{{#Wiki_filter:NIAGARA MOHAWK POWER CORPORATION NINE MILE POINT UNIT 1 ATTACHMENT A SECOND TEN YEAR INTERVAL INSERVICE TESTING PROGRAM 6515G 890i310374 890ii8 PDR ADOCK 05000220 P PDC

NIAGARA MOHAWK POWER CORPORATION NINE MILE POINT NUCLEAR STATION UNIT 1 SECOND TEN YEAR INTERVAL PUMP AND VALVE INSERVICE TESTING PROGRAM PLAN APPROVALS SIGNATURES INITIALS AND DATE REVISION 1 REVISION 2 REVISION 3 Station Superintendent, NMPNS Unit 1 K.A.Dahlberg Manager, Nuclear Engineering, G.J.Gresock Manager, Nuclear Technology D.Greene (Acting)I.frs LC~~Qlg I I e Summary of Pa es.Revision 1 (Effective

~Pa es i, III-30-5 Date January 1989 THIS PROGRAM PLAN IS A GENERAL REWRITE NIAGARA MOHAWK POWER CORPORATION

PUMP AND VALVE INSERVICE TESTING PROGRAM PLAN TABLE OF CONTENTS SECTION I.O I.1.0 I.2.0 I.3.0 I.4.0 I.5.0 I.6.0 I.7.0 I.8.0 II.O II.1.0 II.2.0 II.3.0 II.4.0 II.5.0 II.6.0 II.7.0 III.O III.1.0 III.2.0 III.3.0 III.4.0 III.5.0 I I I.5.1 I I I.5.2 III.5.3 III.5.4 III.5.5 III.5.6 III.5.7 III.5.8 III.5.9 I I I.5.10 I I I.5.11 III.5.12 I I I.5.13 III.5.14 I I I.5.15 III.5.16 III.5.17 TITLE OVERVIEW Introduction Basis General Program Plan Concept Organization Def ini ti ons General Relief Request for Pumps General Relief Request for Valves References PUiMP IST PROGRAM PLAN Introduction Code Interpretation Pump List Pump Table Nomenclature Pump Test Table Pump Test Table Notes Pump Relief Requests VALVE IST PROGRAM PLAN Introduction Code Interpretation Valve Test Table Nomenclature Valve Test Table Format Valve Test Tables and Relief Requests Attachment 1: Main Steam System Attachment 2: Reactor Recirculation Attachment 3: Control Rod Drive Attachment 4: Feedwater/HPCI Attachment 5: Core Spray Attachment 6: Emergency Cooling Attachment 7: Reactor Shutdown Cooling Attachment 8: Containment Spray Attachment 9: Reactor Cleanup Attachment 10: Inert Gas Purge and Fill Attachment 11: Hydrogen-Oxygen Monitoring Attachment 12: TIP Attachment 13: Nitrogen Supply 811 Attachment 14: Nitrogen Supply 812 Attachment 15: Reactor Building HVAC Attachment 16: Liquid Poison Attachment 17: Spent Fuel Storage Pool Filtering 5 Cooling PAGE I-l I-2 I-3 I-4 I-5 I-6 I-7 I-12 I-19 II-1 II-2 II-3 Ij-4 II-5 II-1-1 II-1-5 II-1-6 III-1 III-2 III-3 III-7 III-9 III-I III-1-1 III-2-1 III-3-1 III-4-1 III-5-1 III-6-1 III-7-1 III-,8-1 III-9-4 III-10-1 III-11-1 III-12-1 III-13-1 I I I-14-1 III-15-1 III-16-1 III-17-1  

PUMP AND VALVE INSERVICE TESTING PROGRAM PLAN TABLE OF CONTENTS (Cont'd)SECTION I I I.5.18 III.5.19 I I I.5.20 III.5.21 III.5.22 III.5.23 I I I.5.24 III.5.25 III.5.26 III.5.27 III.5.28 III.5.29 III.5.30 Attachment 18: Attachment 19: Attachment 20: Attachment 21: Attachment 22: Attachment 23: Attachment 24: Attachment 25: Attachment 26: Attachment 27: Attachment 28: Attachment 29: Attachment 30: TITLE Sample Reactor Building Closed Loop Cooling Condensate Transfer Torus Vacuum Relief Emergency Service Water Emergency Diesel Generator Cooling Water Emergency Diesel Generator Air Start Emergency Diesel Generator Fuel Oil Transfer Waste Di sposal Breathing Air To Drywell Control Room Chilled Water, Control Room HVAC Instrument Air PAGE III-18-1 III-19-1 III-20-1 III-21-1 III-22-1 III-23-1 III-24-1 III-25-1 III-26-1 III-27-1 III-28-1 III-29-1 III-30-1  

PUMP AND VALVE INSERVICE TESTING PROGRAM PLAN for NINE MILE POINT NUCLEAR POWER STATION UNIT 1 SECTION I OVERVIEW Pages I-l through I-20 I-1 January 1989

This document presents the 2nd Ten Year Program Plan for Inservice Testing (IST)of Pumps and Valves at the Nine Mile Point Nuclear Station Unit 1 (NMPS-1)in compliance with the requirements of 10CFR50.55a(g) and Station Technical Specification 3.2.6.This Program Plan was prepared in accordance with the rules of the ASME Boiler and Pressure Vessel Code, Section XI, 1983 Edition, Summer 1983 Addenda.Although the 1st ten year inspection interval was not scheduled to end until December 1989, Niagara Mohawk voluntarily revised the program.The revi sed Inservice Testing Program ten year interval now runs concurrently with the revised Inservice Inspection ten year interval;to June 1996 (Reference C.V.Mangan, NMPC, letter to D.B.Vassello, NRC, dated September 13, 1983).I-2 January 1989

2.0 Basis In addition to the reference Code edition and addenda, the Program Plan has been prepared in compliance with the NRC guidance (except where exemption/

relief has been requested) contained in"Guidance for Preparing Pump and Valve Testing Program Descriptions and Associated Relief Requests Pursuant to 10CFR50.55a(g)", the November 1981 Draft Regulatory Guide"Identification of Valves for Inclusion in Inservice Testing Programs" and the August 1988 Draft Generic Letter"Inservice Testing for Pumps and Valves." These four documents provide the basis for selection of components, test requirements, relief.requests, and format.Regarding the inclusion of certain valves based on their Containment/Reactor Coolant Isolation functions; this program is inclusive of valves which are categorized as Isolation Valves as specified in the latest NMPC NMPl Appendix J Program.Current NMP1 practice is to perform Leakage Rate Testing in accordance with the NMPl Appendix J Program.Any changes to the Appendix J Program shall be incorporated into the IST Program Plan as applicable.

The information except individual valve maximum stroke times, requested by the reference documents has been included in this Program Plan.Maximum stroke times are determined for the appropriate valves and recorded in a separate NMP-1 document as they are established.

I-3 January 1989

~'Y Np 3.0 General Program Plan Concept The Program Plan specifies Section XI testing requirements for pumps and valves providing a safety-related function.The document which delineates safety-related components is titled Nine Mile Point Unit 1"g-List".By definition, a safety-related function is one that is required to assure: a)b)c)Integrity of the reactor coolant pressure boundary;Capability to achieve and maintain safe shutdown;Capability to prevent or mitigate the consequences of postulated accidents which could result in off-site exposures comparable to the guidelines of'10CFR Part 100.The selection criteria used for components included in this Program Plan are safety-related active components as delineated in the"Nine Mile Point Unit 1 g-List." Safety-related passive components have no operability test requirements and are not included in the Program Plan.Only those safety-related passive components which have leakage requirements shall be included in the Program Plan.Station Technical Specifications, special manufacturer's tests, system operating conditions, etc., may dictate additional components which should be included in the overall station testing program, but whose functions fall outside the criteria above, and are, therefore, not addressed by this Program Plan.Section XI requires quarterly testing of components unless it is a burden to do so.This program specifies quarterly testing of pumps and valves unless it has been determined that such testing would: a)Render a safety-related system inoperable; b)Cause a reactor scram or turbine trip;c)Require significant deviations from normal operations; d)Require entry into inaccessible station areas;e)Increase the possibility of an inter-system LOCA.Each component excluded from quarterly testing has been analyzed to determine when appropriate testing may be performed.

If operation of a valve is not practical during station operation, the Code allows part-stroke exercising during normal station operation, and full-stroke exercising at cold shutdown.Since the Code allows testing at cold shutdown, this program does not request relief for those valves for which testing is delayed until cold shutdown, The Valve IST Program Plan does provide a justification for the delay of testing until cold shutdown.These justifications are prepared in a format similar to relief requests, and are included following the Valve Test Tables for each system.Where it has been determined that testing is not practical during station operation, or at cold shutdown, a specific relief request has been prepared.Each specific relief request provides justification for not performing the Code required testing, and provides appropriate alternative testing.In addition to specific relief requests, general relief requests which address specific Code requirements found to be a burden for this station have been prepared.Because of the general nature of these relief requests, and the number of components involved, they are presented in separate sections and are not repeated in the individual system sections.I<<4 Januar y 19S9

4.0 Organi zation The Pump and Valve Inservice Testing Program Plan is organized into three sections.Section I presents the general program commitment basis, the conceptual framework used in developing the Program Plan, and general relief requests for Code requirements found to be a burdeh for this station.Section II deals specifically with the Pump Test Program, and Section III deals specifically with the Valve Test Program.Section II and III are formatted in a manner to aid review.Each section summarizes the bases and concepts used to formulate the Pump and Valve Test Tables.Pump testing requirements are summarized in a single Pump Test Table attached to Section II.Valve test requirements are summarized in Valve Test Tables attached to Section III.The Valve Test Tables are arranged into separate attachments for each system.Where quarterly testing has been found to be impractical, either a justification for delay of test to cold shutdown, or a relief request, is provided following the appropriate Pump or Valve Test Tables.In those cases where additional discussion of the test requirements for a component is needed, the remarks column of the Test Table contains a Note Number.These Notes may be found following the Valve Test Tables for each system.I-5 January 1989

The terms below, when used in the Inservice Testing Program Plan, are defined as follows: quarter ly: Cold Shutdown: An interval of 92 days for testing components which can be tested during normal plant operation.

Testing deferred until cold shutdown shall commence within 48 hours of achieving cold shutdown, and shall continue until testing is complete or until the plant is ready to return to power.Completion of cold shutdown testing is not a prerequisite to return to power.Any testing not completed at one cold shutdown shall be preferentially scheduled for testing at subsequent cold shutdowns.

Cold shutdown testing of a component is not required if less than 92 days have passed since the last cold shutdown test of that component.

For scheduled outages greater than 14 days, all cold shutdown tests shall be performed; testing does not have to commence within 48 hours.Refueling:

Period: Testing deferred to refueling will be performed during the normal scheduled refueling shutdown before returning to power operation.

Category C safety and relief valves (IWV-3511), Category 0 explosive actuated valves (IWV-3610) and Category 0 rupture disks (IWV-3620)are periodically tested as defined in the appropriate Code Sub-Sections.

Pressure Isolation:

Active: Passive: Any valve which acts as an isolation boundary between the high pressure Reactor Coolant System and a system having a lower operating or design pressure.Any valve which performs a containment isolation function and is included in the Appendix J Leakage Rate Test program.Any'valve which is required to change position to accomplish its safety-related function.Any valve which is not required to change position to accomplish a specific function.I-6 January 1989

6.0 General Relief Requests for Pumps This section requests relief from specific requirements of Section XI found to be a burden for Nine Mile Point Unit 1.Since they are general in nature, and pertain to a number of components, this section requests general relief as presented below.The relief requests do not appear in the Pump Test Table except for bearing temperature and for vibration relief requests.General Relief Request: Pumps: Test Requirements:

Basi s For Rel i ef: Alternate Testing: PG-1 Al 1 Table IWP-3100-2, Acceptance Criteria Standard Industry practice is to use vibration velocity as a basis for the establishment of vibration reference values for pumps operating at normal speeds.Vibration velocity is used because it is independent of frequency in this RPM range.Thus yielding a simple reliable measure of the severity of the vibration.

In lieu of the code specified criteria, Nine Mile 1 will use the following Table: RANGES OF TEST PARAMETERS PUMP PUMP TYPE SPEED TEST PARAMETER ACCEPTANCE RANGE ALERT RANGE REQUIRED ACTION RANGE Centri fugal<600 rpm and Vertical Line Shaft Vd or Vv<2.5 Vr>2.5vr to 6Vr but not>10.5 mi1s>6Vr but not>22 mils>600 rpm Vv or Vd<2.5 Vr>2.5vr to 6Vr but not>0.325 in/sec>6V but not>0.70 in/sec Reciprocating Vd or Vv<2.5 Vr>2.5Vr to 6Vr>6Vr NOTE: 1)Vr is vibration reference value in the selected units.2)Vv is vibration value in velocity.3)Vd is vibration value in displacement.

I-7 January 1989

6.0 General Relief Requests for PumpsGeneral Relief Request: Pumps: Test Requirements:

Basis for Relief: Alternate Testing: PG-2 Emergency Service Water, Reactor Building Closed Loop Cooling Water, Core Spray, Emergency DG Cooling Water, Containment Spray, Containment Spray Raw Water, Condensate Transfer and Emergency Diesel F.O.Transfer Measure pump suction pressure, Table IWP-3100-1 Instrumentation is not installed for measuring pump suction pressure.However, the suction pressure can be calculated by measuring the level of the applicable supply, (eg., torus water level, condensate storage tank level, diesel F.O.storage tank level or lake level)and the elevation of the pump suction and taking the difference.

The difference is the suet>on pressure in feet of head, which is then converted to pressure in pounds per square inch.Calculate suction pressure from the level of the suction supply.I-8 January 1989

6.0 General Relief Requests for Pumps General Relief Request: PG-3 Pumps: Emergency Service Water, Reactor Building Closed Loop Cooling Water, Core Spray, Emergency Oiesel Generator Cooling Water, Spent Fuel Pool Cooling, Containment Spray Raw Water, Containment Spray, Condensate Transfer, and Emergency Oiesel Generator Fuel Oil Transfer Test Requirements:

Basis for Relief: Alternate Testing: Neasure pump inlet pressure before pump startup and during the test, Table IWP-3100-1 These pumps use lake water or applicable tank contents as a fluid medium, and the change in supply level is negligible throughout the duration of testing.Inlet pressure shall only be measured or calculated once.I-9 January 1989

6.0 General Relief Requests for Pumps General Relief Request: PG-4 Pumps: Test Requirements:

All Measure pump bearing temperature yearly, Table IWP-3100-1 Basis for Relief: Alternate Testing: The measuring of bearing temperatures, along with vibration monitoring are both means of determining the mechanical condition of a pump.However, the condition of a pump bearing would have to seriously degrade to cause a detectable rise of temperature on the bearing housing.With the improved vibration monitoring program employed at NMPl, the ability to detect very small changes in the mechanical condition of a pump exists.Therefore, any degradation of a bearing would be detected before an increase of temperature on the bearing housing occurred.Pump mechanical condition will be determined by the enhanced vibration monitoring program.Bearing temperatures will not be measured.I-10 January 1989

6.0 General Relief Requests for Pumps General Relief Request: Pumps: Test Requirements:

PG-5 All Table IWP-4110-1, Acceptable instrument accuracy requires a pressure instrument accuracy of+2X of full scale Basis for Relief: Al ternate Testing: NNPl uses pressure sensing instrumentation which meets the acceptable instrumentation accuracies defined in Table IWP-4110-1.

The total loop accuracy from the sensing device to the final readout device will not meet the instrumentation accuracies of Table IWP-4110-1.

A threshold loop accuracy value of+3X shall be established which does not significantly exceed Section XI limits and should be sufficiently repeatable from test to test to allow for evaluation of the pump hydraulic condition and for the detection of pump degra-dation.For instruments that exceed this threshold loop accuracy value, temporary test instrumentation will be used.An engineering evaluation shall be made to add permanent pressure instrumentation for the individual pumps.Permanent and temporary pump pressure instrumen-tation shall be used until a permanent modifica-tion (1991)is performed.

I-11 January 1989

7.0 General Relief Requests for Valves This section requests relief from specific requirements of Section XI found to be a burden for Nine bile Point Unit 1.Since they are general in nature, and pertain to a number of components, this section requests general relief as presented below.These relief requests do not appear in the applicable system valve test tables.General Relief Request: Valves: VG-1 Rapid actuating power operated valves with stroke times of 4 seconds or less Category: Test Requirements:

A, 8 IWV-3417 requires corrective action if the measured stroke time for a valve which normally strokes in ten seconds or less increases by fifty percent from the last measured stroke time.IWY-3413 allows measurement to the nearest second for stroke times of ten seconds or less.Basis for Relief: Alternate Testing: For rapid actuating power operated valves the application of the above criteria could result in requiring corrective action when the valves are functioning normally.These valves are generally small air and solenoid operated valves which because of their size and actuator types stroke very quickly.Operating history on this type of valve indicates that they generally either operate immediately or fail to operate in a reasonable length of time.The intent of the referenced Code sections is to track valve stroke time as a means of detecting valve degradation.

This type of valve does not lend itself to this tracking technique.

Historical valve stroke time results for rapid acting valves has been collected and analyzed.Based on the results of this analysis, two separate acceptance criteria will be established.

Rapid acting solenoid valves will be those that operate in 2 seconds or less.Rapid acting piston and diaphragm valves will be those that operate in 4 seconds or less.If stroke times fall within these limits, the results will be acceptable.

If stroke times exceed these limits, the valves will be considered inoperable and corrective action initiated in accordance with IWV-3417(b).

I-12 January 1989

7.0 General Relief Request for Valves General Relief Request: Valves: Category: Test Requirements:

Basis for Relief: Alternate Testing: VG-2 Containment Isolation Valves A, AC Leak rate test in accordance with Subsection IWV-3421 through 3425 and IWV-3427(b).

Containment isolation valves are required to be leakage rate tested in accordance with 10CFR50, Appendix J.The leakage rate requirement is based on a total allowable leakage rate for all valves instead of an individual valve leakage rate.IWV-2200(a) defines Category A as"valves for which seat leakage is limited to a specified maximum amount in the closed position of fulfillment of their function." Although, leakage r ates for containment isolation valves are not limited on an individual basis, they have been determined to be Category A valves.Since containment isolation valves are Category A, the leakage rate testing requirements of IWV-3420 must be satisfied.

The leakage rate testing performed per Appendix J satisfies the intent of IWV-3421 through 3425, however, it does not satisfy the individual valve leakage r ate analysis and corrective actions of IWV-3426 and 3427.In order to prevent duplicate leakage testing of these valves, individual leakage rate will be obtained during Appendix J testing and the requirements of IWV-3426 and 3427(a)wi 11 be applied via separate procedure.

The usefulness of IWV-3427(b) does not justify the burden of complying with this requirement.

Containment isolation valves will be leak rate tested in accordance with the 10CFR50 Appendix J testing program.In addition, individual valve leakage rates will be obtained by test or analysis and the requirements of IWV-3426 and 3427(a)will be applied via a separate procedure for those valves that are Appendix J Type C tested.I-13 January 1989

7.0 General Relief Request for Valves General Relief Request: Valves: VG-3 Excess Flow Check Valves;(Identified by instrument line below)18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18020 18015 18015 18015 18015 18015 18015 18015 18015 18015 18015 18015 18015 18015 18015 X-29R X-29L X-30R X-30L X-31R X-31L X-32R X-32L X-28R X-28L X-43R X-43L X-37R X-37L X-36R X-36L X-35R X-35L X-34R X-34L X-41R X-41L X-44R X-44L X-42R X-42L X-38R X-38L X-47R X-47L X-82R X-82L X-71A X-71B X-71D X-71E X-71F X-720 X-72E X-133 X-72F X-53 X-72A X-72B Recirculation Pump'A'ifferential Pressure Recircu1 ati on Pump'A'i f f erenti al Pressure Recirculation Pump'B'ifferential Pressure Recirculation Pump'B'ifferential Pressure Recirculation Pump'C'ifferential Pressure Recirculation Pump'C'ifferential Pressure Recirculation Pump'O'ifferential Pressure Recirculation Pump'O'ifferential Pressure Recirculation Pump'E'ifferential Pressure Recirculation Pump'E'ifferential Pressure Recirculation Pump'A'low Recirculation Pump'A'low Recirculation Pump'B'low Recirculation Pump'B'low Recirculation Pump'C'low Recirculation Pump'C'low Recirculation Pump'O'low Recirculation Pump'O'low Recirculation Pump'E'low Recirculation Pump'E'low Recirculation Pump'A'eal Water Pressure Recirculation Pump'A'eal Water Pressure Recirculation Pump'B'eal Water Pressure Recirculation Pump'B'eal Water Pressure Recirculation Pump'C'eal Water Pressure Recirculation Pump'C'eal Water Pressure Recirculation Pump'O'eal Water Pressure Recirculation Pump'D'eal Water Pressure Recirculation Pump'E'eal Water Pressure Recirculation Pump'E'eal Water Pressure Total Recirculation Flow Total Recirculation Flow Reactor Vessel Water Level Reactor Vessel Water Level Reactor Vessel Instrumentation Reactor Vessel Instrumentation Reactor Vessel Instrumentation Reactor Vessel Instrumentation Reactor Vessel Instrumentation Reactor Vessel Instrumentation Reactor Vessel Level Reactor Vessel Level Reactor Vessel Level Reactor Vessel Level I-14 Janu ar y 1989 I 0 General Relief Request (Cont'd)General Relief Request: Valves: VG-3 (Cont'd)Excess Flow Check Valves;(Cont'd)PE ID Penetration Oescription 18002 18002.18002 18002 18017 18017 18017 18017 18007 X-75R X-75L X-81R X-81L X-51 X-71C X-54 X-72C XS-348 Mainstream Loop ll Flow Mainstream Loop ll Flow Mainstream Loop 12 Flow Mainstream Loop 12 Flow Emergency Condenser Loop 11 Steam Flow Emergency Condenser Loop ll Steam Flow Emergency Condenser Loop 12 Steam Flow Emergency Condenser Loop 12 Steam Flow Torus Water Level Category: Test Requirements:

Basis for Relief: AC Required testing procedure (IWV-3522), and quarterly oper ability testing (IWV-3521).

Excess flow check valves differ in design from conventional swing check valves in that there is no valve'disk'ut rather a ball which functions to block flow upon initiation.

Consequently, code test requirements are impractical.

The valves are used for containment isolation purposes in the event of an instrument line break outside containment.

These valves are located on instrument lines which function to provide signals relating reactor vessel conditions to station operations personnel as well as automatic trip systems for normal and emergency operation of the station.These instruments are typically required to operate during cold shutdown conditions as well as during normal operation.

Testing the excess flow check valves requires valving the corresponding instrumentation out of service.This could cause spurious instrument signal fluctuations to occur resulting in the inadvertent automatic initiation or trip of certain systems.Testing the excess flow check valves during normal operation or cold shutdown conditions imposes undue risk to plant operations and personnel since the test medium is high pressure (normally greater than 800 psig), high temperature (approximately 200-300'F) and highly contaminated reactor coolant.Testing during scheduled refueling outages provides adequate assurance of proper operation and satisfies the intent of Appendix J requirements associated with containment iso1ation.

I-15 January-1989  

General Relief Request (Cont'd)General Relief Request: VG-3 (Cont'd)Valves: Excess Flow Check Valves;(Cont'd)Alternate Testing: At NMP1, excess flow check valves are tested during scheduled refueling outages with the reactor pressure at least 200 psig.The test method consists of simulating a line break downstream from the check valves by opening a manual drain valve which initiates flow due to reactor pressure.Verification of proper valve closure is by an audible indication (when check valve closes, a noticeable noise is generated by the hydraulic surge within the piping)as well as temperature sensing in the drain piping (if the valve fails to close, a rapid increase in drain pipe temperature is detectable due to high temperature reactor water flowing through it).Visual observation of any flow from the drain piping is not possible since the drain line is hard piped directly to the equipment drain tank.I-16 January 1989

7.0 General Relief Request For Valves General Relief Request: Valves: Category: Test Requirements:

Basis For Relief: Alternate Testing: VG-4 Valves equipped to fai 1 open or closed A,B Observe the operation of the valves upon loss of actuator power, IWV-3415.Certain valves are equipped with remote position indication which provides a positive means of verifying valve position.Valves equipped with remote position indicators shall have their fail safe actuation verified using control room indicating lights.I-17 January 1989

7.0 General Relief Request For Valves General Relief Request: Valves: Category: Test Requirements:

Basis For Relief: Alternate Testing: VG-5 All Control Valves A, B IWV-3412 and IWY-3413, Exercising and Stroke Time Requirements.

Exercising these valves at any periodic frequency is impractical.

They respond to signals generated by flow, pressure, level, or temperature.

Valve degradation will be indicated by the inability to perform a system control function.The operability of these valves is demonstrated continuously by virtue of it performing its control function.The control valves are included in the inservice test program because of their fail safe feature only.Operability of these control valves will be assessed during normal system operation and during individual valve calibration tests.I-18 January 1989

0 8.2 8.3 8.4 8.5 8.6 8.7 8.10 8.11 8.12 8.13 8.14 8.15 8.0 References ASME Boiler and Pressure Vessel Code, Section XI, Rules For Inservice Inspection of Nuclear Power Plant Components, 1983 Edition, Summer 1983 Addenda.Nine Mile Point Unit 1, Section XI Pump and Valve Inservice Testing Program Plan, 1st Interval.Technical Specifications, Niagara Mohawk Power Corporation, Nine Mile Point Nuclear Station Unit 1, Section 3.2.6, 3.2.7, 3.3.4, Table 3.2.7, 3.2.7.1, 3.3.4.Final Safety Analysis Report (Updated), Nine Mile Point Nuclear Station Unit l.10CFR50.55a(g), Inservice Inspection Requirements, Guidance For Preparing Pump and Valve Testing Program Descriptions and Associated Relief Requests.Nine Mile Point Station Unit 1"Q-List".Nine Mile Point Station Unit 1"Q-Boundary Drawings".

IE Bulletin No.83-03, Check Valve Failure in Raw Water Cooling Systems of Diesel Generators.

IE Bulletin No.88-70, Check Valve Inservice Testing Program Deficiencies.

Nl-ISP-R-201-550, Local Leak Rate Test-Summary (Type B and C Tests).Nl-ST-M4, Emergency Diesel Generators Manual Start and 1 Hour Rated Load Test.NMPl Letter, Log No.6777, dated June 14, 1983, from T.E.Lempges to R.C.OeYoung,"IE Bulletin No.83-03 Response." NMPl Letter, Log No.7947, dated December 10, 1984, from T.E.Lempges to R.C.OeYoung,"IE Bulletin No.83-03 Response, Rev.l." NRC Letter, TAC 65888, dated March 29, 1988, from R.A.Capra to C.V.Mangan,"Relief Request Transmitted by Letter Dated July 8, 1987 for Nine Mile Point Unit 1." NRC Letter, TAC 54152, dated May 6, 1988, from R.A.Capra to C.V.Mangan,"Proposed Technical Specifications and Exemption Requests Related to Appendix J." 8.168.17 NRC Letter, TAC 68462, dated October 17, 1988, from R.A.Capra to C.V.Mangan,"Schedular Exemption from the Requirements of Appendix J to 10CFR50 for the Emergency Condenser Condensate Return Line Valves." NRC Letter, TAC 54152, dated November 9, 1988, from M.F.Haughey to C.V.Mangan,"Review of the July 28, 1988 Letter on Appendix J Containment Leakage Rates Testing at Nine Mile Point Unit l." I-19 January 1989

8.18 SER 26-88, INPO: Failure of Safety Valve due to Bonding of the Valve Disc and Seat.8.19 USNRC Oraft Inservice Testing Generic Letter.8.20 IE Notice No.85-84, Inadequate Inservice Testing of Main Steam Isolation Valves.I-20 January 1989

PUMP AND VALVE INSERVICE TESTING PROGRAM PLAN for NINE MILE POINT NUCLEAR POWER STATION UNIT 1 SECTION I I PUMP IST PROGRAM PLAN Pages II-1 through II-5 II-1 January 1989

This section presents the Program Plan for Inservice Testing of safety-related Pumps at Unit 1 of the Nine Mile Point Nuclear Station, in compliance with the requirements of lOCFR50.55a.

This Program Plan has been prepared to the requirements of the ASME Boiler and Pressure Vessel Code, Section XI, Subsection IWP,.1983 Edition through the Summer 1983 Addenda.The Pump Program Plan specifies Section XI testing requirements for all pumps provided with an on site emergency power source, and which are required for safety-related system operation.

The pump, the test circuit, and the associated instrumentation were investigated to determine whether Section XI testing could be performed.

For pumps where Code requirements are determined to be inappropriate, a specific relief request has been prepared.The specif ic relief requests fol low the Pump Test Table.Each specif ic relief request provides justification for deviation from the Section XI specified testing, and proposes appropriate alternate testing.II-2 January 1989 t>

3.0 Pump List Pumps required for safety-related operation for NMP1 are as follows: SYSTEM Core Spray Core Spray Topping Spent Fuel Pool Cooling Containment Spray DWG.NO.C-18007-C C-18007-C C-18008-C C-18012-C Sh.2 REV.NO.33 33 26 NO.of PUMPS Containment Spray Raw Water C-18012-C Sh.1 Liquid Poison Emergency Service Water RBCLC Emergency D.G.Cooling~~~~Emergency D.G.Fuel Oil Transfer C.R.Chilled Water Condensate Tr ansfer C-18019-C C-18022-C Sh.3 C-18022-C Sh.3 C-18026-C Sh.l C-18026-C Sh.2 C-18040-C C-18047-C C-18048-C 12 10 10 19 NOTE: Revision numbers listed are those current during Program Plan development, and may not reflect the most current drawing revision available.

II-4 January 1989

4.0 Pump Table Nomenclature The following abbreviations have been used in the Pump Test Table: N=Rotative Speed Pi=Inlet Pressure (Before and after pump start)P=Differ ential Pressure Qf=Flow Rate V=Vibration Amplitude Tb=Bearing Temperature Q=Quarterly X=Measurement/Observation per IWP L=Lubricant Level or Pressure PR=Pump Relief Request NA=Not Applicable I I-5 January 1989

PUMP ANO VALVE INSERVICE TESTING PROGRAM PLAN for NINE MILE POINT NUCLEAR POWER STATION UNIT 1 SECTION II.5.0 PUMP TEST TABLE Pages II-1-1 through II-1-16 I I-1-1 January 1989 0

-.PUMP NAME Liquid Poison (Ill, f12)Emergency Service Water (Ill, 812)NP02A C-18019-C H-5 NP02B H-7 72-04 72-03 C-18022-C B-5 Sh.3 D-5 Q (1)Q (1)3 PR-5 (1)3 PR-5 (1)PUMP CO-ASME TEST I.D.PLI.D.NO.ORD.CLASS FREQ.N Pi PR-4 PR-4 (3)(3)PR-4 PR-4 (4)(4)PR-4 PR-4 PR-5 PR-5 V PG-1)PR-6 PR-6 PG-4 PG-4 PG-4 PG-4 L X X (2)2)Reactor Building Closed Loop Cooling Water (Ill, 812, 813)70-01 70-02 70-03 C-18022-C D-8 Sh.3 0-7 D-6 3 PR-3 (1)3 PR-3 (1)3 PR-3 (1)(3)PR-3 (4)PR-3 PR-3 3)PR-3 (4)PR-3 PR-3 3)PR-3 (4 PR-3 PR-3 PG-4 PG-4 PG-4 Core Spray (8111, 8112 8121, 8122)Core Spray Topping (8111, 8112 8121, 8122)81-23 81-24 81-03 81-04 81-50 81-49 81-51 81-52 C-18007-C C-18007-C B-7 2 B-8 2 L-7 2 L-8 2 A-5 2 A-5 2 M-5 2 M-5 2 (1).(3 (1)3)3)(1)(3 (4 (4)(4)PR-2,7 PR-6 PR-2,7 PR-6 PR-2,7 PR-6 PR-2,7 PR-6 PR-2,7 PR-2,7 PR-2j7 PR-2,7 PG-4 PG-4 PG-4 PG-4 PG-4 PG-4 PG'-4 PG-4 2)(2 II-1-2 January 1989

PUMP T ABLE PUMP LIST MEASURED PARAMETERS PUMP NAME PUMP I.D.PEI.D.NO.ASME TEST COORD.CLASS FREQ.N Pi V PG-1 Tb Emergency D.G.Cooling Water (8102, 8103)Spent Fuel Pool Cooling (ill, 812)'ontainment Spray Raw Water'Pill, 8112:-8121, 8122)72-62 72-63 54-01 53-02 93-02 93-01 93-04 93-03 C-18026-C Sh.1 C-18026-C Sh.2 C-18008-C C-18012-C Sh.1 B-9 A-9 C-5 C-8 E-8 F-8 C-8 J-9 (1)(3)(4)(1)(3)(4)(1)(3)(4)(1)(3)(4)(1)(3 (4 PR-1 PR-1 PR-7 PR-7 PR-7 PR-7 PR-7 PR-7 PR-6 PG-4 PR-6 PG-4 PR-6 PG-4 PR-6 PG-4 PR-6 PG-4 PR-6 PG-4 X X X PG-4 X X PG-4 X (2)(2)(2)(2).Containment Spray 80-04'fill, 8112 80-24.8121, 8122)80-03 80-23 C-18012-C Sh.2 D-7 J-7 0-9 J-9 (1)(3)(4)(1)(3)4)1)(3)4)(1)(3)(4)PR-7 PR-7 PR-7 PR-7 PR-6 PG-4 PR-6 PG-4 PR-6 PG-4 PR-6 PG-4 (2)(2)2)(2);Condensate Transfer.(Ill, 812)57-12 57-11 C-18048-C I-8 H-8 (1)(3)(4)(1)(3)(4)PR-1 PR-1 X PG-4 X PG-4 II-1-3 January 1989

PUMP TABLE PUMP LIST MEASURED PARAMETERS i PUMP NAME PUMP I.D.ASME TEST P&I.D.NO.COORD.CLASS FREQ.N Pi Qf V Tb PG-1)'.R.Chilled.'ater (t>>,>12)12 Emergency D.G.82-40'uel Oil Transfer (8102, 8103)82-41 C-18040-C C-18047-C B-7 NA PR-9 C-7 NA PR-9 I-2 3 I-2 3 (1)X (1)X (4)(4)(1)(3)(4)(1)(3)(4)PR-8 X PR-8 X PR-10 X PR-10 X PG-4 PG-4 PG-4 PG-4 (2)(2)(2)(2)II-1-4 January 1989

6.0 Pump Test Table Notes In the Pump Test Table, the test parameters to be measured or observed, and the test frequency are identified.

Footnotes 1 through 5 refer to amplifications, deviations, and exceptions to the Code requirements and are further discussed below: (1)For pumps with constant speed drive, the speed is not measured since the test wi 11 be performed at nominal motor nameplate speed as required by Section XI, IWP-3100.(2)Lubricant level or pressure not observed because of bearing lubrication design, (e.g., submerged pumps, sealed bearings).

(3)Inlet pressure measurement is satisfied by monitoring various levels such as torus, tank, pit, or lake level (Reference General Relief Request for Pumps PG-2).(4)Differential pressure wi 11 be determined by using inlet (or level information) and discharge pressure measurements as opposed to measuring it directly from differential pressure instrumentation.(Reference Section XI, IWP-4240).

I I-1-5 January 1989 IP 7.0 PUMP RELIEF REQUEST PR-1 System: Pump: Emergency Diesel Generator Cooling Water Condensate Transfer Emergency Diesel Generator Cooling Water 72-62:72-63 Condensate Transfer 57-11:57-12 Class: Function:-

To provide make-up water to safety related cooling systems.Acceptable flowrate instrument accuracy of+2X of full scale (IWP-4110-1).

The system currently does not have instrumentation installed to measure flow rate.Temporary flow instruments shall be used in determining indi vidual pump f low rates.It i s anticipated that the allowable instrument accuracy wi 1 1 exceed Section XI requirements (IWP-4110-1), however, a small reduction in accuracy should not provide a significant reduction in the ability to determine pump degradation.

I I-1-6 January 1989

7.0 PUNP RELIEF REQUEST PR-2 System: Pump: Class: Function: Reactor Core Spray Core Spray 81-03:81-04:81-23:81-24 Core Spray Topping 81-49:81-50:81-51:81-52 To provide cooling to the core in the event of a LOCA.Test Requirements:

Basis for Relief: Alternate Testing: Neasure flow rate (INP-3100-1).

These pumps are designed to operate in series to meet Total Core Spray System flow requirements.

There are no system design provisions to measure flow between these pumps.The discharge from the Core Spray pump is delivered to the suction of the associated topping pump such that independent pump flow measurements are not meaningful.

The combined flow will be measured downstream of the topping pumps.II-1-7 January 1989 0

7.0 PUMP RELIEF REQUEST PR-3 Pump: Class: Function: Test Requirements:

Basis for Relief: Alternate Testing: Reactor Building Closed Loop Cooling Water 70-01:70-02:70-03 Provide cooling water io safety-related equipment.

Measure inservice test quantities (IWP-3100-1) quarterly (IWP-3400).The RBCLC system is not a fixed resistance system and there are no pump test loops installed.

The system flow rate and the number of pumps running are a function of the system heat loads.In most cases it is not possible to operate the system with a single pump and align the system to achieve Code test conditions without adversely affecting plant operation.

Differential pressure, flow rate and pump vibration shall be measured for each individual pump during cold shutdown.Pump vibration wi 1 1 be measured for each indi vidual pump on a quarterly basis.II-1-8 January 1989

7.0 PUMP RELIEF REQUEST PR-4 System: Pump: Class: Function: Reactor Liquid Poison NP02A:NP02B Provide a method of shutting down the Reactor without use of the Control Rods.Test Requirements:

Basi s for Rel i ef: Alternate Testing: Measure flow rate, inlet and di f f erenti al pressure (IMP-3100-1).

These pumps are tested by pumping water from a test tank into a 55 gallon barrel for one minute and calculating flow rate from the change of test tank water level.Pump suction pressure is the head of water in the test tank and test lines which decreases as the tank level drops during testing.These positive displacement pumps are designed to provide a constant quantity of fluid (flow rate)at a relatively high discharge pressure (approximately 1500 psig)regardless of the suction pressure.In addition, the suction head is so small in comparison to the discharge pressure during testing of these pumps (2 psig vs 1275 psig), that measurement of suction pressure would provide no useful information in assessing pump performance.

Pump discharge pressure, calculated flow rate and vibration wi1 1 be used in determining pump degradation.

I I-1-9 January 1989

7.0 PUMP RELIEF REQUEST PR-5 System: Pump: Class: Function: Test Requirements:

Basis for Relief: Alter nate Testing: Emergency Service Water 72-03:72-04 Provide cooling water to safety-related equipment.

Measure f 1 ow rate (IWP-3100-1) quarterly (IWP-3400).

Acceptable instrument accuracy (IWP-4110-1).

The test line piping configuration does not allow for temporary test or permanent flow instrumentation to be installed.

Since the ESW pumps operate at a lower pressure than the normal service water header pressure, testing at quarterly or cold shutdown intervals is not possible.Flow instrumentation can be utilized on the Service Water System inter-tie piping to test the Emergency Service Water pumps during ref ue 1 ing.Pump di f f erent i al pressure, and pump motor vibration wi 1 1 be used to evaluate pump performance quarterly.

Pump di ff erenti al pressure, flow rate, and pump motor vibration will be measured for each individual pump a'refueling.

Temporary test equipment shall be uti 1 i zed in determining individual pump flow rates.It is anticipated that the allowable instrument accuracy will exceed Section XI requirements (IWP-4110-1), however, a small reduction in accuracy should not provide a significant reduction in the ability to determine pump degradation.

An engineering evaluation shall be made to add permanent flow instrumentation on the individual pump discharge.

II-1-10 January 1989

7.0 PUMP RELIEF REQUEST PR-6 System: Pump: Class: Function: Test Requirements:

Basis for Relief: Emergency Service Water, Emergency Diesel Generator Cooling Water, Core Spray, Containment Spray Raw Water, Containment Spray.Emergency Service Water 72-03:72-04 Emergency Diesel Generator Cooling Water 72-62:72-63 Core Spray 81-03:81-04:81-23:81-24 Containment Spray Raw Water 93-01:93-02:93-03:93-04 Containment Spray 80-03:80-04:80-23:80-24 23 Various Measure vibration on pump bearing housing (IWP-4600).

These pumps are vertical centrifugal submerged process pumps.The pump bearings are not accessible for vibration measurements.

Alternate Testing: Vibration measurements will be taken on the pump motors.Since these are vertical line shaft pumps, any change in the vibration characteristics of the pump will be transmitted to the motor.The PG-1 criteria will be applied to these readings.II-l-ll January 1989

7.0 PUMP RELIEF REQUEST PR-7 System: Pump: Class: Function: Test Requirements:

Core Spray, Core Spray Topping, Spent Fuel Pool, Containment Spray Raw Water, Containment Spray Core Spray 81-03: 81-04: 81-23: 81-24 Core Spray Topping 81-51: 81-52: 81-49: 81-50 Spent Fuel Pool 54-01: 54-02 Containment Spray Raw Water 93-01: 93-02: 93-03: 93-04 Containment Spray 80-03: 80-04: 80-23: 80-24 Various Table IWP-4110-1 acceptable instrument accuracy requires a flow rate instrument accuracy of+2/of full scale.Basis For Relief: NMPl uses flow measuring instrumentation which meets the acceptable instrumentation accuracies defined in Table IWP-4110-1.

The total loop accuracy was calculated from the flow device to the final readout device.The loop accuracies do not meet the instrumentation accuracies of Table IWP-4110-1 for flow rate (see the following table for flow instrument accuracies):

I I-1-12 January 1989

PUMP FLOW MEASUREMENT INSTRUMENT ACCURACIES SYSTEM Core Spray System (Core Spray Topping)Spent Fuel Pool System Containment Spray Raw Water System Containment Spray INSTRUMENT ACCURACY<0.25 2.00 0.94 0.25 LOOP ACCURACY (1)2.08 2.12 2.07 2.08 (1)X of Full Scale The flow transmitter is well within or meets the accuracy limits of Section XI.The loop accuracies do not significantly exceed Section XI limits and should be sufficiently repeatable from test to test to allow for an evaluation of the pump hydraulic condition and for the detection of pump degradation.

Alt'ernate Testing: Use the installed instruments.

II-1-13 January 1989

Basis For Relief: Alternate Testing: Emergency Diesel Generator Fuel Oil Transfer 82-40: 82-41 NA Provide fuel oil to the Diesel Generator Day Tank.Measure flow rate IHP-3100-1.

The piping conf i gurat i on (underground, mu1 t i pl e bends)as such does not support itself to allow for temporary test or permanent flow instrumentation to be installed, (See PR-9).The change in level of the Diesel Generator Oay Tank shall be used in calculating flow rate for determining pump degradation.

II-1-14 January 1989

7.0 PUMP RELIEF REQUEST PR-9 System: Pump: Class: Function: Test Requirements:

Basis For Relief: Alternate Testing: Emergency Diesel Generator Fuel Oil Transfer 82-40: 82-41 NA Provide fuel oil to the Diesel Generator Day Tank.Frequency of inservice tests IWP-3400.The Diesel Generator Fuel Oil Transfer Pumps are skid mounted components and are assessed during monthly Technical Specification Emergency Diesel Generator operability tests.The power for these pumps comes from their associated Diesel Generator.

The pumps have no means of operating unless their associated engine is running.Inservice Testing of these pumps shall be performed during refuel when a temporary power supply can be provided to operate the pumps without running their associated engine.In addition, pump degradation assessments shall be performed during monthly Technical Specification Emergency Diesel Generator operability tests.II-1-15 January 1989

14*HO\~-~7.0 PUMP RELIEF REQUEST PR-10 System: Pump: Class: Function: Test Requirements:

Control Room Chilled Water 11:12 Provide cooling water for control room HVAC.Acceptable flowrate instrument accuracy of+2'A of full scale (IWP-4110-1).

Basis For Relief: The system currently has inadequate instrumentation installed to measure flowrate.Temporary flow instruments shall be used in determining individual pump flow rates.It is anticipated that the allowable instrument accuracy will exceed Section XI requirements (IWP-4110-1), however, a small reduction in accuracy should not provide a significant reduction in the ability to determine pump degradation.

Alternate Testing: Temporary test equipment shall be utilized in determining individual pump flow rates.An engineering evaluation shall be made to replace the permanent flow instrumentation.

II-1-16 January 1989'4, M g~

~t wl~6 0~4 CA~44 I lA 4hA%~PUMP ANO VALVE INSERVICE TESTING PROGRAM PLAN for NINE MILE POINT NUCLEAR POWER STATION UNIT 1 SECTION III VALVE IST PROGRAM PLAN Pages III-1 through III-ll I I I-1 Januar y 1989 0 f"'gF  

This section presents the Program Plan for Inservice Testing of Valves at Unit 1 of the Nine Nile Point Nuclear Station, in compliance with the requirements of 10CFR50.55a.

This Program Plan has been prepared to the requirements of the ASME Boiler and Pressure Vessel Code, Section XI, Subsection IWV, 1983 Edition through the Summer 1983 Addenda.This Test Program Plan was developed to assess the operational readiness of valves in safety-related systems.The valves addressed are those whose operability is essential to safety-related system operation.

Section XI testing is then specified for each of these valves to verify individual valve operational readiness.

The Program Plan specifies either Section XI or alternate testing, as appropriate, for all valves which perform a safety-related function.Valves are selected for inclusion in the test program based on a review of all station systems.This review identifies those systems performing safety-related functions.

Each safety-related system was then analyzed to determine which valves are essential to the safety-related operation of the system.These valves are investigated to determine whether Section XI testing can be performed during normal operation.

Those valves for which quarterly testing is determined to be inappropriate are analyzed further to determine if Code allowed cold shutdown testing is possible.If so, a justification for delay of testing to cold shutdown is provided following the appropriate Valve Test Tables.Relief requests describing appropriate alternative testing have been prepared for valves which cannot be tested quarterly or during cold shutdown, and are provided following the appropriate Valve Test Tables.III-2 January 1989

a~~2.0 Code Interpretation I A number of items in Subsection IWV of the Code are subject to interpre-tation.The interpretations of a number of general items encountered in preparing the Valve Test Program Plan are provided below.Corrective Action-Time Frame If a valve fails to exhibit the required change of valve stem or disk position or exceeds its specified limiting valve of full-stroke time, the corrective action shall be initialed immediately.

If the condition is not, or cannot be, corrected within 24 hours, the valve shall be declared inoperable.

This position is in accordance with the Code (see IWV-3417b), but not with the USNRC's Draft Generic Letter, Supplement 1, Item 10.This time frame is needed due to the NNP1 plant technical specification action statement which requires an immediate test of the redundant component in other loop(s)upon declaring the first component inoperable.

This additional testing delays the investigation of the initial test deviation which could have been caused by an electrical problem, additional load on the instrument air system, system loading conditions, etc.Relief Valves: , The Code requires testing of safety and relief valve set points in accordance with ASNE PTC 25.3-1976.

The relief valves designated for test are those which perform a system pressure relief function.Passive Valves: The reference Code excludes valves used only for operating convenience and/or maintenance testing.Also, the Code defines passive valves but specifies no inservice test requirements, only leakage test requirements.

This program defines passive valves as those which do not have to change position to accomplish a specific safety function.System Test Valves: Power operated valves which receive an automatic initiation signal, that are used to align a system for testing purposes, are included for Section XI testing.Control Valves: The reference Code excludes valves which perform system control functions (such as pressure regulating valves).This program excludes them unless they also perform a system safety-related response function such as automatic closure on system initiation.

The program addresses these valves by specifying testing of the safety-related function, and excluding the normal pressure or flow control functi'ons.

Automatic Power Operated Valves: Power operated valves which receive an automatic signal on system initiation are included in the program.III-3 January 1989

2.0 Code Interpretation (Cont.)Remote Power Operated Valves: The program includes power operated valves activated by remote switches if they are required to change position to align a system for safety-related operation, or provide containment isolation.

Dual Function Valves: Valves which provide more than one function are tested for their safety-related function only.Val ves with multiple safety-related functions are tested for each function.Examples are the automatic depressurization valves, which open and close in response to either an automatic or remote manual si gnal, and al so act as rel i ef val ves.Both are safety-rel ated functions, and testing for both functions is included in the program.Simple Check Valves: This Program Plan considers any check valve to be a simple check valve if it has no means of changing position other than by fluid flow.Simple check valves are tested to verify operability in the safety-related flow direction.

If the manual operator is withdrawn, the valve operates as a simple check in the forward flow direction and is tested as a simple check.Reverse flow closure is verified as a simple check, if possible, or by use of the manual operator.Testable Check Valves: Check valves equipped with manual exercisers wi 11 be tested as a simple check, or by exercising using the manual exercising device.Check valves equipped with a power operator installed for the sole purpose of exercising the valve for operability will be tested as a simple'heck, or by use of the power operator.III-4 January 1989~~

II:f 2.0 Code Interpretation (Cont.)Power Operated Stop Check Valves: Testing of power operated stop check valves is based on the function of the operator.If the valve operator is always withdrawn, and the valve operates as a simple check valve except during maintenance, the valve is tested as a simple check.If the operator is normally withdrawn, such that the valve operates as a simple check in the forward direction, and the operator provides positive closure, it is tested as a simple check in the forward direction, and exercised closed using the operator.In addition to exercising, the operator will be timed and fail safe actuation tested as appropriate.

Pump Discharge Check Valves: As a minimum, pump discharge check valves in safety-related systems wi 11 be forward flow exercised.

In addition, reverse flow closure will be verified when failure of the valve to close could result in a reduction of system performance.

Such a potential exists with parallel pumps connected to common suction and discharge headers.If the check valve on the idle pump fails to close, system flow could be diverted back through the idle pump to the suction header.System Piping Keep Fill Check Valves: Keep fill lines are those lines attached to ECCS piping whose function is maintenance of system water inventory to preclude water hammer.Forward flow operability is verified by a system check of water inventory performed at least quarterly.

Reverse flow closure ver if i cati on i s performed only if failure of the valve to close could result in a.reduction of ECCS operation.

Check Valve Full/Partial Stroke: In most cases maximum accident condition flow through a check valve requires less than full mechanical valve movement.As used in this program, the term full stroke refers to the ability of the valve to pass maximum accident condition flow, and not the full mechanical stroking.Forward flow full stroke operability testing wi 11 be by any method that verifies the valve is capable of passing maximum accident condition flow.Tests that verify less than maximum accident condition flow capability is considered as a partial stroke test.Category A (Containment Isolation Valve)Leak Testing: Valves specified for Appendix J Type C leakage rate testing are included in the Valve IST Program as Category A valves.A Relief Request (see VG-2)has been included to perform the Appendix J Type C testing in lieu of testing specified in IWV-3420.The Program Plan reflects the current list of valves receiving Appendix J testing.Future changes to the Appendix J Type C Program will be incorporated into the Valve IST Program.III-5 January 1989

2.0 Code Interpretation (Cont.)Valves which perform a pressure isolation function between the Reactor Coolant System and a low pressure system are included in the Valve IST Program as Category A valves.These valves will be tested to the requirements specified in IWV-3420.Category A (Containment and Pressure Isolation Valve)Leak Testing: Valves which perform both a containment isolation and a pressure isolation function (Event Y only)are included in the Valve IST Program Plan as Category A Valves.These valves will be tested to requirements of both Appendix J and Section XI.Valve Timing: The required maximum stroke times have been established and incorporated into a separate NNPl document.Valve Position Indicator Verification:

IWV-3300 requires that valves with remote position indicators shall be observed at least once every two years to verify that valve operation is accurately indicated.

This program tests active valves equipped with remote position indicators in accordance with IWV-3300.Verification of proper remote position indicator operation will be performed during each refueling outage.Valve Fail Safe Testing: IWV-3415 requires proper operation of valves equipped with Fail Safe Actuators to be observed.For NNPl, thi s i s general ly accomp1 i shed by pl acing the control to the position which de-energizes the actuator and observing proper valve operation (See VG-4).In cases where operation of normal valve controls does not de-energize the valve actuator, alternate means will be adopted to simulate loss of actuator power.Skid Mounted Testing-Valves: The Instrument Air System Air Compressor Inlet Cooling Water valves, the Emergency Diesel Generator Air Start valves, and the Diesel (Fire Pump)Air Start valves are skid mounted valves that cannot be readily tested as a component.

Valve operability will be verified by monitoring the system performance during continuous operation (IAS), weekly operability tests (Fire Pump), or by monthly operability tests (EDG).III-6 January 1989

3.0 Valve Test Table Nomenclature The following abbrevi ations Value Tyae AGV-Angle Val ve BFV-Butterfly Val ve BLV-Ball Valve CHV-Check Valve EXV-Explosive Valve GLV-Globe Valve GTV-Gate Valve NDV-Needle Valve PGV-Plug Valve REV-Relief Valve SCV-Stop Check Valve TPV-Two Port Valve TMV-Three Way Valve have been used in the Valve Test Table Actuator T e APA-Air/Piston ADA-Air/Diaphragm EXA-Explosive HOA-Hydraulic MAA-Manual MOA-Motor NPA-Nitrogen/Piston NDA-Nitrogen/Diaphragm SEA-Self SOA-Solenoid Stroke Direction 0-Closed to Open C-Open to Closed Normal Position 0-Open C-Closed LO-Locked Open LC-Locked Closed TH-Throttled DE-Normal position depends on system condition Check Valve Test Direction F-Forward Flow R-Reverse Flow I II-7 January 1989

3.0 Valve Test Table Nomenclature (Cont.)Test Re uirements EX-Explosive Valve test per IWV-3610.FE-Full Stroke Exercise test.FS-Fail Safe test.LA-Leak Test per Section XI (leakage function only).LC-Leak Test per both Appendix J, Type C, and Section XI (both pressure and containment isolation function).

LJ-Leak Test per Appendix J, Type C (containment isolation function only).LK-Leak Test per Section XI (pressure isolation function only).PE-Partial Stroke Exercise test.PI-Remote Position Indication Verification.

PV-Passive Valve (no operability tests required).

RD-Rupture Oisk test per IWV-3620.RT-Relief Valve test.ST-Stroke Time test.Test Frequenc C-Testing performed during cold shutdown P-Periodically tested during the time period defined in: IWV-3511 (safety and relief valves)IWV-3610 (explosive actuated valves)IWV-3620 (rupture disks)g-Once per 92 days (quarterly)

R-Once per refueling outage III-8 January 1989

4.0 Valve Test Table Format Class and Owg.Coor.Unique number assigned to each valve, and a description of the valves function within the system.The ASME valve classification (Class 1 2 or 3)or Non-ASNE valve classification (NI, and the valve location on the reference drawing.Valve Cat.Valve category as defined in Sub-article IWV-2200.Size (in.)and Type Valve size is the nominal diameter of the valve in inches.Valve type is the specific type of valve, as abbreviated in Section 3.0"Valve Test Table Nomenclature".

Actu.Type The type of Actuator used to operate the valve.Norm.Posit.Test Req.Stroke Direct.Check Valve Test Direct.The valve position during normal plant operation.

The Section XI test requirement(s) which apply to the valve.The direction in which the valve is required to be Stroke Timed (ST), indicated by"0" for Open and"C" for closed.The direction of check valve operabi lity verification, indicated by"F" for forward flow and"R" for reverse flow.C.S.Just.or Relief Req.No.C.S.or Alt.Test Per f.Remarks: Reference number of the cold shutdown justification or relief request.Cold shutdown or alternate testing which is being performed in lieu of the Code specified quarterly testing.Key to notes providing ampl i fying remarks.These notes are located immediately following the appropriate Valve Test Tables.III-9 January 1989

4.0 Valve Test Table Format (Cont.)~Sstem Main Steam Reactor Rec i rcul at i on Control Rod Drive Feedwater/HPCI Core Spray Emergency Cooling Reactor Shutdown Cooling Containment Spray Reactor Cleanup Inert Gas Purge and Fill Hydrogen-Oxygen Monitoring TIP Nitrogen Supply No.11 Nitrogen Supply No.12 Reactor Sldg.HVAC Liquid Poison Spent Fuel Storage Pool Filtering E Cooling Sample~Dw.No.C-18002-C C-18020-C C-18016-C Sh.l C-18016-C Sh.2 C-18005-C Sh.2 C-18007-C C-18017-C C-18018-C C-18012-C Sh.l C-18012-C Sh.2 C-18009-C Sh.l C-18014-C Sh.l C-18014-C Sh.2 C-26939-C C-26949-C C-18014-C Sh.2 C-18014-C Sh.3 C-18014-C Sh.4 C-18013-C C-18019-C C-18008-C C-18041-C Sh.2 Rev.No.21 12 14 15 15 33 32 13 9 26 40 31 5 7 31 12 22 16 12 10 Attachment No.10 12 13 14 15 16 17 18 NOTE: Revision numbers listed are those current during program plan development and may not reflect the most current drawing revision avai 1 ab1 e.III-10 January 1989

4.0 Valve Test Table Format (Cont.)~Sstem Reactor Bldg.Closed Loop Cooling~ow.No.C-18022-C C-18022-C C-18022-C C-18047-C C-26939-C C-26949-C C-18008-C C-18041-C Sh.2 Sh.3 Sh.4 Sh.7 Rev.No.19 10 7 15 5 7 11 5 Attachment No.19 Condensate Transfer Torus Vacuum Relief Emergency Service Water Emergency Diesel Generator Cooling Water Emergency Di esel Generator Air Start Emergency Diesel Generator Fuel Oil Transfer Waste Disposal Breathing Air to Drywell Control Room Chilled Water Control Room HVAC Instrument Air C-18048-C C-18006-C Sh.2 C-18022-C Sh.3 C-18027-C Sh.2 C-18026-C Sh.l C-18026-C Sh.2 C-18026-C Sh.l C-18026-C Sh.2 C-18040-C C-18045-C Sh.7 C-18045-C Sh.9 C-18578-C C-18047-C C-18047-C C-18011-C Sh.l C-18011-C Sh.2 C-18030-C Sh.3 19 17 10 7 15 15 16 10 14 20 21 22 23 24 25 26 27 28 30 NOTE: Revision numbers listed are those current during Program Plan development and may not reflect the most current drawing revision available.

III-11 January 1989

PUMP AND VALVE INSERVICE TESTING PROGRAM PLAN for NINE MILE POINT NUCLEAR POWER STATION UNIT 1 SECTION III 5.0 VALVE TEST TABLES AND RELIEF REQUESTS Pages III-I through III-30-5 I I I-I January 1989

PUMP AND VALVE INSERVICE TESTING PROGRAM PLAN for NINE MILE POINT NUCLEAR POWER STATION UNIT 1 SECTION I II 5.1 ATTACHMENT 1 VALVE TEST TABLES AND RELIEF REQUESTS FOR MAIN STEAM OWG.NO.C-18002-C Pages III-l-l through III-1-14 III-1-1 January 1989 I

SYST N STEAM DWG.NO.C-18002-C NI N f POINT UNIT 1 VALVE TEST TABLE CLASS VALVE SIZE ACTU.NORM.TEST STROKE VALVE NUMBER AND (CAT.)(IN.)TYPE POSIT.REQ.DIRECT.DWG.AND COOR.TYPE C.S CHECK JUST.VALVE OR TEST RELIEF DIRECT.REQ.NO.C.S OR ALT.TEST PERF.REMARKS 01-01 MS-IN-IV&#xb9;1 (111)01-02 MS-IN-IV&#xb9;2 (121)01-03 MS-Out-IV&#xb9;3 (112)01-04 MS-Out-IV&#xb9;4 (122)1 B-5 1 F-5 1 A-5 1 G-5 24 GLV 24 GLV 24 GLV 24 GLV MOA MOA APA APA 0 FE-Q ST-Q LJ-R PI-R 0 FE-Q ST-Q LJ-R PI-R 0 FE-Q ST-Q FS-Q LJ-R PI-R 0 FE-Q ST-Q FS-Q LJ-R PI-R CS-1 FE-C ST-C PE-Q CS-1 FE-C ST-C PE-Q CS-1 FE-C ST-C FS-C PE-Q CS-1 FE-C ST-C FS-C PE-Q NOTE 3 NOTE 3 III-1-2 January 1989

SYST N STEAM DWG.NO.C-18002-C NIN POINT UNIT 1 VALVE TEST TABLE CLASS VALVE SIZE ACTU.NORM.TEST STROKE VALVE NUMBER AND (CAT.)(IN.)TYPE POSIT.REO.DIRECT.DWG.AND COOR.TYPE C.S CHECK JUST.VALVE OR TEST RELIEF DIRECT.RE/.NO.C.S OR ALT.TEST PERF.REMARKS 34-01 1 CRD Head Spray H-2 Outside IV 34-02 1 CRD Head Spray F-2 Inside IV (Check)2 GTV A,C 2 CHV MOA SEA C PV LJ-R C PV LJ-R NOTE 1 NOTE 1 37-01 Rx Head Vent B.V.81 1 F-2 2 GTV MOA C FE-C}ST-0 PI-R O,C CS-2 FE-C ST-C III-1-3 January 1989

SYST N STEAM DWG.NO.C-18002-C NIN POINT UNIT 1 VALVE TEST TABLE CLASS VALVE SIZE ACTU.NORM.TEST STROKE VALVE NUMBER AND (CAT.)(IN.)TYPE POSIT.REQ.DIRECT.DWG.AND COOR.TYPE C.S CHECK JUST.VALVE OR TEST RELIEF DIRECT.REQ.NO.C.S OR ALT.TEST PERF.REMARKS 37-06 Rx Head Vent B.V.82 1 F-3 2 GTV MOA C FE-Q ST-Q PI-R O,C CS-2 FE-C ST-C 66-07 2 SRV Vacuum Breaker B-4 66-08 2 SRV Vacuum Breaker B-4 66-09 2 SRV Vacuum Breaker B-3 66-10 2 SRV Vacuum Breaker B-3 CHV 4 CHV 4 CHV 4 CHV SEA SEA SEA SEA DE Ff-Q DE FE-Q DE FE-Q DE FE-Q F,R F,R F,R F,R RR-2 FE-R RR-2 FE-R RR-2 FE-R RR-2 FE-R 66-11 2 SRV Vacuum Breaker F-3 4 CHV SEA DE FE-Q F,R RR-2 FE-R 66-12 2 SRV Vacuum Breaker f-3 66-13 2 SRV Vacuum Breaker F-4 66-14 2 SRV Vacuum Breaker F-4 66-15 2 SRV Vacuum Breaker F-5 4 CHV 4 CHV 4 CHV 4 CHV SEA SEA SEA SEA DE FE-Q DE FE-Q DE FE-Q DE FE-Q F,R F,R RR-2 FE-R RR-2 FE-R RR-2 FE-R RR-2 FE-R I I I-1-4 January 1989

SYST IN STEAM DWG.NO.C-18002-C NI E POINT UNIT 1 VALVE TEST TABLE CLASS VALVE SIZE VALVE NUMBER AND (CAT.)(IN.)DWG.AND COOR.TYPE C.S C.S ACTU.NORM.TEST STROKE CHECK JUST.OR TYPE POSIT.REQ.DIRECT.VALVE OR ALT.TEST RELIEF TEST DIRECT.REQ.NO.PERF.REMARKS 66-16 2 SRV Vacuum Breaker f-5 66-17 2 SRV Vacuum Breaker 8-5 4 CHV 4 CHV SEA SEA DE FE-Q DE FE-Q F,R RR-2 FE-R F,R RR-2 FE-R 66-18 2 C 4 SRV Vacuum Breaker 8-5 CHV SEA DE FE-Q RR-2 FE-R 66-25 2 SRV Vacuum Breaker B-4 66-26 2 SRV Vacuum Breaker 8-4 66-27 2 SRV Vacuum Breaker B-3 66-28 2 SRV Vacuum Breaker B-3 66-29 2 SRV Vacuum Breaker F-3 66-30 2 SRV Vacuum Breaker F-3 66-31 2 SRV Vacuum Breaker F-4 10 CHV C 10 CHV 10 CHV 10 CHV 10 CHV 10 CHV 10 CHV SEA SEA SEA SEA SEA SEA SEA DE FE-Q DE FE-Q DE FE-Q DE FE-Q DE FE-Q DE FE-Q DE FE-Q F,R F,R F,R F,R F,R F,R F,R RR-2 FE-R RR-2 FE-R RR-2 FE-R RR-2 FE-R RR-2 FE-R RR-2 FE-R RR-2 FE-R I I I-1-5 January 1989

SYSTEM MAIN STEAM DHG.NO.C-18002-C NINE MILE POINT UNIT 1 VALVE TfST TABLE CLASS VALVE SIZE ACTU.NORM.VALVE NUMBER AND (CAT.)(IN.)TYPE POSIT.DWG.AND COOR.TYPE TEST REQ.STROKE DIRECT.C.S CHECK JUST.VALVE OR TEST RELIEF DIRECT.REQ.NO.C.S OR ALT.TEST PERF.REMARKS 66-32 2 SRV Vacuum Breaker G-4 10 CHV SEA DE Ff-Q F,R RR-2 FE-R 66-33 2 SRV Vacuum Breaker F-5 10 CHV SEA DE F,R RR-2 Ff-R 66-34 2 SRV Vacuum Breaker F-5 66-35 2 SRV Vacuum Breaker 8-5 66-36 2 SRV Vacuum Breaker B-5 10 CHV 10 CHV 10 CHV SEA SEA SEA DE Df DE FE-Q FE-Q FE-Q F,R F,R F,R RR-2 FE-R RR-2 FE-R RR-2 Ff-R NR108A MSERV-3 (Pill)NR108B MSERV-1 (8112)NR108C MSERV-2 (8121)1 C-4 1 C-3 1 E-4 B,C 6XB REV B,C 6X8 REV B,C 6XB REV SOA SOA SOA FE-Q ST-Q FS-Q RT-P PI-R Ff-Q ST-Q FS-Q RT-P PI-R FE-Q ST-Q FS-Q RT-P PI-R O,C O,C O,C RR-1 FE-R RR-1 FE-R RR-1 FE-R NOTE 2,4 NOTE 2,4 NOTE 2,4 NR108D MSERV-4 (8122)1 E-4 B,C 6X8 REV SOA III-1-O,C FE-Q ST-Q FS-Q-P R nuary 1989 RR-1 FE-R NOTE 2,4  

SYSTEM MAIN STEAM DWG.NO.C-18002-C NINE MILE POINT UNIT 1 VALVE TEST TABLE CLASS VALVE VALVE NUMBER AND (CAT.)DWG.COOR.SIZE ACTU.NORM.(IN.)TYPE POSIT.AND TYPE TEST REQ.STROKE DIRECT.C.S CHECK JUST.VALVE OR TEST RELIEF DIRECT.REQ.NO.C.S OR ALT.TEST PERF.REMARKS NR108E MSERV-5 (&#xb9;113)1 8 C 6X8 C-4 REV SOA FE-Q ST-Q FS-Q RT-P P I-R O,C RR-1 FE-R NOTE 2,4 NR108F MSERV-6 (&#xb9;123)NR28A Rx.Head PSV NR288 Rx.Head PSV NR28C Rx.Head PSV NR28D Rx.Head PSV NR28E Rx.Head PSV NR28F Rx.Head PSV NR28G Rx.Head PSV NR28H Rx.Head PSV 1 E-5 1 D-1 1 D-1 1 0-1 1 0-1 1 0-1 1 D-1 1 0-1 1 D-1 B,C 6XB REV 6 REV 6 REV 6 REV 6 REV 6 REV 6 REV 6 REV 6 REV SOA SEA FE-Q'T-Q FS-Q RT-P PI-R RT-P O,C SEA RT-P SEA RT-P SEA RT-P SEA RT-P SEA RT-P SEA C RT-P SEA RT-P I I 1-1-7 January 1989 RR-1 FE-R NOTE 2,4  

SYSTEM MAIN STEAM DWG.NO.C-18002-C CLASS VALVE VALVE NUMBER AND (CAT.)DWG.COOR.NINE MILE POINT UNIT 1 SIZE ACTU.NORM.TEST STROKE (IN.)TYPE POSIT.REQ.DIRECT.AND TYPE VALVE TEST TABLE C.S C.S CHECK JUST.OR VALVE OR ALT.TEST RELIEF TEST DIRECT.REQ.NO.PERF.REMARKS NR28J Rx.Head PSV NR28K Rx.Head PSV NR28M Rx.Head PSV NR28N Rx.Head PSV NR28R Rx.Head PSV NR28S Rx.Head PSV NR28T Rx.Head PSV NR28U Rx.Head PSV 1 0-1 1 D-1 1 0-1 1 D-1 1 D-1 1 D-1 1 D-1 1 0-1 6 REV 6 REV 6 REV 6 REV 6 REV 6 REV 6 REV 6 REV SEA SEA SEA SEA SEA SEA SEA C RT-P C RT-P C RT-P C RT-P C RT-P C RT-P C RT-P C RT-P III-1-8 January 1989

SYSTEM MAIN STEAM DWG.NO.C-18002-C NINE MILE POINT UNIT 1 VALVE TEST TABLE CLASS VALVE SIZE VALVE NUMBER AND (CAT.)(IN.)DWG.AND COOR.TYPE ACTU.NORM.TEST STROKE TYPE POSIT.REQ.DIRECT.C.S CHECK JUST.VALVE OR TEST RELIEF DIRECT.REQ.NO.C.S OR ALT.TEST PERF.REMARKS 37-02 Rx Head Vent B.V.83 1 F-3 2 GTV MOA C FE-Q ST-Q PI-R O,C CS-2 FE-C ST-C III-1-9 January 1989

NOTES FOR ATTACHMENT 1 SYSTEM: MAIN STEAM NO.NOTE These valves are in the head spray line which is not used during any mode of normal operation or cold shutdown.IST requirements satisfy SER 26-88.MSIV's 01-03 and 01-04 receive two fail safe tests each cold.shutdown.One test is performed for loss of electrical signal;the second test is performed for loss of air (Ref.IEN 85-84).The setpoint test for the ADS valves consists of a two part process.During the first part, the pressure switch which actuates these valves is subjected to setpoint pressure using a deadweight tester.This verifies that the relay logic picks up at the required setpoint.The second part, consists of manually operating each ADS valve at low power during plant startup following refueling outages.The valves are subjected to reactor steam and verifies that the valve disk opens and steam blowdown to the torus occurs.III-1-10 January 1989

COLD SHUTDOWN TEST JUSTIFICATION MS-CS-1 Valve: Category: Class: Function: Main Steam 01-01: 01-02: 01-03: 01-04 Main Steam Line Isolation ValvesASME Section XI quarterly Test Requirements:

Cold Shutdown Test Just if icati on: quarter ly Part Stroke Testing: Cold Shutdown Testing: Exercise, time and fail safe test (01-03: 01-04)Exercise and time (01-01: 01-02)Full stroke exercising results in loss of steam flow from one main steam line to the turbine causing a reactor trip.Also, recent industry information indicates that closing these valves with high steam flow in the line may be a large contributing factor in observed seat degradation.

The valves are designed for partial stroke exercising with full steam flow during plant operation.

The partial stroke test will verify operability of the valve and operator without the potential for seat damage which could result from full stroke exercising.

Partial stroke close exercise.Full stroke exercise, time and fail safe test.I I I-1-11 Janu ary 1989

COLD SHUTDOWN TEST JUSTIFICATION MS-CS-2 System: Valve: Category: Class: Function: Main Steam Val ves: 37-01 (RHV-BV-1):

37-02 (RHV-BV-3):

37-06 (RHV-BV-2)

Reactor Head Vent ASME Section XI Quarterly Test Requirements:

Cold Shutdown Test Justification:

Exercise and time The design function of these valves is to provide a vent path to primary containment for use during reactor vessel water level changes.Thi s vent path i s only utilized during startup, cold shutdowns and for long-term post-LOCA reactor vessel flooding.There is no design basis which would require these valves to be cycled during reactor power operation.

In addition, cycling these valves during full power operation would significantly reduce the margin of safety of the Reactor Coolant Pressure Boundary since these valves provide a Reactor Coolant/Primary Containment boundary.Failure of the adjacent valve during cycling would introduce a LOCA within the drywell which would affect operation of equipment necessary for safe shutdown.Quarterly Part Stroke Testing: Cold Shutdown Testing: The above justification also applies for partial exerci sing.Full stroke exercise and time.I I I-1-12 January 1989 t'

RELIEF RE(VEST MS-RR-1 System: Valve: Category: Cl ass: Function: Main Steam NR108A,B,C,D,E 8(F ADS Val ves ASME Section XI quarterly Test Requirements:

Basis for Relief: Alternate Testing: Exercise IWV-3412, time IWV-3413 and fail safe test IWV-3415 quarterly IWV-3411 Opening the ADS valves during power operation causes a discharge of steam into the torus.If the valves failed to reclose after testing, the plant would be placed in a loss of coolant transient condition.

In addition, a recent study (BWR Owners Group Evaluation of NUREG-0737 Item II.K.3.16 Reduction of Challenges and Failures of Relief Valves)recommends that the number of ADS valve openings be reduced as much as possible.Based on this study and the potential for causing a possible loss of coolant transient condition, exercise testing of the ADS valves will be delayed to refueling.

Concerning valve stroke timing during exercising, the position indication in the Control Room only indicates ADS Relief Valve pilot position;there is no direct means for detecting the actual position of the valve disk.Actuation of a relief valve is verified by acoustic monitoring of the SRV line discharge to torus.Measuring the time from the initiation signal for the valve and the acoustic monitoring detection provides no meaningful data for predicting valve degradation.

Also, de-energizing the solenoid valve has the same effect as loss of electrical power or loss of control air.Therefore, exercising the valve to it's fail-safe position constitutes a fail-safe test.Exercise at refueling.

III-1-13 January 1989

~4*Cl 4-1 y*I*J'*I~RELIEF REQUEST MS-RR-2 System: Valve: Main Steam 66-07:66-08:66-09:66-10:66-11:66-12:66-13:66-14:66-15:

66-31:66-32:66-33:66-34:66-35:66-36 Category: Class: Function: Vacuum Relief Check Valves on the lines from the AOS Valves to the Torus ASME Section XI, Quarterly Test Requirements:

Basis for Relief: Alternate Testing: Exercise, observe force or torque limitations of PAV-3522(b) quarter ly IWV-3521 The val ves are vacuum breaker check val ves located inside the drywell.The system and valves provide no means for observing operability of the valves other than manually exercising.

This requires entry into the drywell which is not possible during normal operation or cold shutdown because of radiation levels and drywell atmosphere being inert.Also, the valves have no provision for installation of a torque wrench or other device for the purpose of measuring the torque or force needed to operate the valve.Exercising of these valves will be verified by hand exercising during refueling.

III-1-14 January 1989

PUMP AND VALVE INSERVICE TESTING PROGRAM PLAN for NINE MILE POINT NUCLEAR POWER STATION UNIT 1 SECTION III 5.2 ATTACHMENT 2 VALVE TEST TABLES AND RELIEF REQUESTS FOR REACTOR RECIRCULATION OWG.NO.C-18020-C Pages I III-2-1 through III-2-2 I I I-2-1 January 1989

SYSTEM REACTOR RECIRC.DWG.NO.C-18020-C NINE MILE POINT UNIT 1 VALVE TEST TABLE CLASS VALVE VALVE NUMBER AND (CAT.)DWG.COOR.SIZE ACTU.NORM.TEST (I N.)TYPE POSIT.REQ.AND TYPE STROKE DIRECT.C.S C.S CHECK JUST.OR VALVE OR ALT.TEST RELIEF TEST DIRECT.REQ.NO.P ERF.REMARKS 110-127 1 A 1 React.Recirc.K-1 GLV Sample IV MOA C FE-Q ST-Q LJ-R PI-R C 110-128 1 React.Recirc.L-1 Sample IV 1 GLV MOA C'E-Q ST-Q LJ-R PI-R III-2-2 January 1989

PUMP AND VALVE INSERVICE TESTING PROGRAM PLAN for NINE MILE POINT NUCLEAR POWER STATION UNIT 1 SECTION I I I 5.3 ATTACHMENT 3 VALVE TEST TABLES AND RELIEF REQUESTS FOR CONTROL ROD DRIVE DWG.NO.C-18016-C SH.1 C-18016-C SH.2 Pages III-3-1 through III-3-7 III-3-1 January 1989

SYSTEM CRD DWG.NO.C-18016-C SH.l NINE MILE POINT UNIT 1 VALVE TEST TABLE CLASS VALVE SIZE VALVE NUMBER AND (CAT.)(IN.)DWG.AND COOR.TYPE C.S C.S ACTU.NORM.TEST STROKE CHECK JUST.OR TYPE POSIT.REQ.DIRECT.VALVE OR ALT.TEST RELIEF TEST DIRECT.REQ.NO.PERF.REMARKS 106 2 Charging Water 8-4 Isolation Valve 108 2 Scram Discharge A-4 Isolation Valve 126 2 Scram Inlet Valve C-3 127 2 Scram Discharge A-3 Valve 0.5 SCV.75 SCV.75 GLV.75 GLV MAA SEA MAA SEA ADA ADA DE FE-Q DE FE-Q C FE-Q ST-Q FS-Q.PI-R C FE-Q ST-Q FS-Q P I-R F,R RR-1 RR-1 RR-1 RR-1 NOTE 1,5 NOTE 1,2 NOTE 1,3 NOTE 1,3 138 Cooling Water Inlet Check 301-112 Cont.Isol.Valve 301-113 Cont.Isol.Valve 2 D-2 1 L-7 1 M-7 0.5 CHV A,C 3 CHV A,C 3 CHV SEA SEA SEA DE FE-Q DE fE-Q LA-R DE fE-Q LA-R f,R RR-1 RR-3 FE-R RR-3 fE-R NOTE 1,4 III-3-2 January 1989

.~0 SYSTEM CRD DWG.NO.C-18016-C SH.2 NINE MILE POINT UNIT 1 VALVE TEST TABLE CLASS VALVE SIZE VALVE NUMBER AND (CAT.)(IN.)DWG.AND COOR.TYPE ACTU.NORM.TEST TYPE POSIT.REQ.C.S C.S STROKE CHECK JUST.OR DIRECT.VALVE OR ALT.TEST RELIEF TEST DIRECT.REQ.NO.PERF.REMARKS 44.2-15 2 Scram Discharge A-4 Vol.Hld.Tk.IV 44.2-16 2 Scram Discharge B-7 Vol.Hl d.Tk.IV 44.2-17 2 Scram Discharge I-7 Drain IV 44.2-18 2 Scram Discharge J-7 Drain IV 2 GLV 2 GLV 2 GLV 2 GI V ADA ADA ADA ADA 0 FE-Q ST-Q FS-Q LJ-R PI-R 0 FE-Q ST-Q FS-Q LJ-R P I-R 0 FE-Q ST-Q FS-Q LJ-R P I-R 0 FE-Q ST-Q FS-Q LJ-R PI-R RR-2 ST-R RR-2 ST-R I II-3-3 January 1989

NOTES FOR ATTACHMENT 3 SYSTEM: CRD NO.NOTE Typical of 129 Control Rod Drive Hydraulic Units.Proper operation of the Control Rod during Rod Insertion Time testing verifies forward flow opening.Proper operation of the Control Rod during Rod Insertion time testing ver if i es val ve opening and adequate val ve stroke time.Normal control rod motion verifies that these check valves move to their closed position.Each partially or ful ly withdrawn control rod is exercised at least once per week per plant Technical Specifications while at operating conditions.

When fully inserted control rods are withdrawn to a new value, this also has the same effect.Rod motion may not occur if these check valves were to fail in the open position.Also, during refueling, Technical Specification control rod scram insertion time testing verifies proper operation of each of these valves.Proper operation of the control rod during rod insertion time testing verifies proper reverse flow closure of these valves.III-3-4 January 1989

RELIEF REQUEST CRO-RR-1 System: Valve: Category: Control Rod Orive 108:126:127:106:138 (To be done for all 129 HCU's)B (126:127)C (108:106:138)

Class: Function: Reactor ShutdownASME Section XI Quarterly Test Requirements:

Basis for Relief: Alternate Testing: Exercise IWV-3412, time IWV-3413 and fail safe test IWV-3415 quarterly IWV-3411 position indication IWV-3300 (126:127)Verify forward flow opening IWV-3522 quarterly IWV-3521 (108:106:138)

Verify reverse flow closure IWV-3522 quarterly IWV-3521 (106)The Hydr aulic Control Units (HCU)are integrally designed systems (GE)for controlling rod drive movements.

Individual valve testing is not possible without causing a control rod scram with a resulting change in core reactivity.

Scram testing rods at power also introduces degrading wear and tear on control rod drive mechanisms and to the lower region of the reactor vessel due to both thermal and hydraulic shock.In addition, there is high probability that control rod scram testing results in accelerated deterioration of the CRO stub tube area (cracking) due to this thermal and hydraulic shock, a problem identified at NMPl during the 1984 refueling outage and for which a major engineering effort is underway in search of a long term permanent.

repair.Therefore, Niagara Mohawk believes that performing scram time testing during power operation for the sole purpose of verifying proper scram inlet and outlet valve (126,127)stroke times is very undesirable and unwarranted based on these considerations.

The Technical Specification Control Rod Scram Insertion Time testing meets the intent of Section XI testing requirements.

Technical Specification Control Rod Scram Insertion Time testing serves to verify proper operation of each of these valves.Following each reactor scram from rated pressure, the mean 90K Insertion time shall be determined for eight selected rods.If the mean 90%%d insertion time of the selected control rod drives does not fall within the range of 2.4 to 3.1 seconds or the measured scram time of any one drive for 90K insertion does not fall within the range of 1.9 to 3.6 seconds, an evaluation shall be made to provide reasonable assurance that proper control rod drive performance is maintained.

After each major refueling outage and prior to power operation with reactor pressure above 800 psig, all operable control rods shall be scram tested from the fully withdrawn position.Following any outage not initiated by a reactor scram, eight rods shall be scram tested with reactor pressure above 800 psig.III-3-5 january 1989

RELIEF REQUEST CRD-RR-2 System: Valve: Category: Class: Function: ASME Section XI quarterly Test Requirements:

Basis for Relief: Alternate Testing: Control Rod Dr ive 44.2-15:44.2-18 A Scram Discharge Volume Vent and Drain Isolation Valves Exercise IWV-3412 and time IWV-3413 quarterly IWV-3411 Solenoid air pi lot val ves control the air supply to the air actuators for valves 44.2-15 and 44.2-18.The solenoid valves uti 1 i ze two different exhaust paths;one reverse venting path for testing purposes (valve exercising) and one path for normal valve operation (reactor scram conditions).

These solenoids have internal pilots and are not designed for universal operation.

That is, they are not designed to accept dual inlet and exhaust flows.When reverse venting occurs during testing, the air flow is restricted.

Consequently, the stroke times obtained during valve (test mode)operation are much longer than those for valve (safety mode)operation (approximately 140 seconds versus approximately 5 seconds).The test mode operation is not repeatable nor does it represent the safety mode of the valve.Also due to the design of the electrical circuitry, it is not possible to de-energize the solenoid valves and vent via the normal path without causing a reactor scram.These valves will be full stroke exercised quarterly using the testing path.Valve stroke times wi 11 be measured whenever a reactor scram occurs using computer points and/or chart recorders, whereby stroke time obtained will represent normal valve operation.

III-3-6 January 1989

~~RELIEF RE(VEST CRO-RR-3 System: Valve: Category: Class: Function: Control Rod Drive 301-112:301-113 A,C Containment Isolation ASME Section XI guar ter ly Test Requirements:

Basis For Relief: Verify reverse flow closure IWV-3522 quarterly IWV-3521 During al 1 modes of operation, the CRO pumps are normally inservice which discharges to the reactor vessel through these valves at a pressure above reactor pressure.Al ternate Testing: These valves will have reverse flow closure verified during ASNE XI Leakage Testing at refueling.

e III-3-7 January 1989

PUMP AND VALVE INSERVICE TESTING PROGRAM PLAN for NINE MILE POINT NUCLEAR POWER STATION UNIT 1 SECTION III 5.4 ATTACHMENT 4 VALVE TEST TABLES AND RELIEF REQUESTS FOR FEEDWATER/HPCI DWG.NO.C-18005-C SH.2 Pages III-4-1 through III-4-4 III-4-1 January 1989

SYSTEM FEEDWATER/HPCI DWG.NO.C-18005-C SH.2 CLASS VALVE VALVE NUMBER AND (CAT.)DWG.COOR.NINE MILE POINT UNIT 1 SIZE ACTU.NORM.TEST STROKE (IN.)TYPE POSIT.REQ.DIRECT.AND TYPE VALVf TEST TABLE C.S C.S CHECK JUST.OR VALVE OR ALT.TEST RELIEF TEST DIRECT.REQ.NO.PERF.REMARKS 31-01&#xb9;11 FW Riser Isolation Check Valve 1 AC 18 C-4 CHV SEA DE FE-Q LJ-R R CS-2 FE-C 31-02&#xb9;12 FW Riser Isolation Check Valve 1 C-4 A,C 18 CHV SEA DE Ff-Q LJ-R CS-2 Ff-C 31-07 1&#xb9;11 FW Isolation C-4 Valve 31-08 1&#xb9;12 FW Isolation C-4 Valve 18 GTV 18 GTV MOA MOA 0 FE-Q ST-Q LJ-R PI-R 0 FE-Q ST-Q LJ-R PI-R CS-1 FE-C ST-C PE-Q CS-1 FE-C ST-C PE-Q III-4-2 Jan ry 1989 0

COLD SHUTDOWN TEST JUSTIFICATION FW/HPCI-CS-1 System: Valve: Category: Class: Function: FEEDWATER/HPCI 31-07:31-08 A" Feedwater I so 1 ation Va1 ves ASNE Section XI quarterly Test Requirements:

Exercise and time Cold Shutdown Test Justification:

*these valves closed during normal operation would require;a significant reduction in power, isolating one loop of feedwater flow (which also constitutes entering an LCO on HPCI since it would be removing one of two redundant trains), introduces undesirable operational transients which could result in a reactor trip and introduces degrading feedwater nozzle temperature transients which could cause cracking.(Ref.NUREG 0619)quarterly Part Stroke Testing: Partial stroke close exercise.Cold Shutdown Testing: Full stroke exercise and time.III-4-3 January 1989

COLD SHUTDOWN TEST JUSTIFICATION FW/HPCI-CS-2 System: Valve: Category: Class: Function: FEEDWATER/HPCI 31-01:31-02 A,C Feedwater Isolation Check Valves ASME Section XI quarterly Test Requirements:

Verify reverse flow closure Cold Shutdown Test Justification:

Cold Shutdown Testing: Exercising these valves closed during normal operation would require;a significant reduction in power, isolating one loop of feedwater flow (which also constitutes entering an LCO on HPCI since it would be removing one of two redundant trains), introduces undesirable operational transients which could result in a reactor trip and introduces degrading feedwater nozzle temperature transients which could cause cracking.(Ref.NUREG 0619)Reverse flow testing wi 1 1 be performed during cold shutdowns by pressur izing across the valve with water.Reverse flow testing during refueling outages will be verified through Appendix J, type C testing.III-4-4 January 1989

~~C~M PUMP AND VALVE INSERVICE TESTING PROGRAM PLAN for NINE MILE POINT NUCLEAR POWER STATION UNIT 1 SECTION III 5.5 ATTACHMENT 5 VALVE TEST TABLES AND RELIEF REQUESTS FOR CORE SPRAY DWG.NO.C-18007-C Pages III-5-1 through III-5-13 III-5-1 January 1989

SYSTEM CORE SPRAY DWG.NO.C-18007-C NINE MILE POINT UNIT 1 VALVE Tf ST TABLE VALVE NUMBER CLASS VALVE SIZE ACTU.AND (CAT.)(IN.)TYPE DWG.AND COOR.TYPE NORM.TEST POSIT.REQ.STROKE DIRECT.C.S C.S CHECK JUST.OR VALVE OR ALT.TEST RELIEF TEST DIRECT.REQ.NO.PERF.REMARKS 40-01 1 A 12 Core Spray Sys 8128 H-4 GTV Inlet to Reactor Vessel MOA C FE-Q ST-Q PI-R LA-R 40-02 CRS 812 Inlet Outside IV 1 8 J-4 12 GTV MOA FE-Q ST-Q PI-R 40-03 CRS 812 Inlet Outside Check Valve 1 AC 12 K-4 CHV SEA DE FE-Q LK-R RR-2 NOTE 3 40-05 1 A Test IV 812 to Torus K-5 6 GTV MOA C FE-Q ST-Q PI-R LK-R NOTE 3 40-06 1 A Test IV tl 1 to Torus C-5~6 GTV MOA C FE-Q ST-Q P I-R LK-R NOTE 3 40-09 1 A Core Spray Sys 812 A H-3 Inlet to Reactor Vessel 12 GTV MOA C FE-Q ST-Q PI-R LA-R III-5-2 January 1989