stations ensure effective coverage of the affected area by adding one additional hose length to the nearest hose station not out of service.The plant utilizes two separate fire water systems.Redundant electric-and diesel-driven fire pumps are provided onsite to ensure that pressure and water flow requirements of the automatic and manual suppression capabilities are maintained.

In addition, an offsite supplied underground yard fire water system with diesel-backed redundant pumps is available.

Each of these sources is capable of supplying all the water required for suppression of a fire in each plant area.A cross-tie capability exists between these two sources so that the manual hose stations and automatic suppression systems can be supplied even with the failure of both onsite pumps.Additional plant modifications include the upgrading of detection and suppres-sion systems, fire area penetration seals, reactor coolant pump oil collection systems, fire area dampers, drain backflow protection, emergency lighting, and fire door supervision.

9.5-3 REV 6 12/90 i GINNA/UFSAR Rochester Gas and Electric Corporation has a fire penetration seal program at Ginna Station, which ensures that all penetrations required to be sealed to specific hourly ratings are identified, sealed, tagged, and maintained in good condition.

9.5'.1.3 Safe Shutdown Criteria In February 1981, the fire protection rule (10 CFR 50.48 and Appendix R to 10 CFR 50)became effective, which promulgated criteria related to the safe shutdown capability following a potential fire and other fire protection features.The evaluation of the fire protection system against the safe shut-down capability criteria is discussed in Section 9.5.1.3.9.5.1.2 S stem Desi 9'.1.2.1 General Fire detection instrumentation is located in all areas of the plant containing safety-related equipment and in areas containing large amounts of combustible or flammable materials.

Actuation of fixed suppression systems and early warning alarms are provided by these detectors.

Normal fire protection is provided by fixed water deluge spray systems, fixed sprinkler systems, fixed Halon 1301 systems, hose lines, and portable and wheeled extinguishers suitably located in the required areas.Water to the fire suppression system is supplied, via a header, by two fire pumps.The source of water is'ake Ontario.The yard loop and fire hydrants are supplied by the town of Ontario water supply.Fire barriers are located throughout the plant to separate established fire areas from each other and also to separate certain safety areas from the remainder of the plant.These barriers are designed to stop a fire from propagating from one area to the other.All penetrations in these barriers are sealed with appropriate materials to match the requirements of the barrier.Fire areas have been defined based upon separation of equipment and cables to ensure that at least one path of safe shutdown systems is always available.

9.5-4 REV 6 12/90 GINNA/UF SAR Fire prevention and mitigation considerations have been included in the design of ventilation systems, drain systems, lighting systems, communication systems, electrical and instrument cables, layout and materials, and oil collection systems.Fire prevention is controlled by administrative methods to prevent accumulation of combustible materials and to practice good safety methods.9.5.1.2.2 Fire Detection and Signaling Systems The plant has a protective signaling system which alarms locally in selected parts of the plant and transmits fire alarm, supervisory, and trouble signals to the control room.In addition to signals from fire detection devices in various rooms or ventilating systems, the system transmits signals indicating water flow in water spray or sprinkler systems, fire pump operation, fire pump trouble, and low fire water tank level or pressure.Fire alarms are initiated by the smoke and heat detectors and by water flow or pressure switches in the water fire suppression systems.Additional protection is available by the installation of tamper switches on all major valves, unless they are locked in position.The signaling system is powered by the emergency power supply system and automatically transfers to a 4-hr battery backup supply if its normal power source is interrupted.

Fire detection and signaling systems are generally designed and installed in accordance with NFPA 72D.Smoke detectors and/or heat detectors have been provided in every area that contains safety-related equipment.

Some detectors provide early warning fire detection and notification only.Others provide fire suppression system actuation in addition to detection and notification.

These detectors are supervised to detect and annunciate circuit breaks, ground faults, and power supply failures.Remote test panels, which allow remote testing of the sensitivity of the detectors, are installed in the vicinity of smoke detectors that are difficult or hazardous to reach.9.5-5 REV 6 12/90 GINNA/UFSAR

~~The list of instruments required to be operable for fire detection and suppression systems actuation and their locations are shown in the Technical Specifications.

Periodic inspection and tests of the fire detection devices are in accordance with NFPA 72E and the Technical Specifications.

I 5 Fire alarm signals are provided as an integral part of the fire suppression systems to indicate an alarm in case of equipment malfunction, tampering, or in case of fire in any protected area.Additional audio and visual alarms and operating switches are provided in the control room, together with such pressure gauges, test, and reset switches as are required to completely monitor the fire protection system.The fire alarm signals in the control room are distinctive from other equipment alarms.9.5.1.2.3 Fire Suppression Systems Fire suppression is provided by'fixed water spray and sprinkler systems, fixed gas systems, hose lines, and portable and wheeled extinguishers suitably located in the required areas.The water systems associated with the fire protection system are shown in Figures 9.5-1, 9.5-2, 9.5-2a, 9.5-2b, and 9.5-2c.The fixed gas systems for the relay and MUX rooms are shown in Figure 9.5-3.and manual water suppression systems and hose stations inside the plant is pumped from Lake Ontario.A fire header.of sufficient size is provided to deliver an adequate quantity of water throughout the plant at a pressure of no less than 75 psi at the highest nozzle.The water supply for the fire hydrants on the yard fire main are supplied with water from the Town of Ontario.The yard hydrant system can be used as a backup to the fixed protection systems and inside hose stations'through wall hydrants in four locations.

Figure 9.5-4 shows the fire protection system yard loop (yard fire main).See also Section 9.5.1.2.3.5.

/5~~vertical shaft centrifugal fire pumps located in the screen house.Both pumps take suction from the circulating water intake.One pump is diesel-engine driven and the other is electric-motor driven.Each pump has a rated output of 9.5-6 REV 6 12/90 GINNA/UP SAR 2000 gpm at 125 psig, which is adequate to meet the largest anticipated water demand.An automatic sprinkler system supplied by the yard fire main is provided in the area of the screen house that contains the two fire pumps.A curb has been installed around the diesel fire pump and the diesel oil storage tank to control any diesel oil, leaks.The curbed area is equipped with a floor drain which drains to a holding tank buried outside the screen house.A 15,000-gal pressure tank (10,000 gal of water)and a 120-gpm centrifugal jockey pump maintain system pressure at a minimum of 100 psig.When the system pressure drops below 95 psig the electric-motor-driven fire pump starts, If the pressure drops below 85 psig, the diesel-driven fire pump starts.An automatic controller is located with each fire pump.Each pump can be manually started from the control room or at the individual controller.

Each pump can be manually stopped at the controller.

In addition, the electric-driven fire pump can also be manually stopped by opening a circuit breaker located in the screen house near the fire pumps.Pump running and pump power loss or engine trouble signals are annunciated in the control room as well as at the individual pump controllers.

The diesel fire pump is provided with an engine coolant heater and filter.The function of the heater is to raise the engine block temperature to a level at which the engine can start more easily and which would result in reduced wear on engine components.

The coolant filter removes corrosion particles from the engine coolant.The diesel'ire pump engine is started by redundant 24-V batteries.

The batteries are maintained fully charged and ready for service by an automatic dual battery charger operating in the float mode.The charger can charge one battery on high rate while maintaining the other battery on float or charge both batteries on high rate simultaneously.

The charger automatically switches from float to high rate and back in order to recharge the batteries when necessary.

The 120-V ac,power is supplied to the battery charger from the screen house lighting panel.9.5-7 REV 6 12/90 GINNA/UFSAR Specific procedures covering the diesel fire pump testing and maintenance

~~include battery surveillance, testing of diesel oil in the day tank, and the requirement that the diesel engine be operated for a minimum of 15 min each month.9.5.1.2.3.3 Pi in and Valves.A separate 10-in.discharge line from each fire pump supplies the 8-in.and 10-in.interior loop main.All automatic and manual fixed water suppression systems and interior hose stations are supplied by this loop main.Outside screw and yoke gate valves subdivide the loop into a number of sections so that a single section can be isolated without impairing the entire loop.The design is such that isolation of a section of fire water piping system does not cause a loss of both the fixed suppression system pro-tection and the manual hose coverage for the same area.Key-operated sectional valves are provided on the exterior yard main to subdivide it into a number of sections so that a single section can be isolated without impairing the entire system.Electrical supervision is provided for valves controlling water flow into sprinkler or deluge systems, Sectional valves on the interior loop and valves controlling fire pump discharge are locked open and/or are provided with electrical supervision (valve tamper switches).

9.5.1.2.3.4 Fire H drants.Yard fire hydrants are provided at approximately 250-ft intervals around the exterior of the plant.The lateral to each hydrant is controlled by a key-operated (curb)valve.Threads on hydrant outlets and hose couplings are compatible with those of fire departments which serve the plant.Impact barriers protect those fire hydrants and post-indicator valves which are located within 25 ft of roadways.The ground area surrounding each exterior hydrant is graded to provide a clearance of at least 12 in.between the ground and the center of the lowest hydrant port.Fire-fighting equipment is housed within hose houses.Administrative procedures cover snow removal operations and inspection of all outdoor fire hydrants for drainage immediately prior to freezing winter weather and for proper function immediately after the winter season.A yard hydrant on the southeast corner of the yard loop provides backup fire suppression capability 9.5-8 REV 6 12/90 i

GINNA/UF SAR for the transformers and primary fire suppression capability for the standby auxiliary feedwater building.9.5.1.2.3.5

~ard Loo.The fire protection system yard loop (yard fire main)is shown in Figure 9.5-4.The yard loop supplies water to the yard fire hydrants (Section 9.5.1.2.3.4) and as a backup to the water suppression systems 7 inside the plant (Section 9.5.1.2.3.1).

The yard loop provides a backup source of cooling water if service water is lost.It provides a backup to the condensate storage tanks for feedwater to the motor-driven or turbine-driven auxiliary feedwater pumps.It provides a backup to the condensate supply tanks for feedwater to the standby auxiliary feedwater pumps.It can be used to provide cooling water to the emergency diesel generators.

The yard loop is equipped with manual isolation gate valves, as shown in Figure 9.5-4, to provide segment isolation in the case of line failures.The yard loop is supplied water from the town of Ontario water system.F 9.5.1.2.3.6 terio Hose Stat ons.A total of 42 interior hose stations, each equipped with 100 ft of 1.5-in.diameter UL-approved municipal fire hose, are provided to protect various areas of the plant.The nozzles are 1.5-in.fog nozzles designed specifically for use in electrical fires and have a fog pattern range from 30'o 90'ith no straight stream capability.

A list of the hose station locations~is provided in Table 9.5-1.zQ Op8,rkili~

f 9.5.1,2.3.7 Wate Su ression S stems.Water suppression systems include water spray systems and water sprinkler systems with open or closed-head nozzles and sprinkler heads.The water suppression systems meet the design installation requirements of NFPA 13 and/or NFPA 15.Each sprinkler system has an outside screw and yoke shutoff valve.All control valves for spray or sprinkler systems are electrically supervised with alarms in the control room.Other important valves on the water supply are either electrically supervised or locked in the proper position.The water flow rates follow NFPA 15 guide-lines.The water suppression systems and the areas covered are tabulated below.Automatic water spray systems (which can also be manually actuated)provide protection for 1.The turbine lube-oil system in the turbine building.9.5-9 REV 7 12/91 GINNA/UF SAR 2.3.5.7.8.9.The hydrogen seal-oil system in the turbine building.The oil storage room in the turbine building.The oil filled transformers outside the turbine building.The cable trays in the screen house.The cable tunnel.The charcoal filter unit in the auxiliary building ventilation system.Control room-turbine building wall.The cable trays in the air handling room.Manually actuated water spray systems provide protection for 1.The turbine-driven auxiliary feedwater pump and feedwater pump oil 7 tank area.2.The condenser pit area.3.The relay room.The relay ro'om water suppression systems serve as backup to the automatic Halon system that provides primary protection.

Automatic preaction sprinkler systems provide protection for 1.The cable entrance area at the auxiliary building.2.The cable tray area in the basement of the auxiliary building (elevation 235 ft 8 in.).3.The cable tray area at elevation 253 ft 6 in.of the auxiliary building.4.The cable tray area in the intermediate building.5.The diesel generator rooms.The sprinkler systems for these areas have closed-head sprinklers with preaction trim on the deluge valves in accordance with NFPA 13.Automatic sprinkler systems provide protection for the following.

9.5-10 REV 7 12/91 GINNA/UF SAR 1.The service water pumps in the screen house.2.The fire pumps in the screen house.3.The turbine island.4.The service building.5~The technical support center diesel room.An automatic and manual water curtain is provided for protection of the wall between the turbine building and the control room (superwall).

The design of the water curtain is in accordance with NFPA 15.The system is actuated by heat detection.

Closed-head, close-spaced sprinklers are installed around the perimeters of the east and west stairwells and the equipment hatch, at the ceiling level of the auxiliary building mezzanine floor, as water curtain fire barriers to prevent the spread of fire from one level to the other.The sprinkler systems are wet pipe systems, which open automatically at a fixed temperature of 165'F or less.The containment postaccident charcoal.filter units are protected with a water dousing system from the containment spray header, as described in Section 6.5.1.2~The service building interior, including storage areas, shop areas, offices, locker rooms, and all rooms having combustible material, is protected by automatically operating wet-pipe sprinkler systems, with exterior water gauges and indication in the control room.The turbine-driven auxiliary feedwater pump is protected with a water spray system consisting of six spray nozzles (Grinnell Mulsifyre Projector Type S-l 40-15)located in an array above the equipment.

The north center and northwest corner nozzles are partially blocked by existing auxiliary feedwater piping in the area.An analysis was performed which demonstrated that the original design had sufficient margin such that the existing configuration met RG&E's original criteria of 0.5 gpm/ft water spray density and exceeds the NFPA 15 general range of 0.2-0.5 gpm/ft 9.5.1.2.3.8 Gas Su ression S stems.Total flooding automatic Halon 1301 I 5 extinguishing systems are provided in the relay room, MUX room, and technical 7 9.5-11 REV 7 12/91 GINNA/UFSAR support center SAS/PPCS computer room.The systems are designed in accordance with NFPA 12A-1980, Section 1-5.4, to maintain a Halon concentration of 5%for at least 5 minutes following delivery (sufficient time to allow effective emergency action by trained personnel).

Ionization type smoke detectors in each are a alarm and annunciate in the control room.Where appropriate, a reserve supply of Halon 1301 permits prompt restoration of automatic protection following a system discharge.

The Halon fire extinguishing systems are controlled by electronic control systems that are interfaced with the station fire detection system.The control system coordinates the fire detection system with local alarm actuation, air conditioning and ventilation shutdown as appropriate, electrical discharge.

In addition to local manual pull stations control panels in the main power disconnection as appropriate, and Halon automatic activation, Halon can be released using or by operation of manual key switches on the fire control room.Halon 1301 storage cylinders are weight tested semiannually.

The relay room and MUX room systems are shown in Figure 9.5-3.9.5.1.2.3.9 Portab e i e Ext s e s.Pressurized

~ater, dry chemical,~~~~carbon dioxide portable extinguishers are distributed throughout the plant in accordance with the provisions of NFPA 10.9.5.1.2.4 Other Design Considerations systems are capable of exhausting volumes of smoke directly to the outsider In addition, three portable smoke ejectors, each with 5000-cfm capacity, are provided for smoke removal.Flexible hose sections are provided to channel smoke and hot gases through the buildings.

9.5.1.2.4.2 Breathin E u me t.At least 10 self-contained breathing units dedicated to emergency use are provided.Each breathing unit has one spare bottle.The plant has the capability to supply breathing air to 10 men for 6 hr at the rate of two (1.0 hr)bottles per man per hour.A compressor and cascade system are provided onsite to supply the breathing air.9.5-12 REV 7 12/91 LW 0 I J Ilk f ,I GINNA/UFSAR 9.5.1,2.4.3 Cont ol Bui d n Venti at o.The control building ventilation system is designed to provide a safe, controlled environment for the control room, chart room, MUX room, and battery rooms under all required conditions, including high-and moderate-energy line breaks outside containment, as well as small fires in the relay room or control room.Further, the battery room ventilation system will maintain the concentration of free hydrogen in the battery rooms at a low level.In addition to the normal air conditioning system, the battery'rooms have backup fans, powered from the batteries, which would exhaust air to the outside vent ductwork.l3 The control room ventilation system has controls which allow for manual actuation of dampers such that 25%of the return air is bypassed through the charcoal filter unit (see Figure 9.4-1).This mode of operation allows for removal of products of combustion from the control room atmosphere following the occurrence of a small fire.9.5.1.2.4.4 Reacto Coolant Pum Moto 0 Col ect o S ste.The reactor coolant pump motor oil collection system consists of a package of splash guards, drip pans, and enclosures assembled as attachments to the reactor coolant pump motor at strategic locations to preclude the possibility of oil making contact with hot reactor coolant system components and piping.Any leaking oil is drained from each individual pump to its own collection tank, which is capable of handling the entire oil inventory of the motor.Strainers are placed at the drain of each drip pan or enclosure.

The oil collection components are designed and attached to preclude dislodging during a seismic event.9.5.1.2.4.5 loor D ains and Curbs.Safety-related equipment is mounted on pedestals and floor drains provided in these areas are generally adequate to carry off fire water and prevent safety-related equipment from being flooded with stand'ing water.In areas such as the control room, where floor drains are not provided, fire water will be drained out through door openings.Curbs are provided in the screen house to prevent water or flammable liquid from flowing into the basement where both divisions of safety-related cables are routed.Additional curbs are provided around the diesel-driven fire pump area in the screen house.9.5-13 REV 7 12/91~

GINNA/UFSAR A barrier has been installed around the turbine lube-oil reservoir area to contain possible oil spillage.The capacity of the enclosed area is large enough to retain the entire contents of the lube-oil system plus 10%margin for fire water.Where drains from safety-related areas are tied into drains from areas which contain a large quantity of flammable liquid, backflow protection is provided to prevent possible spread of a liquid fire via the drain'system.9.5.1.2.4.6 Li htin S stems.See Section 9.5.3.plant.The primary system is the combination paging and party system;in addition, there is a sound powered phone system and a radio paging system.The sound powered system is hard wired with separate wires from the combination paging and party system.The radio paging system provides communication with areas inside the containment with the help of a radio antenna mounted in the containment.

Additionally, a repeater located in the yard area allows for greater flexibility with radio communications.

There is adequate redundancy 2 with these three systems to ensure good communications throughout the plant during any fire emergency (see Section 9.5.2).9.5.1.2,4.8 Elect cal Cab e Insu at o.The cable insulation used at Ginna Station includes Kerite, oil-based rubber, neoprene, and polyvinyl chloride.The cables have, as a minimum, passed the ASTM and UL horizontal and vertical flame tests.Power cables and polyvinyl chloride control cables have passed the Consolidated Edison Bonfire Test.The majority of the electrical cables were purchased and installed prior to the publication of the IEEE 383 standard for flame testing of electrical cables;however, the potential combustion products for the materials used at the station have been evaluated from generic test reports and do not exhibit an unusual or significantly hazardous nature.All cables used for modifications meet IEEE 383 criteria unless specifically excepted.The spent fuel pit bridge crane motive and control power cable is payed in and out from a spring-loaded storage reel assembly.Cable meeting IEEE 383-1974 flame retardant requirements and meeting the 9.5-14 REV 7 12/91 I C 4 Ih GINNA/UF SAR flexing duty requirements of the bridge crane cable was not available at the time replacement was required.The replacement cable was reviewed and it was determined that the proposed replacement would not adversely impact existing 10 CFR 50 Appendix R compliance methods or options used to maintain compliance (Reference 7).This determination will be made whenever it is impracticable to meet IEEE-383 criteria for cables used in modifications.

February 1977 (Reference 2)identifies the fire barriers in the plant and the requirements for maintaining their integrity.

These barrier requirements were determined by the fire loadings calculated for each area subject to a poten-tial fire hazard.As a result of this analysis, several design modifications were implemented at the plant including upgrading of the rating of original barriers and installing new barriers.Additional definition of fire areas and barriers and analysis of fire zones were conducted as part of the 10 CFR 50, Appendix R, review effort.The addition of the water curtain around the perimeters of the stairwells and equipment hatch at the'ceiling level of the auxiliary building mezzanine floor is a part of this effort.See Section 9.5.1.2.3.7.

Also, 3-hr-rated dampers were installed in ducts penetrating these fire areas.New fire barriers were installed in the emergency diesel-generator cable vault, battery room 1B, the charging pump room, the auxiliary building, the intermediate building, and the containment.

Fire barriers associated with power and instrument cable systems are discussed in Section 8.3.3.Fire protective coatings have been applied to the structural steel members forming or supporting a designated fire barrier.In this regard, the struc-tural steel roof beams and a column that supports the roof of the A and B battery room and the floor of the relay room are provided with a fire protec-tive coating, which will ensure that adequate margins of safety will be maintained for at least 1 hr during a fire emergency.

9.5.1.2.4.10 Electr ca Cab e e et at o s.The fire seals installed at Ginna Station fall into two major categories:

1.Seals installed in 1975 using BISCO SF-20 silicone room temperature vulcanizing foam rubber.9.5-15 REV 7 12/91~

p IP~'a GINNA/UFSAR 2.Seals installed since September 1979 using Dow Corning 3-6458 silicone room temperature vulcanizing foam rubber.The adequacy of several fire endurance tests and their applicability to cable tray and conduit penetration fire seals has been demonstrated in a submittal to the NRC in June 1980, with the conclusion that the seal designs at the station are either similar to or more conservative than the seal designs tested by the ASTH E-119 fire test method for a 3-hr rating.The NRC concurred with the evaluation.4 NRC Information Notice 88-04 alerted licensees that some fire barrier penetration seal designs may not be adequately qualified for the design rating of the penetrated fire barriers.As part of RG&E's review in response to Information Notice 88-04, a program was established to evaluate fire barrier penetrations against a tested configuration and examine the qualification test documentation.

Branch Technical Position (BTP)-APCSB 9.5-1 requires that cable and cable tray penetrations of fire barriers (vertical and horizontal) be sealed to give protection at least equivalent to that of the fire barrier.Although not specifically stated in APCSB 9.5-1 that penetration designs must be qualified by tests, RG&E proceeded with this program in order that the penetrations would continue to meet a tested configuration, when being maintained or involved in a plant modification, thereby ensuring the barrier would not be degraded.For fire barrier penetration seals for which it is not possible to achieve a duplication of a specific tested configuration, appropriate compensatory measures are taken, such as posting fire watch patrols when required by the Technical Specifications, temporarily repairing and qualifying the penetration until it can be reworked, and performing technical evaluations to demonstrate that the penetration meets an equivalent level of protection.

Guidance from General Letter 86-10 is employed in these cases.9.5.1.2.4.11 Pi and Duct enet at o s.Piping penetration of fire barriers are either poured in place or sealed by one of the following methods: grout, silicone RTV foam seals, or flexible reinforced silicone-rubber boots.The piping and duct penetrations have fire resistance ratings commensurate with 5 the fire hazards on either side of the penetration determined by the fire hazards analysis.The fire rating adequacy of the seals was demonstrated in a submittal of fire test reports to the NRC in June 1980.Based on the data of 6 9.5-16 REV 7 12/91 G INNA/UFSAR these reports, the NRC concurred that the piping and duct penetration seals provide adequate resistance to prevent a fire from propagating through the rated fire barriers.4 9.5.1.2.4.12 Cable e a at o.The design and construction of Ginna Station predates current industry standards of physical separation.

The criteria and design features related to cable separation at the plant are discussed in Section 8.3.1.4.Cable separation as it relates to the safe shutdown capa-bility of the plant under a fire emergency is discussed in the references cited in Section 9.5.1.3.intermediate building over the control rod drive motor control center and switch-gear, and in the auxiliary building over switchgear, motor control centers, and other electrical equipment to help protect this equipment from damage or undesirable effects from the application of fire water.9.5.1.2.4.14 Const ction Jo ts.The construction points between containment and the surrounding buildings provide fire resistance commensurate with the 2 hazards in the area.9.5.1.2.5 Administrative Controls The administrative controls for fire protection consist of the fire protection organization, fire brigade training, the controls over combustibles and igni-tion sources, the prefire plans and procedures for fighting fires, and the quality assurance provisions for fire protection.

These controls are discussed in Sections 9.5.1.2.5.1 through 9.5.1.2.5.6.

The fire protection program is in conformance with the guidelines of Nuclear Plant Fire Protection Functional Responsibilities, Administrative Controls, and Quality Assurance and is updated in the Fire Protection Plan as indicated in References 9 and 10.9.5.1.2.5.1 Or anization.

The fire protection organization defines the organizational responsibilities and lines of communication between the various positions involved in the fire protection program, the qualification require-ments of the key positions in the fire protection program, and the composition of the fire brigade.The fire protection organization encompasses positions 9.5-17 1>/>1~  

GINNA/UF SAR extending from the Vice President of Ginna Nuclear Production to the Station Shift Supervisor.

The organization includes a dedicated Fire Protection Engineer who reports directly to the Ginna Superintendent of Support Services.These management and staff positions are responsible for formulation, implementation, and assessment of the fire protection program.g 5,(,2.5.a fvvss~z Qa ana assai~]F'lg+Qpl+ADG 9.5.1.2.5.$

re B de T.....3 The fire brigade training program consists of classroom instruction, practice in fire fighting, and fire brigade drills.The classroom instruction is provided quarterly and includes instruction in the types of fires that could occur in the plant, their particular hazards, location and use of the plant fire-fighting equipment, and fire-fighting strategies and techniques.

Brigade members participate annually in training sessions in actual fire extinguishment; at quarterly intervals the station conducts preplanned fire drills.-Fire brigade training is provided for all members.In addition to the training and drills conducted onsite, the program includes 8 hr per year of hands-on training for each brigade member at the Rochester Fire Academy, an academy which is used to train members of the local paid and volunteer fire departments'.

Additional training is also conducted at the Niagara Mohawk training facility in Oswego.The local fire department is approximately 4 miles offsite and is included in an annual training, session onsite to ensure its ability to respond quickly and effectively to fire situations at the plant.Other surrounding departments periodically respond to the site and participate in this drill.A good working relationship has been established between the plant staff and these fire departments.

9.5.1.2.5.(Control of Combust bles, Administrative controls have been established to limit the amount of combustibles to which a safety-related area may be exposed.These controls include housekeeping procedures, periodic inspections to determine the effectiveness of housekeeping practices, procedures and guidelines for use and storage of combustible materials, and a review of proposed work activities to identify potential transient fire loads to evaluate the need for additional fire protection provisions in the work activity procedure.

Administrative procedures have been established to ensure that all wood products such as boxes, staging forms, construction lumber, shelves, and benches used in safety-related areas are fire-retardant treated.9.5-18 REV 7 12/91 GINNA/UFSAR 9.5.1.2.5.$

Control of t on Sou ces.Administrative controls have been established to protect safety-related equipment from fire damage or loss resulting from work involving ignition sources.These controls include station procedures which require a work permit to perform welding, grinding, or flame cutting operations and the posting of a fire watch during such operations, and controls that prohibit smoking in safety-related areas and in areas containing flammable or potentially explosive materials.

Administrative controls have been established to prohibit the use of open flame or combustion-generated smoke for leak testing.Administrative controls have been established to ensure that before issuing the open flame, welding, and grinding permit, a foreman or supervisor trained in basic industrial fire fighting and fire prevention physically surveys the area where the work is to be performed and establishes that the following precautions have been accomplished:

1.All movable combustible material below and within a 35-ft radius of the cutting, welding, grinding, or open flame work has been removed.2.All immovable combustible material below and within a 35-ft radius has been thoroughly protected by asbestos curtains, metal guards, or flameproof covers, and fire extinguishers, hose, or other fire-fighting equipment are provided at the work site.6 9.5.1.2.5.

i e-t Procedu es.Procedures have been established to prescribe the actions to be taken by the individual discovering the fire, the control room operators, and the members of the fire brigade.Plans covering fire-fighting strategies for safety;related fire areas and areas presenting a hazard to safety-related equipment have been developed and documented.

Such" plans include a discussion of the combustibles, appropriate extinguishing agents, location of nearby fire-fighting equipment, likely approach routes, location and protection of safety-related and necessary auxiliary equipment, fire-fighting hazards, handling of radiological and toxic hazards, and methods to ventilate the fire area.The fire brigade members'esponsibilities associated with the prefire plans have been delineated.

GINNA/UF SAR A written.agreement with the local fire company is maintained to ensure adequate support for a fire emergency.

Members of the local fire company have received training in basic radiation principles, typical radiation hazards, and precautions to be taken in a fire involving radioactive materials in the plant;they also participate in fire brigade drills at least once per year.Station procedures have been established to provide for the recall'of off-duty fire brigade members to assist the on-shift brigade in the event of a fire emergency.

9.5.1.2.5.g ua ssurance.The design, procurement, installation, test-ing, and administrative controls for the fire protection program are controlled in accordance with Ginna Station Quality Assurance Program, Appendix D, implementing the quality assurance provisions contained in Branch Technical Position 9'-1, Appendix A.Q.S.].8 OPBQA+1Ln'/

A>4'P$<Ri/klLMIJCE R~O'IREN&ldT5 p'KldSERT c]9.5.1.$~Sa e S utdown Ca ab t 9.5.1.$.1 Safe Shutdown Requirements The requirements for protecting safe shutdown systems and their respective components and"associated circuits are specified in 10 CFR 50, Appendix R, and t the NRC Generic Letter 81-12.The objective of the requirements is to limit damage to safe shutdown systems resulting from an unmitigated fire to the extent that the ability to achieve safe shutdown is ensured.Rochester Gas and Electric submitted an evaluation report in January 1984 11 describing alternative safe shutdown capability in accordance with Appendix R, 6 Section III.G.This report was revised in October 1984 and in January 12.13 1985;the revisions included a request for twelve specific exemptions from the retrofit requirements of Appendix R, Section III.G.In safety evaluation reports of February 1985 and March 1985 the NRC accepted the alternative 14 15 safe shutdown proposals and granted the requested exemptions.

Thus, all areas of the plant either meet the retrofit requirements of Appendix R (as exempted)or are provided with acceptable alternative safe shutdown capability.

I Subsequent to the implementation of the Appendix R modifications during the 1986 refueling outage, the RGB alternative safe shutdown report was revised 9.5-20 REV 7 12/91~

4-v" t I*i qC GINNA/UFSAR (March 1986)to incorporate deviations from the original design and compliance i2 methods.These revisions were in accordance with the previously approved safety evaluation reports mentioned above and with NRC guidance for reviewing 2 compliance methods.9.5.1.jf.2 Alternative Shutdown Capability id Alternative shutdown capability is provided for the control room, relay room, air handling room, battery rooms, cable tunnel, and auxiliary building basement/mezzanine.

Alternative shutdown is accomplished independent of these areas by procedural means.with required'actions performed at local shutdown stations or locally at the equipment.

These procedures are designed to ensure that the following shutdown functions would be available following a fire: reactivity control, primary system makeup control, primary system pressure control, decay heat removal, process monitoring, and support services.If a shutdown function could be potentially lost due to a fire, a procedure to restore the shutdown function is included.The procedure delineates the operator actions necessary to restore the lost function.To ensure continued operation of the onsite diesel generators in the event of a fire, control circuits in the diesel generator A room are isolated so that fire damage in other fire areas cannot inhibit proper diesel control and operation.

Also, sufficient control features have been provided so as to allow for local control of the 1A diesel generator.

Alternative controls and instrumentation including start/stop controls;voltage and speed controls;voltage, current, and rpm indication are provided in the diesel generator A room.See Section 7.4.4 for a discussion of alternative shutdown instrumentation and control.In addition to the actions necessary to res'tore or compensate for lost functions, the procedures for several areas also identify the fire's potential effect on other equipment not necessarily needed to provide a shutdown function and identify what, if any, operator actions should be taken.Further, the procedures provide the operators with the necessary guidance for initial plant cooldown and subsequent cold shutdown.All necessary actions to achieve hot shutdown can be performed by onsite personnel.

All necessary materials are stored onsite.9.5-21 REV 7 12/91 i I 4 0 GINNA/UFSAR Procedures are provided for all fire areas where an unmitigated fire could disrupt needed shutdown functions.

As an example, the procedure for the K control room (which identifies the actions necessary to achieve and maintain cold shutdown)is discussed below.9.5.1.$.3 Shutdown From Outside the Control Room In the event of a control room fire that results in evacuation of the control room, safe shutdown capability is provided by a procedure that describes the (2 operator actions necessary to achieve hot shutdown conditions.

The procedure uses four plant personnel exclusive of the fire brigade and provides for local 2 control of a charging pump, auxiliary feedwater pump, and service water pump;local operation of a diesel generator; and local indications for process monitoring.

Reactivity control, reactor coolant makeup control, and primary system pressure control will be provided by the charging system in conjunction with the refueling water storage tank and the pressurizer safety valves.Initial decay heat removal will be provided by a turbine-driven auxiliary feedwater pump and the atmospheric dump valves.The condensate storage tanks 2 and service water will ensure a long-term supply of water for the auxiliary feedwater pump.Diesel generators and the service water system will provide the necessary support services.The process monitoring function will be provided by the following instrumentation:

reactor coolant hot and cold temperature, reactor coolant system pressure, pressurizer level, and steam generator pressure and level.Additionally, turbine-driven auxiliary feed-water flow and source range neutron monitoring are available.

 

GINNA/UFSAR coolers for each diesel generator.

The service water lineup is made reliable by ensuring that the service water crossover valves remain open at all times.This ensures that no matter which service pump is selected to automatically start'during an emergency, and no matter which diesel starts, the diesel that is running will receive cooling water.The 1A and 1C service water pumps are powered from bus 18 which can be supplied by diesel generator 1A.A selector switch in the screen house allows selection of either pump to automatically start.The 1B and 1D service water pumps receive their power from bus 17 which can be supplied from diesel generator 1B.Another selector switch in the screen house is provided for this set of pumps automatic start feature.An alternative means for diesel generator cooling is provided via a valve installed in the service water cooling to each diesel generator.

The valve allows the connection of fire.hoses from a fire hydrant located outside the turbine building in case of failure of the service water pump during diesel generator operation.

The cooling water is heated by jacket water heaters.Below each diesel is a subbasement which contains the buswork for that diesel.To prevent flooding of this area, a vault pump is provided for each diesel.This runs automatically as required to remove any accumulation of water.9.5.6 DIESEL GENERATOR STARTING SYSTEM The diesel generator starting system is shown in Figure 9.5-5.Two air receivers are provided to start each diesel.The receivers for each 7 diesel are charged by a 480-V air compressor.

Diesel generator 1A air compressor receives its power from the motor control center which can be supplied from diesel generator 1B.Diesel generator 1B air compressor receives its power from the motor control center which can be supplied from diesel generator lA.Each air system is utilized to crank the diesel with air to start the diesel within 10 sec.The compressors will automatically start at 220 psig to charge the receivers, and will automatically stop at normal receiver pressure of 245 psig.A relief valve set at 275 psig provides overpressure protection.

9.5-29 REV 7 12/91 GINNA/UFSAR Starting air at 245 psig is supplied to two air regulators.

The air regulators reduce the pressure to 140 psig to supply the air distributors.

Nominal air pressure required for starting the engine is 80 to 150 psig.Parallel dc-powered solenoid valves will open to admit air to the air start motor for each diesel.One solenoid valve is supplied from battery 1A and the other from battery 1B.The diesel air start systems can be cross-connected by two valves in series.Periodic testing requirements of the diesel generator starting systems are provided in the Technical Specifications.

9.5.7 DIESEL GENERATOR LUBRICATION SYSTEM A simplified diagram of the diesel generator engine lubrication system is shown in Figure 9.5-6.Lubrication of the engine is accomplished by a prelube pump 3 and an engine-driven lube-oil pump.The engine must be kept prelubed and preheated to provide immediate starting.A sensor is provided for each diesel generator to detect the loss of prelube oil and to alarm on this condition.

When'he engine starts, the prelube pump and heater are deenergized and the engine-driven lube-oil pump provides oil flow.9.5.8 DIESEL GENERATOR COMBUSTION AIR INTAKE AND EXHAUST Fresh air for combustion is drawn into the engine through a filter and distributed to the cylinders by an air intake manifold.Correct air to fuel ratio is maintained by sensing the manifold gas pressure and throttling air intake dampers according to the diesel load and speed.Turbocharging is used to increase flow or volume of air.This consists of a turbocharger driven by exhaust gases of the engine.Compressing the air with the turbocharger increases the temperature of the air.Since air intake temperature should be j as low as possible for maximum operating efficiency, the air must be cooled before entering the cylinders.

The system is shown in Figure 9.5-5.9.5-30 REV 7 12/91 GINNA/UFSAR REFERENCES FOR SECTION 9.5 1.Rochester Gas and Electric Corporation, Technical Supplement Accompanying Application for Full-Term Operating License, August 1972.2.Letter from L.D.White, Jr., RG&E, to A.Schwencer, NRC,  

Fire Protection at R.E.Ginna Nuclear Power Plant, dated February 24, 1977.3.Letter from D.L.Ziemann, NRC, to L.D.White, Jr., RG&E,  

Transmittal of Fire Protection Safety Evaluation Report (enclosure), dated February 14, 1979.4.Letter from D.M.Crutchfield, NRC, to J.E.Maier, RG&E,  

Supplement 1 to Fire Protection Safety Evaluation Report, dated December 17, 1980'5.Letter from D.M.Crutchfield, NRC, to J.E.Maier, RG&E,  

Supplement 2 to Fire Protection Safety Evaluation Report, dated February 6, 1981.6.Letter from D.M.Crutchfield, NRC, to J.E.Maier, RG&E,  

Fire Protection, Ginna, dated June 22, 1981.7.RG&E Appendix R Conformance ReviewGinna Station, Spent Fuel Pit Bridge Crane Cable, Number WR/TR 9020864, Revision 0, dated March 2, 1990.8.Letter from L.D.White, Jr., RG&E, to D.M.Crutchfield, NRC,  

Fire Protection at R.E.Ginna Nuclear Power Plant, dated June 4, 1980.9.Letter from L.D.White, Jr., RG&E, to D.L.Ziemann, NRC,  

Fire Protection at R.E.Ginna Nuclear Power Plant, dated May 15, 1978.10.R.E.Ginna Nuclear Power Plant Fire Protection Plan, dated April 29, 1986.11.Letter from J.E.Maier, RG&E, to D.M.Crutchfield, NRC,  

Transmittal of Appendix R, Alternative Shutdown System, dated January 16, 1984'.5-31 REvi u/91 i GINNA/UF SAR REFERENCES FOR SECTION 9.5 (Continued) 12.Letter from R.W.Kober, RG&E, to W.Paulson, NRC,  

10 CFR 50, Appendix R, Alternative Shutdown System, Revision 1, dated October 4, 1984.13.Letter from R.W.Kober, RG&E, to J.A.Zwolinski, NRC,  

Appendix R, Alternative Shutdown System, dated January 16, 1985.14.Letter from J.A.Zwolinski, NRC, to R.W.Kober, RG&E,  

Safety Evaluation for Appendix R to 10 CFR Part 50, Items III.G.3 and III.L, dated February 27, 1985.'5.Letter from J.A.Zwolinski, NRC, to R.W.Kober, RG&E,  

Exemptions to Section III.G of Appendix R, dated March 21, 1985.9.5-32 1>/91~

GINNA/UFSAR Table 9.5-1 FIRE SERVICE WATER HOSE REEL LOCATIONS Hose Reel Number~Buildin Turbine urbine Tu bine Turb'Floor Basement Basement Basement Basement Locatio Elevator Battery oom Oil s orage room St am generator feed-water pumps 8 10 12 13 14 15 16 17 18 19 20 21 23 Turbine Turbine Turbine Turbine Turbine Turbine Turbine Intermediate Intermediate Intermedi e Interm iate Int ediate termediate Intermediate Intermediate Intermediate Intermediate Auxiliary Auxiliary Intermediate Intermediate Intermediate Intermedi e T bin Tur ne rbin Level fou Level four Level three Level three Level two Level two Level one Level one Level one Level two Operating Operating Elevator 4160 bus Air ejector 5A heater Elevator Control room North wall West East East West West E t East West South Nuclear sam e room West Center 9.5-33 REV 5 12/89 GINNA/UFSAR Table 9.5-1 FIRE SERVICE WATER HOSE REEL LOCATIONS (Continued)

Hose eel Numbe 24 25 26 27 28 29 30 3255 34 35 36 37 38 39 4O~Building Auxiliary Auxiliary Auxiliary A iliary Auxi iary Auxili y Auxiliary Screen house All-volatile-treatment building Containment Containment Containment Containment Containment Containment Service Servic Floor Operating Intermediate Intermediate Intermediate Basement Basement Basement Main Resin tank, ea Ope at g Oper ng M zanin ezzanine Basement Basement Main Ground Location East East Cente We est Center East Fire pumps Northwest center Vest East Vest East West East North hall orth hall 41 All olatile-tr atment ilding Technical support center Ea 42 All-volatile-treatment building Technical support center West: 9.5-34.REV 5 12/89 (PROM TECHNICAL SpECIFICATIONS 6.2.2)9.5.1.2.5.2 Insert A: Fire Brigade of 5 members shall be maintained on site at'll times.This excludes the two members of the minimum shift crew necessary for safe shutdown.Insert B: Fire Brigade composition may be less than the minimum requirements for a period of time not to exceed 2 hours to accommodate unexpected absence of Fire Brigade members provided immediate action is taken to restore the Fire Brigade to the minimum requirements.

GAH/244 GINNA/UFSAR INSERT'9.5.1.3 0 erabilit and Surveillance Re uirements Table 9.5-2 lists the operability requirements for the Fire Protection Systems, required actions.to be taken when equipment is inoperable and surveillance.

These requirements were previously'ncluded in the Ginna Station Technical Specifications (Appendix A to Operating License DPR-18)but were-removed in accordance.

with Generic Letter" 86-10, Implementation of Fire Protection Requirements:

and.Generic Letter 88-12, Removal of Fire Protection Requirements.

from Technical Specifications.

The bases for the requirements.

listed in Table 9.5.-2 are described in sections 9.5.1.3.1 through 9.5.1.3.4.

The list of spray and/or sprinkler systems shown on Table 9.5-4 are required to be operable.when the, equipment; in.the area.is required to be operable.9.5.1.3.1 General[From TS Bases 3.14(1)]The fire protection.

system has the capability to extinguish any probable fire which might occur at the station.The system, is designed in accordance.

with the standards of the National Fire Protection Association.

[From TS Bases 3.14(2)]Procedures have been developed for fighting fires in all.the plant areas and are contained in the plant's emergency procedures..

Fire prevention is controlled by administrative methods to prevent accumulations.

of combustible materials and to practice good safety methods.Periodic, practice.exercises.

will be employed to insure plant personnel are familiar.with the proper corrective procedures.

[From TS 4.15(1)]Bases Sufficient tests, will be made to.be certain that fire detection instruments and associated circuitry are operable such that fires'n areas which would jeopardize., the safe shutdown of the plant are detected.Page 9.5-xx 9.5.1.3.2 Fire Detection System[From TS 3.14(3)]Bases Detection is located in all areas of the plant containing safety related equipment and in areas, containing large amounts of combustible or flammable.

Actuation of fixed suppression systems and early warning'alarms are.provided by'hese detectors.

The list of instruments required to be operable for fire detection and their locations.

are shown.on Table 9.5-3.9.5.1.3.3 Fire Suppression System (Water, Spray and/or Sprinklers, Halon, Fire Hose Stations, and Yard Loop)[From TS Bases 3.14(5)]Normal fire protection is provided by a fixed-fire fog system, fixed.Halon.1301 system, sprinklers, hose lines, and portable and wheeled extinguishers suitably.located in the required areas:.[Prom TS Definition 1.11]The fire suppression water system consists.of Lake Ontario water supply, pumps and.distribution piping'ith associated sectionalizing control or isolation valves.Valves include valves between.the fire pumps, and the first valve ahead.,of the water flow.alarm.device-on, each sprinkler., or spray system riser.[From-TS 3.14(7)]Bases.Water to the fire system is supplied via the header by two vertical, centrifugal fire pumps of 2000 gpm capacity each.One of these pumps.is driven.by an electric.motor and the other by a combustion engine:.Both, are automatic starting through.fire.pump controllers.

with indication, alarm and manual.starting from the central.control room fire panel.The combustion engine local fuel supply capacity is designed for 8.hours of operation.

[Prom TS Bases 3.14(8)]A fire header is installed of sufficient size to deliver an adequate quantity of water throughout the;plant: at a.pressure of no less than 75 psi at the highest nozzle.Page 9.5-xx  

-,II'a g

[Prom TS 3.14(9)]Bases The header system is normally pressurized through'he.use of a hydro-pneumatic tank using.house service air and.having an active water capacity of 10,000 gallons Loss of header pressure and/or opening of.any deluge system'.activates the fire pumps and the alarm system.[Prom TS'ases.3.14 (10)]A backup fire suppression water.system would.be.used to provide protection in the event.the.fire suppression water system were inoperable A,backup system could, for example, be comprised of a backup pump, and, yard hydrant system supplying water to wall hydrants, or other equipment or measures.[Prom TS 3.14(6)]Bases Readily accessible 1-1/2 inch rubber covered.hose lines.and continuous, flow.type hose.reels;are distributed throughout the station: so that all.areas.in the station: are within.20 feet.of a.fog.nozzle when attached: to not.more than: 125 foot lengths: of hose.All nozzles.are.1-1/2 inch variable fog-off nozzles.[Prom TS Bases 3.14(11)]The yard hydrant.on.the south-east:.

corner of the yard.loop provides.the secondary fire suppression capability.

for the transformers and.the primary fire suppression capability for the standby auxiliary feedwater building..

[From TS 4.15(2)]Bases, The fire suppression.

water system testing will assure the.capability of.the system to meet its.requirements..

[From-TS 4.15(3)]Bases The Halon System is used to protect those-areas.that.would, be.damaged.by the use..of.water.The.90't of full.charge pressure, is, based on.a temperature of 70'F.Pressures at temperatures.

other than 70'F will be corrected by.Chart ULE.2671 March 1, 1973 ANSUL 1301 Clean Agent Pree Contro1 System Manual.P/N17210-02,.

9.5.1.3.4 Fire Barrier Penetrations

[From TS 3.14(4)]Bases.Fire barriers are located throughout the.plant to separate major areas: from each other.and.

also;to separate=Page 9.5-xx  

certain safety related areas from the remainder of the plant.These are designed to stop a fire from propagating from.one area.to another.All penetrations in these barriers are sealed.with appropriate.

materials to match the requirements.

of the barrier.[Prom TS Bases 4-15(4)3 Visual inspection.

of fire barrier penetration seals will be made to insure.the containment of any fire that may start until it can be extinguished either automatically or manually.There are no fire.barriers'hat.

perform a pressure sealing function.Page 9.5-xx I

Qe GINNA/UFSAR Table 9.5-1 FIRE SERVICE WATER HOSE REEL LOCATIONS AND.OPERABILITY Hose Reel Number Buildin Floor Location Required to 5 6 7 8 9 10 11 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 Turbine Turbine Turbine Turbine Turbine Turbine Turbine Turbine Turbine Turbine Turbine Intermediate Intermediate Intermediate Intermediate Intermediate Intermediate.

Auxiliary Auxiliary Auxiliary Auxiliary Auxiliary Auxiliary Auxiliary Auxiliary Auxiliary Screen House All-volatile-Treatment Bldg Basement Basement Basement Basement Intermediate Intermediate Intermediate Intermediate Turbine Turbine Turbine Level Four Level Four Level Three Level Three Level Two Level Two Level One Level One Level One Level Two Operating Operating Operating Intermediate Intermediate Intermediate Basement Basement Basement Main Resin Tank Area Elevator Battery Room D/G Rooms Steam: Generator, Foedwater Pumps Elevator 4160 Bus Air, Ejector 5A Heater Elevator Control Room North Wall West East East West West East East West South Nuclear Sample Room West Center East East Center West West Center East Fire Pumps Northwest Center X x x X x x x X x x x x x X x x x x x x x x*See Table 9.5-2 for Required: Actions if Inoperable Page 9.5-xx  

GINNA/UP SAR Table 9.5-1 PIRE SERVICE WATER HOSE REEL LOCATIONS AND OPERABILITY (continued)

Hose Reel Number 33 34 35 36 37 38 39 40 41 42~Buildin Containment Containment Containment Containment Containment Containment Service Service All-volatile-Treatment Bldg All-volatile-Treatment Bldg Floor Operating Operating Mezzanine Mezzanine Basement Basement Main Ground TSC TSC Location West East West East West East North Hall North Hall North South Required to be 0 erable x x x x x x*See Table 9.5-2 for Required Actions if Inoperable Page 9.5-xx Table 9.5 2 PIRE PROTECTION STSTEM REQUIREMENTS Page I of I STSTI)5 1.Fire Detection Instruments REQUIREMENT Instzuxentatfon for each fire detection xone shown fn Table 9.5-3 shall be operable.AP PLICARIE NODES At all times.Chub I TION Any of the fnstruments ln Table 9.5-3 fnoparable.

REQUIRED ACTION a.l Outsfde contairtaent 4)Establfsh an hourly fire vetch fn the affected fire xone>except during emergency conditions vhfch prohibit 4cceas~b)Restore to operable status ot c)Prepare and submit a Special RepOZta Our lfnfng the Cacao Of the lnoperablllty and plans for restorfny the instru-ments(s)to of>>table status b.l Inside contafment a)Inspect affected contafnmant xone once every d bours or b)aenltor contafnment air temperature at least once pet hour at~minimum of 16 representative locations TINE REQU I Rf)5ENT a)Nithfn I bout b)Mithfn 14 days c)Mlthfn next 30 days 4)Nfthfn I hour b)Nithfn I hour TESTINCI INSPECTION REQUIREMENT a.2 The fire detection instruments listed ln Table 9.5 3 which are accessible during plant operation shall be dlmlonatzk'ted opetabl~by performance of tests at least on<<e every sfx months Fire detectots vhfch ate 5>>t accessible durfny plant of>>ration shall be dea>>nstrated operable by th~performance of tests during each cold shutdown exceeding 24 hours unless pazfozme4 ln the previous 6 months.The functional test for RTD detectots inside containmant vill be performed by vetlfylny detector circuit continuity and detector temp>>rature Indication fn the control zoom.b.2 The supervised circuits supetvisfon associated vfth the detector alarms of each of the detection fnstruaents listed fn Table 9.5-3 vhlch are accessible during plant operation shall be demonstrated opERABIE at least once per 6 months.The non-supervised cfrcults betveen the local alarm panels and the control room shall be demonstrated OPERASIE at least once per 31 days.Circuit supervision vhfch 14 not accessible during plant, operation shall be dmaonatrated operable by the performance of teats durfny each cold shutdown exceeding 24 bours unless performed fn'the 14at 6 alon'ths~4)restore to operable status ot prepare and submit a Special RepOttv Outlfnfng the Camas Of the fnoparabilfty and plans for restoring the fnstzut>>st is)to operable 4'54'tua c)Nfthfn 14 days d)Mithfn next 30 days~Special Report are submitted fn accordance vlth 10 CFR 50.4  

~iran v r l'Table 9.5 2 FIRE PROTECTION STSTEM REQUIREMENTS Page 2 of 7 1 Fire Suppression Niter Systea REQUIREMENT The fire suppression vater systslk Shall be operable vithi a)two fire pusps each w(Ch k ckPac)Cy of 2000 gps with their discharge aligned to tha fire suppression header.b)Aucoaatlc lnitiatlon logic for each fire APPEICABIE MOOTS At all tfaes CONDITION a.Nfth an inoperable redundant coa(>>nant b.Nfth the fire suppression vater systea lnopetkble a.2 b.l b.2 b 3 a)b)c)b)REQUIREU ACTION In the operatfay s>>de restore the inoperable coaponent to oi>>rable status or Rua the reaainfnq pusp continuously and Prepare and suhaft a Special Repotti outllalng the cause of Cha inoperability and plans for restoring cha coaponent to operable sckcus~In cold or refaelfng shutdown Restore'Che fnoj>>table coaponent to operable status ot Prepare and sukait a specie]Repotte ou'clfnfng the cause of tt>>inoperability and plans for testorfny the coaponent to operable s'titus'stablfsh a backup fire suppression vater systea ot Place the reactor in Mot Shutdova and In cold shutdown TINE REQUIREMENT a)within 7 days b)Until the inoperable coaponent fs restored to operable scat'us c)Nfthfn the sext 30 days a)Nithfn 7 days b)within the next 30 days b.l within 2k bouts b.2 Nfthfn the next 6 hours b.3 Nithfn tha next 30 hours TESTIMC/INSPECTION REQUIREMENT The fire suppression vater system shall be denonatrated operable: a.2 At least once per 31 days by starting each pusp and operatinq lt for at least 15 Minutes on tecfrcalatfon flov.b.2 At least once per 31 days verlfylng that each Valse (aanual, paver Operated, Or auteaktfC) fa tbe flOv Pkthk la ln fta COrreCt POSltlOS.c.2 At least once per 31 days by vetffyfsy tbe level of tbe diesel driven fire pxsp fuel tank.4.2 At least once per 31 days by fnspeecfng and tastfnq the diesel fice pusp startlaq batteries'to de'Celsius

'Cf>>coadiCfon of'Che battery cells.~.2 At least once pet 92 days by verifying that a saaple of diesel fuel frclk the diesel fire puap feel oil day tank fs within the ASIN D915 reccxvaaaded i(sits for nunber 2 diesel fuel oil vhea cheCked for vlseosfty, water and sedfaent.f.2 At least once per year by cyclfnq each testable valve fn the flow path (except for hydrant isolatfoa valves)through at least ona eoaplace cycle of fall travel.A further exception ls the contains>>nt isolation valve vhfch shall ba dose at a ainiaua of at last once per IS tkonths.0.2 At.least opce per ld aonths by perforafnq a systea functional test vhfch includes sfaulated actuation of tbe syscear throughoat fts operating sequence, and)(1)verifying that each aatcaatfc valve fn the flow path actuates to fts cotrect position oa k'CssC slgnkl)(11)verifying that each fire puap develops at least 2000 gpa at 210 Ft.Hd.)(iff)cycling each valve fn the flov path that ls not testable durfny plant operation through at least one cospfete cycle of fall travel)(fv)ver(fylng that each high pressers puap starts (segaentlally) to Maintain the fire suppression vater systea pressure kt or above 210 Ft Md h.2 At least once psr IS aonths by subletting the diesel engine to an faspeetfon fn accordance with procedures prepared fa con)unct)on vfth fts aaaafaetarar's recess>>ndatlons for the class of service.~Specfal Reports are subaftted in~ccordance with IOCFRfa.k.

1.2 At least ones avery 3 years a flow test of the fire suppression vater systea shall be perfotaed with ol>>fits pusp rivaling tbe static pressure vill be recorded at the test connection for the fire suppression water n 1 Table 9.5-2 FIRE PROTECTION SYSTEM REQDIREMENTS page 3 of 7 SYSTEM 3.Spray and/or Sprinkler Systeo Spray and/or Sprinkler Systeos shovn on Table 9.5-4 shall be operable AT 9 LICASIX MODES lihenevet the equ)poeot being ptotect4d 14 requ)red to be operable CONDITION Any of the systesls shown on Table 9.5-S inoperable RECDIRED ACT I CN~.1 Those areas in vhlch redundant systens ot ccoponents necessary for safe shutdown could be daoaged.a)Establish a continuous fire vatch vith backup fire suppression equ)poenti except during eoergeocy conditions which prohibit aecesss or for testing.b)Restore'th4 inopetable

~ysteo to op4table status 0 1'IME RE001 RI2IENT 4)Nithin 1 hour b)Nithin IS days'ESTIMC/INSPECTION RECUIREMENT a.2 The spray systeos shall be deoonstrated to be operablei a)At least once per 12 Months by verifying the loss of locking pressure Manual operation.

b)At least once per 18 Months)il)By petfornlng a systen functional test vhlch iocludes s)on)Sting actuation of the systen and verifying that the valves in the flow path are capable of going to their correct positions.

ill)hy visual external inspection of spray headers to verify their lntegrlty.

iiii)hy visual external inspection of eaehnoxsle to verify no blockage.c)Trapeze and subsit a Specie)Report'utlining the cause of the looperabillty and plans for restoring the systeo to operable status, b.l Ocher plant areas)Establish a fire vetch patrol to inspect the zone vith the Inoperable systeo at least once per hour and place backup fir~suppression

~quipleot ln the unprotected area (4)g~xcept daring energeney conditions vhlch prohibit SCCSSSS Ot far teatiOg.b)Restore the inoperable sys'ten'to opetable status ot c)trepare and su)xsit a Special Report'utlining the cause of the inoperability and plans for restoring the systcn to operable statQS c)'Nlthln the next 30 days 4)Nlthin 1 hour b)Nlthln li days c)'Nithln the next 30 days e)At least once per 3 years by petforoing an air flov test through each spray heater and verifying each spray Sortie is unobstructed.

b.2 The sptinkjer systens shall be deoonstrated to be operable at least once per 12 nonths by opening the Inspectors test valves and verifying vat<<r flow and systeo alaro.~Special Reports are sukoitted in accordance vlth 10CFR50.4~  

'1'~Table 9.5 2 FIRE PROTECTION SISTI RfamREMENIS Page 6 of 7 V SYSTEM S.Melon Syston RECC I R EMENT Melon systens in the folloving areas shall be opetablo 4nd'tho stor4go tanks shall have at least 956 of the full charge veight arxl 905 of full charge pressure at 70eF a.CtNSLuter Roon (S07)b.Relay Rocll ISOS)APPEICASIE MODES Whenever the~quiplent in the area is required to bo operable CORO IT ION A halon systen inoperablo REQOI RED ACTION a,l Those areas in vhich redundant systens or conpononts necessary for safe shutdovll could be danagod.a)Establ ish a continuous fire vetch vith backup fire suppressioll ega)plenty oxcep'k dllrlng energency conditions vhlch prohibit access b)Restore the inoperable systsla to oper4blo status or c)Prepare and suklllt a Special Report'utlining the cause of ths inoperability and plans for restoring the syston to operable status b.l Other plant, areas 4)Establish a fire vetch patrol to lnspsct the xone vlth tho inoperable systen and place portable~qulplent ln the ullprotoctod 4rea(s)s except during osergency condltlons vhlch prohibit access.TIME REQQIR)ILENT 4).Within I hour b)within Ii days c)Within the next 30 d4ys 4)Within I hour TEST)WC/INSPECTICN REQQIREMENT Tho salon systen shall be delenstrated to bo operable: a.2 At least once per 6 sonths by verifying each Melon~'torago't4nk pressure b.2 At least once psr 6 nonths by serifylng each Melon storage tank velght.c.2 At least once psr IS nonths by ssrlfylng tbe systen including associated senti)ation daspers actuate in response to a s)hoisted actuation signal.A flov tost vith gas through headers and nottles shall be perforned to assure no blockage.The operability of tho nanual Initiating aysten vill also be verified L L~b)Restore the inoperablo systcn to operable status or c)Prepare and subnlt a Special Report+outlining the cause of the inoperability and plans for restoring th>>systen to operable status.b)Within Ii days c)Wlthln the next.30 days~Special Reports aro sukslitted ln accordance vith IOCFR50 6~p e

rCC"'>>E.C t.'f~v>>l.>>>>C~\~v C 1 Table 9.5-2 FIRE PROTECTION SIST))f REQOIREHEMTS Page 5 of 7 SYSTE)f Fire Nose Stations Fire hose stations iadicated on Table 9.5-1 shall be operable AP PL I CAR LE))00ES At all tines COHO IT ION Any of the hose stations regufted operable by T4ble 9.5-1.including vater service to then>>lnopetable REQOIRED ACTION 4 I Route 4 hose to'the unprotected area fron aa operable hose statfon except fot those stations inside contalnnent.

b.l Return the hose station to opetable st4tus ot c.l Prepare and su)xsft a Special Reports outllnlag the cause of the fnoperabf I fty and plans fot te~'toting'the systen to opet4ble st4'tus TINE REQOIRI))ENT a)Nithfn I hoot b)Nlthfn 14 days c)Mf thin the next 30 days TEST INC/INSPECTI CN REQOIREHENT Each Fire hose station listed in Table 9.5-1 shall be verified to be operable: a.2 At least once per neath by visual inspection of tbe station to assure all egufpneat is available and the fire vatet header systen pressure is recorded.The hose stations ia contafmeat are aa exception and shall be laspected once per Month during the refueling shutdovn b.2 At least once per 18 Months by unrolling the bose for Inspection and re-racking and replacing gaskets ln the coupllngs, as reqaired.c.2 At least once per 10 Months, partfally open bose station valves to vetlfy valve operability and no blockage.0.2 At least evety 3 years by pressure testing each bose to 50 psl greater than the Naxlnun Notklng Pressure~Special Reports are suhaitted ln accordance vith IOCFR50.4~  

~v Table 9.5 2 FIRE PROTECTION SIST)2)RECQIRDKMTS Pace 6 of 2 SYSTEM Fire harrier Penetration Fire battler penetrat)on fire seals vhich protect safety related areas shall be intact AP PLI CASIE NOOES At all tines CO!C)IT ION Any of the fire barrier penetratlons not iatact REOQIREO ACTI CN a.l Establish a cont)nuous fire vetch on one side of the penetration or b.l Establish an hourly fire vetch patrol and verify that fire detectors on at least one side of the lnoperabl~seal are ln service c.l Restore the systes to operable status or d,l Prepare and sutaalt a Special Report'utllnlnQ the cause of the inoperability and plans for restorinQ the oyster to operable status.TINE REOQIR)PC&#xc3;T a)Nlthin I hour b)Ml thin 1 hour c)Nlthln 1 days d)Nlthin the next 30 days TEST INC I IN SPECTI CN RECQI RENENT Penetration seals ln fire barriers vhlch protect a safety related area shall be Ter)fled to be intact by Tlsual inspect)out a.2 At least once per IS nonths, and b.2 Prior to declarlnQ a penetration seal ln a fire barrier intact follovinQ repairs or nalntenance.

~Special Reports are sutnltted in accordance vith IOCPR50 6 0~j~'t I I Table 9.S 2 FIRE PROTECTION STSTEM REQUIREMENTS Page T of 7 STSTEM Pard Fire Loop The yard hydrant on the southeast, corner of the yard loop shall be operable to provide fire protection to the transforners and the standby auxiliary fsedvatsr building.APPLICARIE NODES At all tines CD&#xc3;DIT ION The yard hydrant on the southeast corner of the yard loop inoperable REQUIRED ACTION a.l Place sufficient lengths of 2-1/2 inch disaster hose in an ad)anent operable hydrant hose house b.l Restore the systen to operable s'ta'cus or c 1 Prepare and suknit a SI>>clsl Report'utlining the cause of the Inoperability and plans for restoring the systen to operable status, TIME REQDI REMENT a)Nithin 1 boar b)Nithin IS days ct Nithin the next 30 days TESTING/INSPECT I CN REQDIREMENT The yard fire hydrant on the southeast corner of the yard loop and its associated hydrant hose house shall be denonstrated QPERABLEI s a.2 At least once per 31 days hy visual insi>>ctlon of the hydrant bose house to assur>>all required equ)Scent ls at the hose house.b.2 At lest once during March, April or May and once during septenr>>r, October or Novesber by visually inspecting the yard fire hydrant and verifying that the hydrant barrel ls dry and that the hydrant ls not dasaged.c.2 At least once psr 12 nonths by.li)Conducting a hose hydros'ta'tlc test at a pressure at least 50 psig greater than the sax)nun pressure available at the yard fire hydrant.ill)Replace>>eat of all degraded gaskets ln coupl ings.~Special Reports are subnitted ln accordance vith 10CFR50 i I~~a,  

GINNA/UF SAR TABLE 9.5-3 FIRE DETECTION INSTRUMENT OPERABILITy Instrument Location.Minimum Instruments.

0 erable***2.Containment a."A" Posh-Accident Charcoal Bank (Z09, Z10)b."B" Post-Accident Charcoal Bank-(Z11., Z12)c."A" Aux.Filter Charcoal Bank (Z06)d."B" Aux.Filter Charcoal.Bank (Z07)e.Cable Trays Basement Elev.(Z08)f.Cable Trays Intermed'.

Elev.(Z15) g.Cable Trays Operating Floor (Z16)h."A" RCP Intermediate Floor (Z13)i."B" RCP Intermediate Floor (Z14)j.Area Detection Operating.

Floor (Z16)Control Room a.Area and Cabinet: (Z19)b.Control Room/Turb.

Bldg.Wall (S29.)Heat 3*3*]*]*1**2**]***4'**N/A Smoke N/A N/A N/A N/A N/A N/A N/A N/A N/A 7 17 N/A 3.Relay Room (Z18, S08)Computer (MUX)Room Ceiling (S07)5.Battery Rooms A&B (Pyrotronics Zone 8)N/A N/A 16 6.7.8.Control Building a.Air Handling Room (S06)Diesel Generator a."A" Generator Room (S12)b."A" Generator Vault (Z20)c."B" Generator Room (S13)d."B" Generator Vault (Z21)Intermediate Building a.Motor Driven Aux.Fd.Pump Area (Z22)b.Turb.Driven Aux.Fd.Pump&Res..(S14)c.Cable Trays Basement North (S15)d."A" Purge Filter Elev, 315<4l'Z23)e."B" Purge Filter Elev.315"-4" (Z24)N/A 2 N/A 2 N/A N/A 1 N/A N/A N/A N/A 1 N/A 1 9 N/A 14 1 1 Page 9.5-xx GINNA/UFSAR TABLE 9.5-3 FIRE DETECTION INSTRUMENT OPERABILITy (continued)

Instrument Location Minimum Instruments 0 erable**" Heat Smoke 9.Screen House a.Area Detection Serv.Water Pump and Bus Area (Z26)b.Cable Trays Basement (S17)N/A N/A 11 4 10.Standby Auxiliary Feedwater Bldg.(Z25)11.Cable Tunnel (Z05, S05)N/A 10 12.Auxiliary Building a.General Area (Pyrotronics Zones 1,2,3)N/A b.Area Basement East (Z01)N/A'c.Area Basement West and RHR Pit (Z02)N/A d.Cable Trays/SI Pumps Basement (S01)N/A e.Penetration Area Cable Trays Mezz.(Z03)N/A f.Cable Trays, Elec.Cab.Mezz.Center (S03)N/A g.Cable Trays Mezz.East'(S04)