Forwards Sample of AP600 PRA Features,Operational Assumptions & Risk Insights for Passive Core Cooling Sys, Normal RHR Sys & Instrumentation & Control Sys

ML20135A737
Person / Time
Site:	05200003
Issue date:	11/25/1996
From:	Mcintyre B WESTINGHOUSE ELECTRIC COMPANY, DIV OF CBS CORP.
To:	Quay T NRC OFFICE OF INFORMATION RESOURCES MANAGEMENT (IRM)
Shared Package
ML20135A740	List: ML20135A742 NSD-NRC-96-4891, Forwards Sample of AP600 PRA Features,Operational Assumptions & Risk Insights for Passive Core Cooling Sys, Normal RHR Sys & Instrumentation & Control Sys
References
NSD-NRC-96-4891, NUDOCS 9612040023
Download: ML20135A737 (13)
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f Westinghouse Energy Systems Ba 355 '

Pinsburgh Pennsylvania 15230-0355 Electric Corporation November 25,1996 NSD-NRC-96-4891

. DCP/NRC0664 Docket No.:STN-52-003 Document Control Desk U.S. Nuclear Regulatory Commission Washington, D. C., 20555 A'ITENTION: T.R. QUAY

SUBJECT:

SAMPLE OF AP600 PRA INSIGHTS, FRAMEWORK FOR AP600 SEVERE ACCIDENT MANAGEMENT GUIDANCE (WCAP-13914, Rev.1), AND

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RESPONSE TO REQUEST FOR ADDITION INFORMATION

Dear Mr. Quay:

Enclosure 1 provides the important AP600 PRA design features, operational assumptions, and risk insights for the passive core cooling system (which includes automatic depressurization system, core makeup tanks, in-containment refueling water storage tank, passive residual heat removal, and accumulators), normal residual heat removal system, and the instrumentation and control systems (protection and safety monitoring system, diverse actuation system, and plant control system). This information is being provided, as requested by the NRC Probabilistic Safety Analysis Branch, for l developing the final listing of PRA insights that will be included in Chapter 59 of the AP600 Probabilistic Risk Assessment. The staff is expected to review this information and be prepared to i support a meeting by January 10,1997 with Westinghouse to discuss the enclosure with the intent of  ;

finalizing the information. Cindy Haag will contact Mr. Joe Sebrosky of the NRC to arrange the ,

meeting.

Enclosure 2 is a copy of revision 1 of WCAP-13914, " Framework for AP600 Severe Accident I Management Guidance." This WCAP was revised to incorporate commitments Westinghouse made in response to RAI 480.439.

Enclosure 3 provides the revised response to accident management RAI 720.56.

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gc013 9612040023 961125 PDR ADOCK 05200003 A PDR 03*H

Page 2 November 25,19%

i NSD-NRC-96-4891 DCP/NRC0664 WCAP-13914, revision 1, and the response to the RAI closes, from a Westinghouse perspective, the accident management DSER open item 19.2.5-1. The status of this item in OITS will be changed to Action N. The NRC technical staff should review this WCAP.

Please contact Cynthia L. Haag on (412) 374-4277 if you have any questions concerning this transmittal.

W Brian A. McIntyre, Manager Advanced Plant Safety and Licensing Enclosures cc: J. Sebrosky, NRC (enclosures)-

J. Kudrick, NRC (w/o enclosures)

J. Flack, NRC (w/o enclosures)

N. J. Liparulo, Westinghouse (w/o enclosure)

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November 25,1996 l l

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Enclosure 2 to Westinghouse !

Letter NSD-NRC-96-4891 i November 25,1996 i

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Enclosure I to Westinghouse .

Letter NSD-NRC-96-4891 l 1

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' PASSIVE CORE COOLING SYSTEM AUTOMATIC DEPRESSURIZATION SYSTEM ASSUMPTIONS, FEATURES, INSIGHTS *

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. A. DESIGN FEATURES

1. ADS provides a safety-related means of depressurizing the RCS. .

2. '

" . ADS has four stages. Each stage is arranged into two separate groups of valves and lines.

Stages 1,2, and 3 discharge from the top of the pressurizer to the IRWST.  !

Stage 4 discharges from the hot leg to the RCS loop compartment above the post-accident fkxxl up i

level. '

3. Each stage 1,2, and 3 line contains two motor-operated valves ,

j 4. Each stage 4 line contains a motor-operated valve and a squib valve. The motor-operated valve is i nonnally open.

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5. The MOVs in Stages 1,2, and 3 are diverse from the squib valves in Stage 4. ,

6 The valve arrangement and positioning for each stage is designed to reduce spurious actuation of ADS. >

Stage 1,2, and 3 MOVs are nonnally closed and have separate controls 4

In stages 1,2, and 3, interlocks prevent opening of two MOVs in series during testing '

Each stage 4 squib valve has redundant, series controllers Stage 4 is blocked from opening at high RCS pressures l

7. The ADS valves are automatically and manually actuated via PMS, and manually actuated via DAS.

M. The ADS valves are powered from Class IE de power.

< 9. The ADS valve positions are indicated and alarmed in the control room.

B. OPERATION ASSUMPTIONS

1. Stage 1,2, and 3 valves are stroke-tested every 6 months.

2. Stage 4 squib valve actuators are tested every 2 years for 20% of the valves.  !

3. The COL will maintain the reliability of the ADS.

4. ADS is required by the Technical Specifications to be available from power conditions down through refueling without the cavity flooded.

C. RISK INSIGHTS I

1. ADS is a risk-important system for at-power conditions. Common cause failure of the squib vales is a risk-imp >rtant event.

2. Spurious actuation of ADS is an important contributor to the large LOCA initiating event frequency.

3. Depressurization of the RCS through ADS reduces the probability of HPME events.

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PASSIVE CORE COOLING SYSTEM 1

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CORE MAKEUP TANK I ASSUMPTIONS, FEATURES, INSIGIITS A. DESIGN FEATUIES

1. The CMTs provide safety-related means of high pressure safbty injection of borated water to the RCS.  !

2. There are two CMTs, each with an injection line to the reactor vessel /DVI nozzle.

Each CMT has a nonnally open pressure balance line from an RCS cold leg.  !

Each injection line is isolated with a parallel set of AOVs. 1 These AOVs open on loss of Class IE de power, loss of compressed air, or loss of the signal from PMS.

The injection line for each CMT also has two nonnally open check valves in series.

3. The CMT AOVs are automatically and manually actuated from PMS and DAS.

4. CMT level instrumentation provides im actuation signal to initiate automatic ADS and provides the actuation sign:d for the IRWST squib valves to open. i

5. The CMT AOV positions are indicated and alarmed in the control nom. '

l B. OPERATION ASSUMFrlONS '

l 1. CMT AOVs are stroke-tested quarterly.

2. CMT check valves are exercised at each refueling.

l 3. The COL will maintain the reliability of the CMT subsystem.

4 CMT is required by the Technical Specifications to be available from power conditions down through cold shutdown with RCS pressure boundary intact.

l C. RISK INSIGHTS l

1. The CMTs are risk-important for power conditions,hecause the level indicators in the CMTs provide an open signal to ADS and to the IRWST squib valves as the CMTs empty.

2. The CMT RCS makeup function is not risk-important since the accumulators with manual ADS provide a diverse means for RCS makeup.

3. Diversity of the CMT AOVs and PRHR AOVs minimizes the potenti:d for common cause failures.

4 Diversity of the CMT check valves and accumulator check valves minimizes the potential for common cause failures.

5. Risk important events in the CMT subsystem are:

a. Common cause failures of the AOVs

b. Level sensors are imponant.

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PASSIVE CORE COOLING SYSTEM i

1 IRWST ASSUMPTIONS, FEATURES, INSIGIITS A. DESIGN FEATURES

1. l IRWST subsystem provides a safety-related means of performing the following functions: '

Low pressure safety injection following ADS actuation Long-term core cooling via containment recirculation Reactor vessel cooling through the ikxxiing of the reactor cavity following a severe accident.

2. IRWST subsystem has the following flowpaths:

Two redundant injection lines from IRWST to reactor vessel /DVI nozzle. Each line is isolated with a parallel set of valves; each set with a check valve in series with a squib valve.  !

Two redundant recirculation lines from the containment to the IRWST injection line. Each re:tre.

line has two paths: one path contains a squib valve and a MOV, the other path contains a squib valve and a check valve.

The two MOV/ squib valve lines also provide the capability to fhxx! the reactor cavity. I

3. There are screens for each IRWST injection line and recirculation line.

4. Squib valves provide the pressure boundary and protect the check valves from adverse delta-P. l S. Squib valves and MOVs are powered by Class IE vde power.  !

6. The squib valves and MOVs for injection and recirculation are automatically and manually actuated via PMS, and manually actuated via DAS.

7. The squib valves and MOVs for reactor cavity flooding are manually actuated via PMS and DAS from the control room.

8. Automatic IRWST injection at shutdown conditions is provided using PMS 2-out-of-2 low hot leg level  :

logic.

9. The positions of the squib valves and MOVs are indicated and alarmed in the control room.

B. OPERATION ASSUMPTIONS

1. IRWST injection and recire check valves are exercised at each refueling.

2. IRWST injection and recirc squib valve actuators are tested every 2 years for 20% of the valves

3. IRWST taire. MOVs are stroke-tested quarterly.

4 The COL will maintain the reliability of the IRWST subsystem.

5. IRWST injection and recirculation are required by Technical Specifications to be available from power conditions to refueling without the cavity fimxled.

C. RISK INSIGHTS

1. The IRWST subsystem is risk-important.

2. Reactor cavity thxxiing is an important operator action.

3. Diversity of the squib valves in the injection lines and recire lines minimizes the potential for common cause failure between injection and recirculation / reactor cavity flooding.

4. The dominant contributors to IRWST unavailability are:

a. CCF of squib valves in recirculation lines

b. CCF of IRWST injection check valves l

c. CCF of IRWST injection squib valves

d. CCF of screens in IRWST tank plugging

e. CCF of recirculation screen plugging.

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I PASSIVE CORE COOLING SYSTEM PASSIVE RESIDUAL IIEAT REMOVAL ASSUMPTIONS, FEATURES, INSIGIITS A. DESIGN FEATURES i I

1. PRHR provides a safety-related means of performing the following functions:

core decay heat removal during design basis events automatically terminating RCS leak during a SGTR.

2. There is one PRHR HX which is submerged in the IRWST.

3. The PRHR HX Howpath is isolated by parallel air-operated valves. These air-operated valves open on loss of Class IE 125 vde control power, loss of compressed air, or loss of the signal from PMS.

4 The PRHR air-operated valves are automatically actuated and manually actuated from the control room by PMS and DAS.

5. Long-term cooling of PRHR will result in steaming to the containment. The steam will nonnally  ;

condense on the containment shell and retum to the IRWST. If the steam condensation does not return {

to the IRWST, the IRWST volume is sufficient for at least 72 hours8.333333e-4 days <br />0.02 hours <br />1.190476e-4 weeks <br />2.7396e-5 months <br /> of PRHR operation. Connections  !

are provided to IRS'ST from the SFS and CVS to extend PRHR operation.

6. Capability exi.d4. control nom opemtor to identify a leak in the PRHR HX before it can degrr.de to a tube rupture.

7. The positions of the inlet and outlet PRHR valves are indicated and alarmed in the control room.

B. OPERATION ASSUMPTIONS

1. PRHR air-operated valves are stroke-tested quarterly.

2. PRHR is required by the Technical Specifications to be available from power conditions down through cold shutdown with RCS pressure boundary intact.

C. RISK INSIGHTS j

1. PRHR is not one of the most risk-important systems. It is of " medium" importance with respect to the systems modeled in the PRA.

2. The contribution to CDF associated with PRHR HX tube rupture event is small.

3. Diversity of the PRHR air-operated valves from the CMT air-operated valves minimizes the probability for common cause failure of both PRHR and CMT air-operated valves.

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l PASSIVE CORE COOLING SYSTEM l l

l ACCUMULATOR ASSUMPTIONS, FEATURES, INSIGilTS ,

i A. DESIGN FEATURES I

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1. The accumulators provide a safety-related sneans of safety injection of borated water to the RCS.

2. There are two accumulators, each with an injection line to the reactor vessel / DVI nozzle. Each injection line has two check valves in series.

3. The accumulators are pressurized with nitrogen gas. I B. OPERATION ASSUMI'rIONS j

1. Accumulator check valves are exercised at each refueling.

2. The COL will maintain the reliability of the accumulator subsystem.

C. RISK INSIGHTS I

1. The accumulators are risk-important. .

2. Diversity between the accumulator check valves and the CMT check valves minimizes the potential for I common cause failure.

3. The dominant contributor to the accumulator subsystem failure is common cause failure of the check vidves, j

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NORMAL RESIDUAL IIEAT REMOVAL SYSTEM ASSUMPTIONS, FEATURES, INSIGIITS A. DESIGN FEATURES

1. RNS provides a safety-related means of perfonning the following functions:

containment isolation for the RNS piping that penetrates the containment isolation of the reactor coolant system at the RN3 suction and discharge lines makeup of containment inventory following a severe accident.

2. RNS provides a nonsafety-related means of core cooling through:

hot leg recirculation at shutdown conditions low pressure pumped injection from the IRWST and long tenn recirculation from the containment.

3. The RNS has redundant pumps and heat exchangers. The pumps are powered by non-Class IE power with backup connections from the diesel generators.

4. The RNS containment isolation and pressure boundary valves are safety-related. The motor-operated valves are powered by Class IE de power.

5. RNS is manually aligned from the control room to perfonn its core cooling functions. The performance of the RNS is indicated in the control nom.

6. The containment isolation valves in the RNS piping automatically close via PMS with a high radiation sigmd.

7. The RNS containment isolation MOVs are automatically and manually actuated via PMS. The RNS pumps are manually actuated via PLS.

8. Interfacing system LOCA between the RNS and the RCS is prevented by:

each RNS line is isolated by at least 3 valves the RNS equipment outside containment is capable of withstanding nonnal RCS pressure.

9 CCS provides cooling to the RNS heat exchanger.

B. OPERATION ASSUMPTIONS

1. The itC.S pressure boundary isolation MOVs and CVs are exercised during each cold shutdown.

2. The ;ontainment isolation MOVs and CVs are exercised quarterly.

3. Planned maintenance of the RNS is performed at-power.

4. Operating pncedures require RNS and its supporting systems (CCS, SWS, ac power) he available during reduced inventory operations.

C. RISK INSIGHTS

1. RNS is not a risk buport:mt mitigating system for at power and shutdown conditions..

2. A loss of RNS is an important initiating event for shutdown conditions.

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• PROTECTION AND SAFETY MONITORING SYSTEM ASSUMPTIONS, FEATURES, INSIGIITS A. DESIGN FEATURES

1. PMS provides a safety-related means of performing the following functions:

initiates automatic and manual reactor trip automatic and manual actuation of engineered safety features (ESF).

2. PMS has four redundant divisions of reactor trip and ESF actuation. PMS automatically produces a safety-related reactor trip and ESF actuation using 2-out-of-4 logic.

3. PMS has two redundant divisions of post-accident parameter display.

4. Each division is powered from its respective Class IE power division.

5. PMS provides fixed position controls in the control room

6. PMS software development and verification will be perfonned in a way to minimize the potential for common cause failure of software.

B. OPERATION ASSUMf'flONS

1. Continuous automatic PMS system monitoring and failure detection / alarm is provided.

2. The COL will maintain the reliability of the PMS.

3. PMS is required by the Technical Specifications to be available from power conditions down to refueling.

C. RISK INSIGHTS

1. PMS is risk-important.

2. The dominant contributors to PMS unavailability are:

a. Common cause failure of PMS software (includes ESF output logic ESF actuation logic, and ESF input channel software)

h. Common cause failure of ESF hardware (includes ESF output driver card and input channel hardware)

c. Common cause failure of rextor trip breakers.

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DIVERSE ACTUATION SYSTEM ASSUMPTIONS, FEATURES, INSIGIITS A. DESIGN FEATUIES

l. DAS provides a nonsafety-related means of performing the following functions:

initiates automatic and manual reactor trip automatic and manual actuation of selected engineered safety features (ESF).

2. The DAS automatic actuation signals are generated in a functionally diverse manner from the PMS signals. Diversity between DAS and PMS includes different architecture, different hardware implementations and different soitware. This diversity eliminates the potential for CCF between PMS imd DAS

3. DAS provides control nom displays and fixed position controls to allow the operators to take manu:d actions.

4. DAS has two channels and actuates using 2-out-of-2 logic.

B. OPERATION ASSUMPTIONS

1. Operating procedures require DAS reactor trip capability be available during power operations.

2. The COL will maintain the reliability of the DAS.

C. RISK INSIGliTS

1. DAS is not one of the most risk-important systems, it is of " medium" importance with respect to the systems modeled in the PRA I&C-2

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4 PLANT CONTROL SYSTEM ASSUMirrIONS, FEATURES, INSIGHTS 1.

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A. DESIGN FEATURES i

4 l. PLS provides a nonsafety-related means of controlling nonsafety-related equipment.

) _ 2. - PLS receives some of its sensor inputs from isolated PMS sensor inputs.

3. PLS has redundancy to minimize plant transients.

4. PLS provides capability for both automatic control and manual control, s

B. OPERATION ASSUMPTIONS None 2

C. RISK INSIGHTS 1

.l. PLS is not risk-important.

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