Discusses Undetectable Failure in Engineered Safety Features Actuation Sys.Failure of P-4 Permissive Circuit in Both Redundant Protection Trains Could Result in Failure of Sys to Automatically Initiate Protective Function.Details Encl

ML19305B959
Person / Time
Site:	Salem, North Anna, Sterling
Issue date:	11/07/1979
From:	Anderson T WESTINGHOUSE ELECTRIC COMPANY, DIV OF CBS CORP.
To:	Stello V NRC OFFICE OF INSPECTION & ENFORCEMENT (IE)
Shared Package
ML19305B953	List: ML19305B956 ML19305B959
References
NS-TMA-2150, NUDOCS 8003250397
Download: ML19305B959 (13)
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Water Reactor

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Westinghouse .

Electric Corporation Divisions s.355 .

Mnscurgh Pemsytvania 18.230

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' November 7, 1979 NS-TMA-2150 Mr. Victor Stello, Jr. ' -

Director -

Office of Inspection and Enforcement U. S. Nuclear Regulatory Commission Washington, D. C. 20555

Dear Mr. Stello:

Subject:

Undetectable Failure in Engineered Safety Features Actuation System As a result of our continuing reviews of systems important to safety,  !

I Westinghouse has identified an undetectable failure which potentially could J exist in a circuit associated with Engineered Safeguards and which is required for reactor protection. i The specific circuit is described in the attachment. The design function of l the circuit-is a permissive to provide the operator, depending on plant con-ditions, the capability to manually reset and block Safety Injection.

A failure a'nalysis, which assumed a failure of the affected circuit in both of the redundant protection trains (per IEEE-379), showed that the system's ability to automatically initiate the protective function could be lost under certain conditions.

Despite the low probability of the events necessary to set up the conditions, the WRD Safety Review Committee concluded on Novemoer 6,1979, that the poten-tial loss of the protective function is reportable to the NRC under Title 10CFR Part 21 for operating plants and Title 10CFR50.55(e) for plants under construction.

Detailed information, affected plants and recor= ended corrective action is contained in the attachment. This information has already been communicated to the utility owners of the affected plants. .

Please refer any questions to Mr. D. H. Rawlins, the Manager of Safety Standards in the Westinghouse Nuclear Technology Division.

Very truly yours, X/4&nWJ/ .

> T. M. Anderson, Panager Nucle Nf'ty 0 partment FWM/TMA/bek Attachment ,

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' Attachm:nt to NS-TMA-2150 Undetectable Failure in Engineered Safety Features Actuation System (ESFAS)

Design (refer to accompanying typical functional logic diagram)

The P-4 permissive is used to input the status (open or closed) of the Reactor Trip breakers to the Engineered Safety Features Actuation System (ESFAS). This P-4 permissive provides an interlock in the ESFAS to enable or defeat the capability to manually reset and block Safety Injection (SI).

In operation, the initiation of SI instantly trips the reactor and simultaneously starts an electric timer. After a preset time interval, deter-ined by plant specific system analyses, the timer effectively returns system control to the operators for manual reset and block of SI in order to either begin ECCS switchov'er from the injection phase to the recirculation phase or terminate SI. The system permits manual reset and block of SI only if the P-4 permissive indicates that the trip breakers are open (i.e., the reactor is tripped).

During normal plant power operation, the P-4 permissive prevents manual actions whicti could electrically block SI.

Imolementation The P-4 permissive is derived from a switch contact operated via a mechanical linkage within the reactor trip breaker. When the breakers move (open or. closed), the switch contact changes position. The contacts are hardwired to the ESFAS input logic which registers the trip breaker position to allow or prevent operator action as described above.

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During normal plant operation, ESFAS logic is required to be periodically l tested. On newer plants with the Solid : a Prot--tion System, this l l

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testing is performed via automatic self test circuits which verify system operability. On older plants with a relay logic protection system, this testing is performed manually.

1 In addition, the rea,ctor trip breakers are also periodically tested.'

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Potential Concern Currently, the tests described above do not provide for checking the operation of the P-4 contacts or the interconnecting wiring. Therefore, a potential failure of the P-4 contacts or in the wiring would be undetectable.

l IEEE 379 requires that in the case of undetectable failures either (1) ,

provide revised test schemes to identify failures or redesign to

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eliminate them, or (2) in system failure analyses demonstrate that the safety function can be assured assuming both the undetectable failures ,

have occurred and a random single failure has also occurred.

The failure modes of the P-4 contacts are (1) contacts fail to close when the reactor trip breakers open, or (2) contacts fail to open when 9

the breakers are closed. Failure mode (1) could prevent the normal made of resetting and blocking SI and alter the sequence of switchover opera- '

tions from injection to recirculation phase. The consequences of failure l

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mode (2) are such that following a previous initiation of SI and manual i reset and block, the block of SI could remain following the reset of the reactor trip breakers and when the plant was returned to power.

- No credit can be taken for illuminated Control Board windows (lamp

! bulbs) which would alert the operators to the hazard since they are '

not safety grade and are not implemented as such. l l .

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Affected Domestic Plants ,

Operating Plants SSPS '

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D. C. Cook Units 1 and 2 Farley Unit 1 Beaver Valley Unit 1 Trojan

' Salem Unit 1 North Anna Unit 1 Relay Logic Zion Units 1 and 2 .

Prairie Island Units I and 2

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Kewaunee Indian Point Unit 3 Non-Operating Plants SSPS Farley Unit 2 .

Byron Units 1 and 2 Braidwood Units 1 and 2 Virgild.Succer ShearonHarrisdniks1,2,3and4 McGuire Units 1 and 2 Catawba Units 1 and 2

- Beaver Valley Unit 2 Yogtle Units 1 and 2 Jamesport Units 1 and 2 O

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Non-OperatingPlants(continued)

. SSPS Seabrook Units 1 and 1 M111 stone Unit 3 .

. Marble Hill Units 1 and 2 Diablo Canyon Units 1 and 2 .

Salem Unit 2 SNUPPS Units Comanche Peak Units 1 and 2

. South Texas Project Units 1 and 2 Sequoyah Units 1 and 2 '

North Anna Unit 2

- Watts Bar Units 1 and 2 ,

Haven Units 1 and 2 All other domestic plants are unaffected.

Recommended Corrective Actions

. A. Plants Using Reactor Tripped Signal in Safety Injection Reset Circuit of Engineered Safeguards Relay Racks Iion Units 1 and 2 Kewaunee -

Prairie Island Units 1 and Z Indian Point Unit 3 In the Engineered Safeguards Relay Racks for the above plants, a reactor tripped signal (Reactor Trip Breaker RTA and Bypass Breaker BYA open for Train A and Reactor Trip Breaker RTB and Bypass Breaker

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BYB open for Train B) energizes Relay RTA in Train A and Relay RTB in Train B. These relays are located in the rear compartment of

- the relay racks. The relay coils and contacts are tested during on-lina testing of the Safeguards Relay Racks. In addition to this l

l testing. it is necessary to verify that the relays are operated by .

r the auxiliary switch contacts of the Reactor Trip Switchgear. ,

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T. During normal plant operation, immediately verify that relays RTA and RTB are deenergized.

2. After each reactor trip operation, verify that relays RTA and RTB are energized. .

3. After closing the reactor trip , breakers on plant startup, .

verify that relays RTA and RTB become deenergized.

I'f verification shows a relay is not in the correct position, j 4,

I check the interconnecting wires to the Reactor Trip Switchgear l

and the breaker auxiliary switch and cell switch contacts.

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5. Verification of the correct relay position can be made by visual observation of the relays. (For Indian Point Unit 3, verification is made by observing 11e test lamp " Reactor Trip

- Auxiliary Relay" - on the front of the Engineered Safeguards

Relay Rack.)

NOTE 1:~ During on-line testing of the reactor trip breakers, relays I

RTA and RTB do not change position due to the closing of the bypass

- breaker for the test. Following on-line testing of the reactor

- trip breakers, observe that relays RTA and RTB remain energized.

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NOTE 2: The interconnecting wiring from the Engineered Safeguiwds Relay Racks to the Recctor Trip Switchgear for relays RTA and RTB can. be verified during normal plant operation. At the switchgear controi teminal bTocks, use a 0-150 volts de range voltmeter or multimeter to measure the voltage across the two tenninals con- *

- necting the switch contacts to the coil circuit of Relay RTA in the Train A Engineered Safeguards Relay Rack. A nominal 125 volts (dependent upon battery system voltage) reading should be indicated on the voltmeter. A zero reading indicates an open or short cir-cuit in the interconnecting wiring from the relay racks or closed switch contacts, requiring corrective action. Repeat the voltmeter measurement across the two terminals connecting the switch contacts

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to Relay RTB coil circuit in the Train B Engineered Safeguards

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Relay Racks. .

Revise appropriate procedures to require the verification tests noted above following automatic or manual reactor trip. Repeat the tests following reclosure of the reactor trip breakers and prior to rod withdrawal.

. S. Byron /Braidwood/ Marble Hill

- Assure the following test sequence is adopted for each train of SSPS, with the plant at, shutdown and the SSPS in Ncrmal Operation:

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T Place a impson Mode \ '260 multimeter in the 50 VDC range.

2. At the reactor trip switchgear, place the (+) lead on the tenninal leading to the SSPS, TB506-4.

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! 3. Place the (-) lead on the terminal leading to the SSPS, TB506-5. -

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4. The multimeter should read 0 VDC (nominal) with the reactor trip breaker tripped open.

5 This indicates either the reactor trip breaker P-4 contact is properly c,losed, the blocking diode on printed circuit card A519* is failed open or interconnecting wiring is open. The

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diode and wiring will be confirmed in the following steps.

6. With the multimeter still connected as in steps (2) and (3),

close the reactor trip breaker.

7 The multimeter should read 48 VDC (ncminal).

8. This indicates the reactor trip breaker P-4 contact is properly open, and confirms the blocking diode on printed circuit card

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A519* as well as the interconnecting wiring. End of test.

91 Should step (7) not yield a 48 VDC (nominal) reading, either the P-4 contact is not open, the blocking diode on printed cir,cuit card A519* is open, or interconnecting wiring is open.

10. Initiate corrective action.

• 11. At the reactor trip switchgear, place the (+) lead on the terminal leading to the SSPS, TB508-7.

12. P' lace the (-) lead on the terminal leading to the SSPS, TB508-8.

13. The multimeter should read 0 VDC (nominal) with the bypass breaker,associatedwithsteps(4)and(6), tripped. t i

• Located in the SSPS e

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' . This indicates either the bypass breaker P-4 contact is properly closed, the blocking diode on printed circuit card A519* is failed open or interconnecting wiring is open. The diode and

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' wiring. will be confirmed in the following steps.. i CAUTION / ,

DO NOT CLOSE BOTH BYPASS BREAKERS A & B SIMULTANEOUSLY.

I DOING SO WILL RESULT IN ALL BREAKERS INSTANTLY TRIPPIN"

15. With the multimeter still connected as in steps (11) and (12),

close the bypass breaker.

16. The multimeter should read 48 VDC (nominal).

17.~ This indicates the bypass breaker P-4 contact is properly open, and confirms blocking diode on printed circuit card .

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A519* and the interconnecting wiring. End of test.

18. Should step (16) not yield a 48 VDC (nominal) reading, either the P-4 contact is not open, the blocking diode on printed circuit card A519* is open, or interconnecting wiring is open.

- 19. Initiate corrective action.

The appropriate procedures should reflect a requirement to perform the above tests following automatic reactor trip or any condition requiring opening of tae reactor trip breakers. Repeat the tests  ;

- following reclosure of the reactor trip breaks and prior to rod l withdrawal.

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C. Farley Unit 1 D. C. Cook Units 1 and 2. Beaver Valley Unit 1 Tro,1an, Salem Unit 1 North Anna Unit 1

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Inmediately perform the following for each train of SSPS:

1. Place a Siinpson Model 260 multimeter in the 50 VDC range.

2. At the reactor trip switchgear, place the (+) lead on the terminal leading to the SSPS, TB506-4.

3. Plac,e the (-) lead on the terminal leading to the SSPS, TB506-5.

4. ' The multimeter should read 48 VDC (nominal).

S'. This indicates that P-4 contact (s) is (are) properly open, and

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confirms the blocking diode on printed circuit card A518* as

- well as the interconnecting wiring. End of test.

6. Should step ,(4) not yield a 48 VDC (nominal) reading, either P-4

, contact (s) is (are) not open, blocking diode on printed circuit t

caN A518* is open or interconnecting wiring is open.

7._ Initiate corrective action.

Implement the test sequence in part 0 for future periodic. testing when the plant is shutdown. Revise appropriate procedures to require verification by test of the P-4 contact status following autcmatic reactor trip or any condition requiring opening of the reactor trip breakers. Repeat the test following reclosure of the reactor trip breakers and prior to rod withdrawal.

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l t D. All Other Non-Operating Plants With An SSPS Which Are Not Identified in Part B or C

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Incorporate- the following test sequence for each train of SSPS, when the plant is at shutdown- and the SSPS' in normal operation: ,

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1. Place a Simpson Model 260 multimeter in the 50 VDC range.

2. At the reactor trip switchgear, place the (+) lead on the terminal leading to the SSPS, TB506-4.'

3 Place the (-) lead on the terminal leading to the SSPS,'TB506-5.

4. The multimeter should read 0 VDC (nominal). ,

5.~ This.indicatestheP-4 contact (s)is(are)properlyclosed, the blocking diode on printed circuit card A518* is failed open or interconnecting wiring is open. The diode and wiring will be confirmed in the following steps.

6. With the multimeter still connected as in steps (2) and (3),

close the reactor trip breakers.~ .

7. The multimeter should read 48 VDC (nominal).

8. This.indicatestheP-4 contact (s)is(are)properlyopen,and confirms the blocking diode on printed circuit card A518* as well as the interconnecting wirir.g. End of test.

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$hould step (7) not yield a 48 VDC (nominal) reading, either

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the P-4 contact (s) is (are) not open, the blocking diode on

. printed circuit card A518* is not open, or interconnectin'g wiring- is open.

10'. Initiate corrective action. / .

Revise appropriate procedures to require verification, by the above tests, of the P-4 contact status following automatic reactor trip or any condition requiring opening of the ieactor trip' breakers.

Repeat the tests following reclosure of the reactor trip breakers and prior to iod withdrawal.

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