ML18037A104

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Forwards Info Discussed During 841114 Meeting Re Containment Isolation to Close Out NRC Question.Info Will Be Incorporated in FSAR Amend 17.W/16 Oversize Tables.Aperture Cards Available in PDR
ML18037A104
Person / Time
Site: Nine Mile Point Constellation icon.png
Issue date: 12/07/1984
From: Mangan C
NIAGARA MOHAWK POWER CORP.
To: Schwencer A
Office of Nuclear Reactor Regulation
References
(NMP2L-0283), (NMP2L-283), NUDOCS 8412110131
Download: ML18037A104 (46)
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Text

REGULATO

'INFORMATION DISTRIBUTION TEM (RIDS)

ACCESS)A NOR:8412110131 Dt)C ~ DATE: 84/12/07 NOTARIZED:

YES DOCKET' FAC)gg 50 410 Nine Mi l e Point Nucl ear Stati one Uni t 2'g Niagara Moha 05000410 AUTH INANE'UTHOR AFFILIATION MANGANeC ~ VS Niagara Mohawk Power Corp'EC IP ~ NAME RECIPIENT AFFILIATION SCH!IENCER,A Licensing Branch 2

SUBJECT:

Forwards info discussed during 841 114 meeting re containment isolation to close out NRC question, Info will be, incorporated in FSAR Amend 17,N/16 oversize tables. Aperture cards available, in PDR ~

DISTRIBUTION CODE:

BOO IO COPIES RECEIVED:LTR ] ENCI.

SIZE:

]'ITLE:

Licensing Submittal:

PSAR/FSAR Amdts 8, Related C rrespondence NOTES; RECIPIENT ID CODE/NAME NRR/DL/ADL NRR LB2 LA INTERNAL: ACRS 41 ELD/HDS3 IE/DEPER/EPB 36 IE/DQA SIP/QAO21 NRR/DE/AEAB NRR/DE/EHEB NRR/DE/GB 28 NRR/DE/MTEO 17 NRR/DE/SGEB 25 NRR/DHFS/LQB 32 NRR/DL/SSPB NRR/DSI/AS B NRR/DS I/CSB 09 NRR/DS I/METB 12" RAB 22 FI E

04 MI/MIB EXTERNAL: BNL(AMDTS ONLY)

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RECIPIENT ID CODE/NAME NRR LB2 BC HAUGHEYgM 01 ADM/LFMO IE FILE IE/DEPER/IRB 35 NRR ROEiM ~ L NRR/DE/CEB 11 NRR/DE/EQB NRR/DE/MEB 18 NRR/DE/SAB 24 NRR/DHFS/HFEB40 NRR/DHFS/PSRB NRR/DS I/AEB 26 NRR/DS I/CPO 10 NRR/DSI/ICSO 16 NRR/DS I/PSB 19 NRR/DSI/RSB 23 RGN1 DMB/DSS (AMDTS)

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M V MIAN,IRK IN U MOHAWK NIAGARAMOHAWKPOWER CORPORATION/300 ERIE BOULEVARDWEST, SYRACUSE, N.Y. 13202/TELEPHONE (315) 474-1511 December 7,

1984 (NMP2L 0283)

Mr. A. Schwencer, Chief Licensing Branch No.

2 Division of Licensing Office of Nuclear Reactor Regulation U.S.

Nuclear Regulatory Commission Washington, DC 20555

Dear Mr. Schwencer:

Re:

Nine Mile Point Unit 2 Docket No. 50-410.

Enclosed for your use is information regarding Containment Isolation for Nine Mile Point Unit 2 which was discussed with the Nuclear Regulatory Commission staff durng a meeting on November 14, 1984.

The information is provided to close out this staff question.

The enclosed information will be included in Final Safety Analysis Report Amendment 17.

Very truly you'rs, C.

V. Mang Vice President Nuclear Engineering 5 Licensing NLR:ja Enclosure xc:

R. A.

Gramm, NRC Resident Inspector Project File (2) 1207

--80~21iocb, 05000PDR 0131-84 410 pog AD

0 r,

C

UNITED STATES OF AMERICA NUCLEAR REGULATORY COMMISSION In the Matter of

)

)

Niagara Mohawk Power Corporation

)

)

(Nine Nile Point Unit 2)

)

Docket No. 50-410 AFFIDAVIT C. V. Mangan

, being duly sworn, states that he is Vice President o

Niagara o

aw ower orporation; that he is author ized on the part of said Corporation to sign and file with the Nuclear Regulatory Cotmnission the documents attached hereto; and that a11 such documents are true'nd cor rect to the best of his know1edge, information and belief.

Subscribed and swor to before me, a Notary Publi in and for the State of New York and County of

, this ~

day of s 1984.

N ary ub

>c

>n and or

County, New York My Comnission expires:

JANIS M. MACRO Notary public In tho State ol New York Qu Illled ln Onondaga County No. 478455+

ra, rmmlsslon fsplres hlarOII 30r 19..trap.

Nine Mile Point Unit 2 FSAR TABLE 6.2-56

{Cont)

KEY TO ISOLATION SIGNALS:

A = Low reactor vessel water level 3

B = Low reactor vessel water level 2

C = High main steam line radiation D = High main steam line flow E = High main steam line tunnel area ambient temperature F = High drywell pressure H = Steam supply pressure low J = High reactor water cleanup system equipment, area differential or ambient temperatures, or turbine building high space temperature, or reactor water 1 5 cleanup high differential flow K = Reactor core equipment area steam supply

pressure, high isclation cooling high pipe routing or ambient or differential temperatures, low pressure.

High steam line differential turbine exhaust diaphragm pressure L = High reactor vessel pressure M = High residual heat removal system equipment area differential or ambient temper atures P = Low main steam line turbine inlet pressure R = Low main condenser vacuum S = Standby liquid control system actuated T = High main steam line tunnel differential temperature W = High reactor water cleanup system nonregenerative heat exchanger outlet. temperature 1

5 X = Low reactor vessel water level 1

Y = Standby gas treatment exhaust radiation high LC = Locked closed RM = Remote manual switch from control room 15 Amendment 15 17 of 24 November 1984

Nine Mile Point Unit 2 FSAR TABLE 6.2-56 (Cont)

LMC = local manual

control, locked

.closed, position indication in control room NOTES:

Type C testing is discussed on Figure 6.2-70 which shows the isolation valve arrangement.

Further discussion on Type A and C testing is also provided in Section 6.2.6.

(2)

Provisions have been made in the control room to secure closed the main steam drain line valves 2MSS¹SOV97A,B,C,D.

Power supply fuses for these valves are removed during normal plant operation except during startup and shutdown or during periods of operation with associated main steam line in board isolation valve (2MSS¹HYV6A,B,C, or 0) closed.

Normal status position of valve (open or closed) is the position during normal power operation of the reactor (see Normal Position column).

Pximary containment and reactor vessel isolation signals are indicated by lette,'rs.

Isolation signals generated by the individual system process control signals or for remote manual closure based on information available to the operator are discussed in the referenced notes in the Isolation Signal column.

The specified closure rates are as required for containment isolation or system opex ation, whichever is less.

Reported times are in seconds.

The standard minimum closing rate is 12 in/min of nominal valve diametex for gate valves and 4 in/min of valve stem travel for globe valves.

For example, a

12-in gate valve will close in 1 min.

Ac motor-operated valves required for isolation functions are powered from the ac standby power buses.

Dc.-operated isolation valves are powered from safety related station battexies.

A main steam isolation valve requires that two spring latches be released to close the valve.

One spring latch released will not close the valve, thus pxecluding a spurious actuation.

The valves are designed to fully close within 3 to 5 sec.

18 of 24

Nine Mile Point,Unit 2 FSAR TABLE 6.2-56 (Cont)

'~'All isolation valves are Category I.

4'All motor-operated isolation valves remain in the as-is position upon failure of valve power (FAI = Fail as is).

All air-operated valves close on motive air failure in the safe position.

'Testable check valves are designed for remote opening with zero differential pressure across the valve seat.

The valves will close on reverse flow even though. the test switches may be posi+ioned for open.

The valves open when pump pressure exceeds reactor pressure even though the test switch may be positioned for close.

(12)

The Hydrogen Recombiner System will be included in Type A Testing with the isolation valves in their operating position, eg. valve open.

In

addition, Type C Testing of the primary containment isolation valves will be performed.

~'These valves are the ECCS and drywell spray suction and discharge isolation valves.

ECCS operation is essential during the LOCA period; therefore, there are no automatic isolation signals.

A high level alarm in the appropriate reactor building sump indicates excessive ECCS leakage into the secondary containment.

~'Suppression pool spray valves have interlocks that allow them to be manually reopened after automatic closure.

This setup permits suppression pool spray, for high drywell pressure conditions.

When automatic signals are not

present, these valves may be opened for test or operating convenience.

'Due to redundancy within the

ECCS, some subsystems may be secured during the long-term cooling period.

In

addition, RHR Loops A and B have several discharge paths (LPCI, drywell
spray, suppression chamber
spray, suppression pool cooling) which the operator may select during the. 30-day post-LOCA period.

6 'The RCIC'team exhaust valve, 2ICS*MOV122, is normally open at all times.

Should a leak occur, it would be detected and alarmed by the RCIC room high temperature leak detection system.

'Criterion 55 concerns lines of the reactor coolant pressure boundary (RCPB) that penetrate the primary reactor containment.

The CRD insert and withdraw lines are not part, of the RCPB.

The classification of the 19 of 24

Nine Mile Point Unit 2 FSAR TABLE 6.2-56 (Cont) insert and withdraw lines is Quality Group B, and therefore they are designed in accordance with ASME Section III, Safety Class 2.

The basis to which the CRD lines are designed is commensurate with the safety importance of isolating these lines.

Since these lines are vital to the scram function, their operability is of utmost concern.

In the design of this system, it has been accepted practice to omit automatic valves for isolation purposes as this introduces a possible failure mechanism.

As a means of providing positive actuation, manual shutoff valves are used.

In the event of a break on these

lines, the manual valves may be closed to ensure isolation.

In

addition, a ball check valve located in the insert line inside the CRD.

is designed to automatically seal this line in the(event of a break.

'The operator's indication that remote-manual closure of the TIP shear valves is required is failure of the TIP ball valves to close.

'Since the traversing incore probe (TIP) system lines do not communicate freely with the containment atmosphere or the reactor coolant, General Design Criteria 55 and 56 are not directly applicable to this specific class of lines.

The basis to which these lines are designed is more closely described by Criterion 57, which states in

'ffect that isolation capability of a system should be commensurate with the safety importance of that isolation.

Furthermore, even though the failure of the TIP system 3.ines presents no safety consideration, the TIP system has redundant isolation capabilities.

A aP~m<

pgeupTloN u)lu OK FQeLAEQ69 FOR-7'Lp bqsTGHc QQQRR sRR44~

The safety features were reviewed by the NRC for BWR/4 (Duane Arnold),

BWR/5 (Nine Mile Point Unit 2) and BWR/6 (GESTAR II), and it was concluded that the design of the containment isolation system meets the objectives and intent of the general design criteria.

Isolation is accomplished by a seismically qualified solenoid-operated ball valve that is normally closed.

To ensure isolation capability, an explosive shear valve is installed in each line.

Upon receipt of a

signal (manually initiated by the operator),

this explosive valve will shear the TIP cable and seal the guide tube.

20 of 20

Nine Mile Point Unit 2 FSAR TABIE 6.2-56 (Cont)

When the TIP system cable is inserted, the ball valve of the selected tube opens automatically so that the probe and cable can advance.

A maximum of five valves can be opened at any one time to conduct calibration, and any one guide tube is used, at most, a few hours per year.

If closure of the line is required during calibration, a

signal causes a cable to be retracted and the ball valve to close automatically after completion of cable withdrawal.

If a TIP cable fails to withdraw or a ball valve fails to

close, the explosive shear valve is actuated.

The ball valve position is indicated in the control room.

The Unit 2 TIP system design ppecifications require that the maximum leakage rate of the ball and shear valves be in accordance with the Mangfacturer '

Standardization Society (hydrostatic testing of valves).

The TIP isolation valve and the shear valve both have a

leak integrity requirement of; 10

~ atm cc/sec for air-water combination and water alone.

This leakage rate represents less than 10 3 cc/sec of fluid at the following conditions:

Air-water combinations:

0-125 psig and 300 F

Water:

1,250 psig and <450'F As stated

above, the penetration is automatically closed following use.

During normal operation the penetration will. be open approximately 8 hr/month to obtain TIP information.

If a failure occurred, such as inability to withdraw the TIP

cable, the shear valve could be closed to isolate the penetrations.

Installation requirements are that the guide tube/penetration flange/ball and shear valve composite assembly not leak at a

rate greater than 10

~ atm cc/sec at'25 psig.

Further leak testing of the shear valves is not recommended since destructive testing would be required.

The periodic surveillance testing of the shear valves will be performed per NMP2 Technical Specification Requirements identified in Section 3/4.6.3 paragraph 4.6.3.5.

21 of 24

Nine Mile Point Unit 2 FSAR TABLE 6.2-56 (Cont)

Removable spool piece that is removed during normal operation; it is installed when the plant is down and fire protection is needed inside the primary containment.

'~Air-operated valves 104 and 106 are manually operated before personnel entry into the primary containment.

Line length is given for the most remote valve.

'~ 'ystem isolation valves are normally closed.

The system is placed in operation only if the hydrogen monitors detect hydrogen buildup after a

LOCA.

The operator has flow indication, in the main control

room, of gas leaving and entering the containment.

Should these flows vary significantly from one another, it would be detected in the main control room and the process loop in service could be shut down.

'~~'This line consists of the following inputs from these valves:

2RHS*SV34A and 2RHS*SV62A - steam condensing line safety valves.

2RHS*RV56A RHR heat exchanger shell side relief valve.

2RHS*MOV26A and 2RHS*MOV27A -

RHR heat exchanger vent line isolation valves.

2RHS*V20 and 2RHS*V19 - vacuum breaker line.

2RHS*RVV35A and 2RHS*RVV36A - vacuum breakers.

The valve is open only during steam condensing mode.

Valve position is indicated in the main control room to provide the operator confirmation of valve status.

22 of 24

Wp

Nine Mile Point Unit 2 PSAR TABI,E 6.2-56 (Cont)

'" 'This line consists of the following 'nputs from these valves:

2RHS~SV34B and 2RHS~SV62B steam condensing line safety valves.

2RHS*RV56B RHR heat exchanger shell side relief valve.

2RHS*MOV26B and 2RHS*MOV27B RHR heat exchanger vent line isolation valves 2RHS*V117 and 2HS*V118 - vacuum breaker line 2RHS*RVV35B and 2RHS*RVV36B vacuum breakers The valve is open only during steam condensing mode.

Valve position is indicated in the main contrcl room to provide the operator confirmation of valve status.

'~~'Penetrations Z-99A,B,C,D, and Z-100A,B,C,D contain lines for the hydraulic control of the reactor recirculation flow control valve.

These lines contain hydraulic fluid used to position the reactor recirculation flow control valve.

23 of 24

Nine Mile Point Unit 2 FSAR TABLE 6.2-56 (Cont)

Integrity of the system is, essentially, constantly monitored since the system is under a constant operating pressure of 1,800 psig.

Any leakage through this system would be noticed because operation would be erratic ~cut because of indications provided on the Hydiaulic Control gnit.

in addition, in order to perform Type C tests on these lines, the system would have to be disabled and drained of hydraulic fluid.

This is considered to be detrimental to the proper operation of the system since possible damage could occur in establishing the test condition or restoring the system to normal.

These lines and associated isolation valves should therefore be considered to be exempt from containment testing.

A specific exemption will be forwarded under separate cover.

'~7'Instrument lines that penetrate primary containment conform to Regulatory Guide 1.11.

The lines that connect to the reactor pressure boundary include a

restricting orifice inside containment, are Category I, and terminate in instruments that are Category I.

"he instrument lines also include manual isolation valves and excess flow check valves These penetrations will not be Type C

testect since the integrity of the lines. is continuously demonstrated during plant operations where subject to reactor operating pressure.

In addition, all lines are subject to the Type A

test pressure on a

regular interval.

Leaktight integrity is also verified with completion of functional and calibration surveillance activities as well as by visual observations during operator tours.

'~Signal B

or F cause automatic withdrawal of tip probe.

When probe is withdrawn, the solenoid-operated ball valve automatically closes by mechanical action.

'~~'This path does not constitute a bypass leakage

path, because a

closed piping system outside the primary containment provides a

leakage boundary.

The piping/components outside the primary containment qualify as a closed system for the following reasons:

a.

The system leakage boundary leak path does not directly communicate with the environment following a loss-of-coolant accident.

b.

The system leakage boundary piping/components are designed in accordance with Quality Group B

standards as defined by Regulatory Guide 1.26.

24 of 24

Nine Mile Point Unit 2 FSAR TABLE 6.2-56 (Cont) c.

The system'eakage boundary is designed to meet Seismic Category I design requirements.

d.

The system leakage boundary is designed to at least the primary containment pressure and temperature design conditions.

e.

The system leakage boundary is designed for protection against pipe

whip, missiles, and jet forces in a manne" imilar to that for engineered safety features.

f.

The system leakage boundary is tested for leakage, unless system integrity is demonstrated to be maintained during normal plant operations.

'This line/path is excluded from further consideration as a potential bypass leakage

path, because a

water or nitrogen sea) is provided to prevent leakage from bypassing the secondary containment.

There is sufficient fluid available to maintain the seal for at least 30 days following a loss-of-coolant accident (see Section 6.2 '.2.3 for seal details).

'~'This line/path is excluded from further consideration as a potential bypass leakage path because (per Branch Technical Position CSB.6-3, Section A) leakage from the primary containment cannot circumvent the secondary containment boundary and escape directly to the environment; that is, leakage cannot bypass the leakage collection and filtration systems of the secondary containment.

Filtration of leakage is assured, because either the piping terminates in the secondary containment or leakage is directly routed to the filtration systems.

'~~'In addition to a swing check valve inside containment and a positive acting check valve outside containment, similar 'to an Atwood-Morrill boiler feed check valve as described in Catalog 63,Section I, a third valve with high leak-tight integrity will be provided in each line outside containment.

The spring-loaded piston operator of the positive acting check valve will be held open by air pressure during normal operation.

Fail-open solenoid valves will be used to release air pressure to permit the check valve piston operator to close.

The positive acting check valve and the high leak-tight Amendment 15 24a of 24

.November 1984

Nine Mile Point Unit 2 FSAR TABLE 6.2-56 (Cont) integrity isolation valve will be remote manually operated from the control

room, using signals which indicate loss of feedwater flow.

The classification of the feedwater lines from the reactor vessel to and including the third isolation valve will be Code Group A; beyond the third valve, Code Group D.

'Bypass leakage through these penetrations is via the post-accident sample system branch connections.

Leakage volumes are accounted for as post-accident sampling system bypass leakage.

(34)

Due to the metal bellows arrangement on tip drywell penetration flanges they will be included in Type A Testing rather than Type B Testing.

(35)

For ILLRT test connections containing a single valve and threaded pipe

cap, the threaded pipe cap will be verified in place and tight every 31 days.

24b of 24

Nine Mile Point Unit 2 FSAR connection the line is Class D.

In a postulated failure of this line, the flow rate through the broken line has been calculated to be substantially less than that permitted for a

broken instrument line.

Continued recirculation pump seal purge is required whenever reactor coolant temperature is above 200'F and the pump is not isolated.

Three check valves in series, two outside the primary containment, are used to provide containment isolation while permitting seal purge, if available.

This design willprevent seal damage during containment isolation events.

Therefore, automatic isolation valves are not desirable.

The seal purge lines are continually pressurized (and therefore leak tested) above reactor pressure.

Thus, any leakage from these lines would be detected either through the floor drain system monitors or by routine surveillance by plant operators.

In addition, the seal purge pressure is continually monitored by pressure transmitters with control room indication.

Therefore, the integrity of these lines is continuously verified.

Effluent Lines Effluent lines that form part of the RCPB and penetrate primary containment are equipped with at least two isolation

valves, one inside the drywell and the other
outside, located as close to the primary containment as practical.

Table 6.2-56 also contains those effluent lines that compose the RCPB and penetrate the primary containment.

1.

Main Steam Main Steam Drain Lines and RHR Shut-down Coolin Lines The main steam lines extend from the RPV to the main turbine and condenser

system, and penetrate the primary containment.

The main steam drain lines also penetrate the containment.

The RHR steam supply line/RCIC turbine steam line connect to the main steam line inside the drywell and penetrate the primary containment.

Isolation is provided by automatically actuated block valves inside the primary containment for the RHR steam supply line/RCIC'urbine steam line.

The RHR shutdown cooling effluent line has automatically actuated block valves for isolation.

2.

Recirculation S stem Sam le lines A

sample line from the recirculation system penetrates the drywell.

The sample line is 3/4 inch in diameter and is designed to ASME Section III, Safety Class 2.

Two solenoid-operated valves which fail closed are provided, one inside and one outside located as close to the primary containment as practical.

0 0

, ~

Conclusion on Criterion 55 In order to assure protection against the consequences of accidents involving the release of radioactive

material, pipes forming the RCPB have been shown to provide adequate isolation capabilities on a case-by-case basis.

In all cases, a minimum of two barriers were shown to protect against the release of radioactive materials.

In addition to meeting the isolation requirements stated in Criterion 55, the pressure-retaining components that compose the RCPB are designed to minimize the probability or consequences of an accidental pipe rupture.

The quality requ'ements for these components ensure that they are

'0

~ c

Pene-tration No Z-1A Z-1B Z-1C Z-1D System Desianation Hain steam Line A

Bain steaa Line drain line Main steaa Line 8

Naia steaa L>ine 8

drain line Hain steam Line C

naxn steaa Line C

drain line Hain steaa Line D

Hain steaa Line D

drain line GDC or Reg Guide ESP SYstem Pluid Size ging 55 Mo Stean 26 55 Steam 26 gv 3/Iy>>

55 No Steam 26 55 Mo Steaa 26 PSAR Arrange-ment Pioure<4>

6 2-70 Sh.

1 6 2-70 Sji.

1 6 2-7D Sji.

1 6 2-70 Sji 1

Location of valve Inside/

Outside Primary Contain-ment Length of Pipe - Con-tainment to Outside Isolation Valve Inside Outside 5 ~

2n Outside 022TSIOE 36 ~

On IS - io" Inside Outside 5 ~

2n Outside OLIC4I '0 F 36 I On I5 (4

Inside Outside 5 ~

2n Outside

()L2CS I OE 36 ~

On IS I Sn Inside Outside 5'2n Outside 364&v Oors(zIE IK -I Type Test

<4)

C C

C C

C C

C C

C Potential Bypass Leakage Path Yes Yes Yes Yes Number SMEC GE 2NSS4'BYV6A 2HSS4'BYV7A B22-P022A B22-P028A T-YPB Ball Ball 2HSS4HOV208 ZIIIS4n SOV 'I IA ISZZ-no49 A GY obe (2 LOlbE 2HSS4BYV6B 2HSS4BYV78 822-F0228 822-F0288 Ball Ball 2NSS4HOV208 ZIIISS 4-Sov'9ve BZZ FO41 8 Globe 42LOBE Ball Ball 2HSSeHOV208 2(riss irsov97L.

Globe IA22.- FO4)<

2HSSeBYV6D 2HSSvBYV7D 2HSS4HOV208 ZniSS+~ 97D B2 2-F022 D 822-P028D (Azz Fo(2'! SI Ball Ball Globe IILoISO 2HSSvBYV6C

. 822-P022C 2HSS4BYV7C 822-P028C Oper-atoi BYV BYV HOV sov BYV BYV HOV Sov BYV BYV HOV SCIv BYV BYV BOV msv Hydraulic to open; spring to close Elec ELu<..

N/A Manual N/A Hydraulic to open; spring to close Elec.

ELEC.

Manual l</*

Hydraulic to open; spring to close Elec.

E.LEC..

Hydraulic to open; spring to close Elec.

E LE<. ~

Manual

)I/A N/A Manual N/A

. Actuator Node P~rzmar SecondarI

,TI

'APERTURE

,CARD Mine Mile Point Unit 2 PSAR TABLE 6.2-56 CONTAINHEMT ISOLATION PROVISIONS POR FLUID LIMES Closure Tiae (4

4>

Valve< 4>

Position Normal Post-Rover

<4>

Shutdovn Accident pailure<io>

Isola-tion Signal

<4>

Notes Closed Closed Closed X AC,D, ErvrTI R ~ RM 3 to 5 sec Open Closed Closed

<LOSED Closed cl ooED PAI II C rD I CLOSEn ~

E F

TIRIFM EIri(zh Closed XrCIDr E ~ P ~ R ~

T,RE 9 sec N/A 3 to 5 sec Open Closed Closed losed 4OSED Closed CLOI ED Closed I. LCD en PAI X,C,D,E 9 sec CLOSED~

Pr FITr RH

~ u(2I(z)

N/A Closed ACIDS 3 to BIFID 5 sec RE RH Closed Closed pen PAI I,CID~ B 9 sec

<LCIDGC2~

P ~ RIT ~ RH L ~(z>

Nl)L closed X ~ C ~Dr 3 to E,P,T, 5 sec RIRM Closed cLos En Closed

<LCDED Closed CLODE>>

Closed Closed Open Closed

(.(4>DED Closed CLOS EO closed C(.<D a. O PAI X,C,D,E, 9 sec Lv E~(z)

N/A Pover Source

<4)

Div I N/A M/A Div I (2(/A M/A Div I Div I N/A Z-2 Hain steaa 55 No Steam 6

6.2-70 Inside drain line Sh.

2 Outside 1 ~ -0" C

C Yes 2HSS4HOV111 B22-P016 Globe 2HSS4HOV112 822-P019g Globe HOV Elec.

Manual Closel Closed Closed PAI HOV Elec.

Manual Closed Closed Closed PAI 38 sec I ~ C ~ D ErprTr F. ~ RH XICrDr 38 sec E ~ PITIRr RH Div II Div I Amendment 15 1 of 2a November 198D SVI~rJoisi oi-

r zamgg

,Cog Pene-tration No Z-4)L System Desianation Feedvater line A to RPV GDC or Reg ESF Guide Svstem Plaid 55 No Water Size gin)

FEAR Arrange-ment

~Pi ure<L>

24 6-2-70 Sh.

3 Location of valve Inside/

Outside Primary Contaia-ment Outside Inside Length of Pipe - Con-tainment to Outside Isolation v alve

~

1 Li Type Test

< L '>

Potential Bypass Leakage Path Number SREC GP.

Tes<ma>

2FRSeAOV23A 822-F032 A 2FW S+V1 2A 8 22-F010A TIRe Sving Check Sving Check Oper-ator AOV N/A Actuator Node Normal Primarv Secondarv

<v>

Process Spring

'pen (test only).

Process N/A Open Nine Nile Point Unit 2 FSAR TABLE 6. 2-56 (Cont)

Valve<v>

PositionPost-Pover Accident Failureme Source

<v>

The time N/A it takes for one valve volume to pass through the valve Isola-tion Signal 0>

<v>

R ever se flov'everse flov No tes 11,32 Oatside 16 ~ -4v Water 8

6.2-70 Outside 57'8" Sh.

3 2FWSvNOV21A 822-F065A 2RCSvHOV200 G33-P040 Open NO V Elec.

Nanual Gate Globe NOV Elec.

Nanual

Open Closed Open Closed FAI Closed FAI N/A Div I N/A Div I Z-48 Feedvater 55 No Water 24 6.2-70 Inside line 8 to RPV Sh 3

Outside 2'-1" C

Yes<*a>

2FWSvV128 822-F0108 2FWSvAOV238 822-P0328 Sving Check Sving Check Open Open

)

N/A Process N/A AOV Process Spring (test only Close d Close 0 N/A Closed Closed N/A Reverse flov Reverse flov The tame N/A it takes for one valve volume to pass through the valve 11 ~ 32 Z-5A Z-58 Z-5C RHS Pump A

suction from suppression pool RHS pump 8

suction froa suppression pool RHS pump C

suction from suppression pool 56 Yes Rater 8

Water 24 6 2-70 Sh 3

6.2-70 Sh.

Outside 16'-4" Outside 65 ~ -8" Outside 5'-6" 56 Tes Water 24 6.2-70 Outside 9'-9" Sh.

4 56 Tes Water 24 6.2-70 Outside 20 ~-9" Sh 4

2PRS+NOV218 822-F0658 2WCS+NOV200 G33-P040 C

NoC*V>

2RHSVNOV1A E12-P004A C

No< vv >

2RHSvNOV18 E12-F0048 C

No<*a>

2RHSeNOV1C 812-P004C Gate NOV Globe Nov Tricen-NOV tric butter-fly Tricen-NOV tric butter-fly Tricen-NOV tric butter-fly Elec L>ac Elec.

Elec.

Elec.

Nanual Nanual Banual Hanual Nanual Open Open Opea Opea Open Closed Open Closed Closed Closed Closed Closed Open Open Open FAI FAI PAI FAI FAI Rh N/A Div II N/A Div I Div I 13 3S RN 45 Div II 13L35 45 RN 45 Div II 13 35 1

Z-6A RHS test line Loo p B to sup-pression pool 56 Yes Rater 18

6. 2-70 Sh 6

Outside 9 ~ -1 C

No<me 2RHSvNOV308 E12-P2018 Tricen-NOV tric butter-fly Elec.

Nanual Open Closed Open Div I 1535 I

November 198>

PAI Amendment 15 0

psI Gl(oisi oa-85

Nine Bile Point Unit 2 1'SAR Pene-tration System No.

Designation GDC or Reg Guide ESP

~sste m

Fluid Size ginl psaR Arrange-ment F~i ure(()

Location of valve Inside/

Outside Primary Contain-ment Length of Pipe-contain-ment to Outside Isolation Valve Type Test Ci)

Potential Bypass Leakage Path S REC Number TIP Q Oper-ator Actuator Node P~rimar second~mr Normal (3) valve(9)

Position Post-Shutdovn Accident Pover Failure((o)

Isola-tion Signal (9)

Closure Time (9 9)

TABLE 6 2-56 (Cont)

Pover Source Cv)

Notes Z-6B RBS test line Loop A to sup-pression pool 56 Tes Water 18 6 2-70 Sh 6

Outside 9 ~

3n No( *9) 2RHS950V308 E12-P201A Tricen-tric butter-flY HOV Elec.

Hanual Open Closed Open FAI RH 85 Div II 15,35 2-7A 2-7B RHS containment spray Loop A

to suppression pool RRS containment spraY Loop B

to suppression pool 56 56 Tes Tes Water 4

Water 4

6 2-70 Sh 7

6 2-70 Sh.

7 Outside Outside 18'-3n 4 ~

6n NO(mv)

No( << 9) 2RBS950V33A E12-F027B Globe 2888950V338 E12-P0278 Globe 5OV HOV Elec.

Elec.

5anual Hanual Closed I

I IClosed Closed Closed Open Open PAI PAI BE F9RH 15 Div I '4 ~ 15, 55 ')

B 9P988 15 Div II 14n15) 2-BB Z-9A RBS containment spray Loop B

to dryvell RHS/L PCI Loop A to RPV 2-9B PBS/LPCI Loop B to RPV 2-9C RRS/LPCI Loop C to RPV Z-Ba RRS containment spray Loop A

to dryvell 56 56 55 55 55 Tes Tes Tes Tes Tes Water 16 Water 16 Rater 12 Water 12 Water 12 6 2-70 Sh.

8 6 2-70 Sh 8

6 2-70 Sh 9

6 2-70 Sh.

9

6. 2-70 Sh 9

Outside Outside Outside Outside Outside Inside Outside Inside Outside Inside 2i pn 11 ~

2n 2(

pn 9 ~

6n 7 ~

pn fi ~

6n 6 ~

6n C

C C

C C

C C

C C

C NO(mv)

NDC 2 9)

No(av)

No(*9)

No(a9) 2RRS950V25A 288svHOV15A 2858950V258 2RBS480V158 2RHs980v24A 2RBS9AOV16A 2RHSC'HOV248 2RHS9AOV16B 2RBS950V24C 2RRSvaOV16C E12-F017a 812-P016A E12-F017B E12-F0 16B 512-P042A 512-F041A E12-F0428 812-P041 8 E1 2-PO 42 C 812-PO 41 C Gate Gate Gate Gate Gate Check Gate Check Gate Check HOV 5OV HOV NOV HOT AOV HOV AOV HOV AOV Elec.

Elec.

Elec.

Elec.

Elec.

Process Elec.

Process Elec.

Process Hanual Hanual Hanual Air

{Test onlY)

Hanual closed Hanual Closed Closed Closed Hanual Closed Air Closed (Test only)I Hanual Closed Air Closed'Test only) I Closed Closed Closed Closed Closed Closed Closed Closed Closed closed Closed Closed Open Open Open Open Open Open Open Open Open Open paI PAI PAI FAI PAI Closed flov PAI Closed PAI Closed RH 87 RH 87 RH 87 88 87 RH 19 Reverse 8/A 95 19 Reverse 8/A flov RH

-19 Reverse 8/a flov Div I Div I Div II Div II Div I Div I 13,15i 5S 13915) l 11 ~ 13, 15 Div II Div II 11 ~ 13r 15 Div II 11 ~ 13, Div II 15 amendment 15 3 of 24 November 1984

Nine Nile Point Vnit 2 PSAB TABLE 6.2-56 (Cont)

Pene-tration No GDC or S ystem Reg.

Desianation Guide Z-101 RBS shutdovn return Loop l to reactor recirc Loop A

55 55 RRS shutdovn cooling re-turn line inboard valve by-pass line recirc Loop B

O Z-10B RBS shutdovn 55 return Loop B to reactor ESP system No No No Pluid Size jin)

Water 12 Water 12 Water 2

FSAR Arrange-ment Picure<<)

6 2-70 Sh 13 6 2-70 S11 13

6. 2-70 Sh.

13 Location of valve Inside/

outside Primary Contain-ment Outside Inside Inside Outside Inside Length of Pipe - Con-tainment to Outside Isolation Valve 6 ~

pw 6r pa T'ype Test C i)

C Potential Bypass Leakage Path No C zv )

Number SWEC GE 2RBSvHOV40A E12-P053A Globe 2RBSvAOV39A E12-P050A Check 2RBSvHOV67A E12-F099l Globe Oper-ator NOV AOV HOV Valve<>>

Position Power Post-Pailure Shutdovn Accident

<io)

Actuator Node Normal Ca) elec.

Process Elec.

Hanual Closed Open Closed Closed PAI Closed Closed Open Air (Test only Closed 5 anual Closed Closed PAI Hanual 2BBSvAOV398 E12-P0508 Check AOV Process Air (Test only Closed Open Closed Open Closed Closed PAI Closed C

No< mv) 2RBSC'HOV40B E12-F0538 Globe HOV Elec.

Isola-tion Signal Ca)

Closure Time ArLr5 ~

??5 25 Reverse 5/A flov lrerHr RH A,L,H, 25 RN Reverse 5/A flov Pover Source C'r )

Notes Div I Div I Div I Dxv II 11 Div II RHS shutdovn 55 cooling re-turn line inboard valve bypass line No Water 2

6 2-70 Sh.

13 Inside 2RBS*HOV678 E12-F0998 Globe HOV Elec Hanual Closed Closed Closed PAI ArLrH~

9 RN Div II Z-11 RBS shutdovn 55 supply from reactor recirc Water 20 6 2-70 Sh.

14 Outside Inside 6 ~

pa C

No< *a) 2RBSa'HOV113 E12-F008 Gate NOV Elec.

2RBSeHOV112 E12-F009 Gate HOV Elec.

Hanual Hanual Closed Open Closed Closed Open Closed lrLrH~

27 RH Are 5'7 RN Div I Div II Z-12 Z-13 CSH suction 56 from sup-pression pool CSB test 56 return to suppression Tes Yes Rater 20 Water 12 6.2-70 Sh.

5 6 2-70 Sh.

15 Inside Outside 2'-2'utside 50r+fv 2RBS eRV(52 Belief 5/A Auto C

Yes<no) 2csBmHOV118 E22-F015 Gate HOV Elec C

No< am) 2CSBeHOV111 E22-P023 Globe HOV Elec Hanual Hanual Closed Closed Closed Closed Closed Open Closed N/A 5/A 5/l Div III 13)35 18 FAI BrP,BN 60 Div III Err Closed Closed Closed FAI RPCS min flow bypass Tes Water 4

Outside 45r-lv 2CSBeHOV105 E22-F012 Gate HOV Elec.

Hanual Closed Closed Closed

'FAI RH 5

Amendaent 15 Div III 35 4 of 24 Noveaber 1984

C ine Nile Point Unit 2 FSAR Pene-tration No.

System Desianation

- GDC or Reg.

Guide 55 Z-15 CSL suction 56 from suppres-sion pool Z-14 CSH to RPV ESP System Yes Yes Fluid Size iin)

Mater 12 Water 20 P SAR Arrange-ment Fiaure<))

6.2-70 SIL.

9 6.2-70 Sh Location of valve Inside/

Outside Primary Con ta in-ment Inside Outside Outside Length of Pipe - Coa-tainment to Outside Isolation Valve 2 ~

Ph 1

~

Hh Type Test

<))

Potential Bypass Leakage Path SMEC Number GE Type Oper-ator No<ms) 2CSHsAOV108 E22-F005 Check AOV 2CSHhNOV107 E22-F004 Gate NOV No<?V) 2CSLhNOV112 E21-P001 Batter-NOV fly Actuator Primary Process Elec.

Elec.

Valve<v)

Positio Node Normal Secondarv Shutdovn Closed Air

'losed (Test only)

Closed Closed Nanual Hanual Open Open Pover Post-Pailure Accident

<<a)

Open Closed Open Open Isola-tion Signal

<h)

Closare Time Pover Source Notes Reverse N/A flov 12 90 Div III 11,13 Div III DIu x 13>'3S I

TABLE 6. 2-56 (Cont) 0 Z-16 Z-17 CSL to RPV 55 ICS suction 56 from suppres-sion pool Yes Yes Water 12 Mater 6

6 2-70 Sh 10 6.2-70 Sh.

5 Inside Outside Outside 1 ~

Ph P ~

9h 2CSL hNOV1 04 E2 1-F005 Yes< xn) 2ICSmNOV136 E51-F031 Gate Gate No<ah) 2CSLmAOV101 E21-F006 Check AOV NOV NOV Process Elec.

Elec.

Closed Closed Closed Closed Nanual Hanual Air Closed Closed (Test onlY)

Open Open Open Closed PAI PAI 16 19 Reverse N/A flov RN RN Div I 11 ~ 13 Div I

(

Z-18 ICS minimum flov to sup-pression pool Yes Water 2

6.2-70 Outside 0'-6h Sh 11 C

No'v) 2ICSmNOV143 E51-F019 Globe NOV Elec.

Nanaal Closed Closed Closed FAI RN 5

125VDC 55 Z-19 ICS turbine exhaust to suppression pool 56 Yes Steam 12 6.2-70 Outside 1

~ -6h Sh 12 C

No<ah) 2ICSmNOV122 E51-FP68 Gate HOV Elec.

Hanaal Open Open Open PAI RN 85 125VDC 16 >'KS I

Z-20 Spare No 3/4 APERTURE CARD Amendment 15 5 of 24 November 1984

Pene-tration No System Designation GDC or Reg.

ESP Guide Svstem Pluid Size gin)

PSAR Arrange-ment Pioure<<<>

Location of valve Inside/

Outside Primary Contain-ment Length of Pipe - Coa-i aiament to Outside Type Isolation Test Valve

<<1>

Potential Bypass Leak age Path Number Tl)Ie 0 per-ator Actuator Node valve<9>

Nine Nile Point Vnit 2 PSAR TABLE 6. 2-56 (Cont)

Closure Time

<9 r>

Pover Source

<7>

Isola-Position tion Normal Post-Pover<lo) Signal Cz>

Shutdovn Accident Pailure c>>>

Notes Z-21A Steam to ICS turbine and RHS heat exchaagers 55 Yes Steam 10 6.2-70 Sh.

16 outside Inside

) ~

9 n C

C No<99>

2ICS9HOV121 E51-P064 Gate 2ICSmboV128 E51-P063 Gate HOV HOV Elec.

Elec.

Hanual Hanual Open Open Closed Closed Open PAI Open FAI H,K,RH H,K ~ RH 14 14 Div I Div II ICS turbine steam supply bypass to inboard isolation valve Steam Inside No<*9>

2ICS9HOV170 E51-P076 Globe HOV Elec.

H anual Closed Closed Close<<1 FAI NrKrRN Div II Z-21B Spare Z-22 ICS to RPV RHR reactor head spray 55 Yes Water 6

6.2-70 Outside Sh 17 Inside Outside Water 6

6.2-70 Sh.

17 Oatside

) ~

6n 4 ~

39 29 ~ - 5n C

C 2lcsnAOV157 2ICsnHOV126 E51-P066 Check P12-P013 Gate Process Elec.

AOV HOV 2RHsnHOV104 E12-P023 Globe HOV Elec.

I No<99>

2ICS9AOV156 E51-P065 Check AOV Process Open Open closed Closed Open Hanual Air (Test only) Closed Air (Test only) Closed Closed Open Open Open Closed Closed Rev. flew N/A Closed Rev. fl<<w N/A PAI PAI A'L2

. RN 125VDC I 25vcrC 125 Vcr<<.

Div I Z-23 WCS supply from RCS 6

RPV 55 No Water 8

Water 8

6 2-70 Sh.

18 Inside Outside II 3>>

c Yes< vo > 2wcsnHov102 533 FnoI GlOhe HOV C

2MCS9HOV112

<<33-F>>OH GlOhe HOV Elec.

ELec.

Hanual Hanual Open

'pen Open Opea Closed Closed PAI PAI BrJrSrRN 13 RN Div Ir Div I Z-24 Spare No Z-25 RDS lines to RPV 53 Insert 53 Withdraval Yes Water 1

N/A 3/4 outside Outside 125 ~

On 125 ~ -On No<99>

See Note 17 Z-26 RDS lines to RPV 39 Insert 39 Withdraval Yes Water 1

N/A 3/4 Outside 125'-On Outside 125 'On Nocv9>

See Note 17 c

Z-27 FDS lines to RPV 54 Insert

'4 Withdraval Yes Water 1

N/A 3/4 Outside outside 125 'On 125'-On No<29>

See Note 17

'Amendment 15 6 of 24 November 198>

Pene-tration No.

Systea DesiHnation RDS lines to RPV 39 Insert 39 With-draval 2-28 2-29 SLCS to RPV 2-301 Spare 3

2-30B Spare 2-311 TIP drive guide tube to RPV TIP drive guide tube to RPV 2-31B TIP drive guide tube to RPV 2-31C TIP drive guide tube to RPV 2-31D TIP drive guide tube to RPV 2-31E 2-32 Nv purge to TIP indez mechanisa 2-331 CCP supply to RCS Pump 1

GDc or Reg Guide 55 57 57 57 57 57 56 56 FSAR arrange-ment Sire fin)

ESF 8~stem Pluid Yes Water 1

N/1 3/4 Boron 1 1/2 6 2-70 solu-Sh.

43 tion Yes 6 2-70 Sh.

19 1 1/2 Note 19 6 2-70 Sh 19 1 1/2 Note 19 1

1/2 6 2-70 Sh 19 Note 19 1 1/2 Note 19 No 6 2-70 511 19 No 6 2-70 Sh.

19 1 1/2 Note 19 1

1/2 6 2-70 Sh. 42 So No 6 2-70 Sh 20 Water 4

Location of valve Inside/

outside Primary Contain-ment Length of Pipe - Con-tainment to Outside Type Isolation Test Valve C ~ )

Potential Bypass Leakage Path Nuaber SWEC NOC av)

Outside Outside 125 ~

Oa 125 ~

Ov C

No(*I) 2SLSeV10 C41-F007 2SLSvBOV5A C41-F0061 Inside Outside 2 '-10" Outs'ide 3 ~ -10" 2SLsvNOV58 C41-P006B Outside Outside 2 ~

av 2'-4" Noes))

C51 J004 C51 J004 5 ~

4a 5I All Outside Outside NOC3 I)

C C51-J004 C51-J004 N/1 S/1 Outside Outside 2 ~

4m

'1

~

4 II Noes))

S/1 N/1 C51 J004 C51-J004 Outside Outside 2 ~

4v 2I Ca No(3))

N/1 S/1 C51-J004 C5 1-J004 Outside Outside 2l 7v 2 I 7a NOC3))

N/1 S/1 C51 J004 C5 1-J 004 7 ~ -6a Outside So(*))

2GSsvV168 2GSsvy169 2GSSvvlyo outslae Inside!

6 ~

3a Inside Outside C

C No(3))

2ccpvHOV94A 2CCPeBOV171 7 ~

Ov TYpe Check stop check g lobe Stop check globe Ball Shear Ball shear Ball Shear Ball Shear Ball Shear Check Check Check Gate Gate Oper-ator BOV BOV SOV S/1 SOV S/1 SOV N/1 SOV N/1 SOV N/1 BOV BOV Nine Bile Point Unit 2

FSAR TABLE 6. 2-56 (Cont)

Valve(v)

Position Isola-tion Signal

(()

Pover Failure C10)

Closure Power Tiae Source Notes lctuator Bode Primarv Secondarv Normal Shutdown Post-Accident See Note 17 N/A i

Closed Closed

. Hanual 'losed Closed Closed Closed Reverse N/1 flow Reverse N/1 flov Process Elec.

Closed Closed Elec.

Closed Closed Banual Closed Reverse S/1 flov S/1 Elec N/1 Closed Open N/1 N/1 Closed Open Closed Open B,F,<tu s/1 RB N/A Closed Opea 120 VAC 18 ~ lgv 125 VDC 28 Elec.

N/1 N/1 N/1 Closed Open Closed Open Closed Open Closed Open BUFFER)I N/1 RB N/A 120 VAC 18 ~ 19 125 VDC 28,3I Elec.

N/1 Closed Open N/1 N/1 Closed Open Closed Open Closed Open 8 ~ P ~'K))

N/1 RB N/A 120 VAC 18 ~ lg 125 VDC 28)24 Elec N/1 N/1 N/1 Closed Open closed Open Closed Open Closed Open Bi P ~ E)l N/1 RB N/A 120 VAC 18I19 125 VDC 28, %4 Elec.

N/1 S/1 N/1 Closed Open Closed Open Closed Open Closed Open B ~ Fertu N/1 RH N/A 120 VAC 18 ~ lg ~

125 VDC 28 Process Closed Closed Open Open Open Reverse S/1 flov R e v er se N/1 flov Reverse S/1 flov 8iP,RB 20 ReF,RN 20 34 Process Process S/1 Closed Closed Closed Closed N/1 N/1 Elec.

Elec.

Ban mal Banual Open Open Closed Closed open Open PAI PAI Div II Div I Aaendmeut 15 of 24 Noveaber 1984

Sine ljile Point Unit 2 FSlR TABLB 6I 2-56 (Cont)

Pene-tration No Z-338 Z-341 Systea Desianation CCP to RCS Pump 8

CCP return from RCS Pump 1

GDC or Reg Guide 56 56 ESP est ea Plaid Water Water Size iinj PSAR Arrange-s ent F~i ure(i) 4 6.2-70 Sh 20 4

6 2-70 Sji 21 Location of valve Inside/

Outside Primary Contain-ment Inside Outside Ii(SIDE Inside Outside 7 ~

On C

C I4/A 7 ~

On C

C Length of l>ipe - Con-tainment to Outside Type Isolation Test Valve Ci) potential Bypass Leakage Path(3)

NDC3l)

NDC31)

Number SWEC GE 2CCPvEOV948 2CCPvEOV178 zcc I v kv I"Io 2 CCPv EOV1 61 2CC P v 5 OV 1 51 TIHB Gate Gate IIEL>EF Gate Gate Oper-ator EOV EOV I4/A EOV EOV Elec.

Elec.

AI)TO Elec Elec 5anual Hanual t>jjA Eanual Eanual Actuator Node

~primar Secondary Valvecv)

Open Open CCOIEb I

Open open Open Open

( LISI Eb Open Open Closed Closed CCATS Eb Closed Closed Position Soraal Post-Shutdovn Accident Po ver Failure(ia)

PAI FAI N/A FAI FAI Isola-tion Signal C I ')

8 ~ FIRE 8 ~ F ~R5 jj/A BIPIRE BnF ~ RE closure Tiae 20 20 N/A 20 20 j>over Source Notes Div II Div I

>(/A Div II Div I Z-348 CCP retura froa BCS Pump 8

56 No Water 4

6 2-70 Sji.

21 Inside Outside I>j SI DE.

7 ~

On C

C N/A NoC3()

2CCP 3 EOV 1 68 2ccpnEOV158 Zcc j> }I we Il I Gate Gate ZEI>EF EOV EOV N/A Elec.

Elec.

  • u I()

i(annal Eanual I(/A Open Open CCC)S Eb Open Open CCQ SED Closed Closed

( C(>S E. >b PAI PAI

~/A 8 ~ F ~ RE BIF ~ RE D>/A 20 20 I>jijj Div II Div I Z-35 Z-36 Z-37 Z-381 Z-388 Z-39 Z-40 S pare Service air to dryvell Breathing air to dryvell RDS to recirc pump A seal RDS to recirc Pump A seal Dryvell floor drain tank vent line Equipment drains from dryvell 56 56 55 55 56 56 so so No Air Water Water air Water 2

6. 2-70 Sji 22 2
6. 2-70 Sh.

22 3/4

6. 2-70 Sh.

23 3/Ij 6 2-70 Sh.

23 6

6 2-70 Sh 24 4

6. 2-70 Sh 24 Outside Inside Outside Inside 0'-7n 0 ~ 7n Inside Outside 0 ~

On Inside Outside 0 ~

On Outside 31'-On Inside Outside 1 ~

Bn Inside Outside 4 ~

2n Outside 33'-Dn C

C C

C C

C No(3))

Nocv ~ )

2SASmHCV161 2SASvHCV163 2AASn HCV134 2AASnHCV136 No<<>>

2RCSvV608 835-F0138 2RCSvv908 835-F0098 2RCSvV598 835-F0178 Yes( *a) 2DFR*EOV121 2DFRv EOV120 2DERvEOV119 Yes(*u) 2DER450V120 jro(*a) 2RCS 3 V60A 835-F0131 2RCSvV90A 835-F009a 28cs*v59a 835-F017a Globe Globe Globe Globe Hanual Eanual jlanual Eanual

)(annal Eanual Eanual Hanual Check N/1 check N/1 Check N/a Process Process Process Check N/1 Process Check N/1 Process Gate Gate 5OV EOV Elec.

Elec.

Gate Gate EOV EOV Elec.

Elec.

Check N/1 Process N/1 N/1.

N/A N/1 N/1 s/a Eanual ljanual 5anual Eanual Closed closed Closed Closed Open Opea Open Open Open Open Open Open Open Open Open Open Open Open Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed 'losed N/1 5/A N/a N/1 FAI Fal FAI PAI LEC ~ LC N/1 LEC ~ LC 5/1 LECILC R/1 LHCILC N/1 Reverse flov N/1 Reverse flov N/1 Reverse flov N/1 Reverse flo 3 N/1 Reverse flov N/h Reverse floe N/1 B,F,RE 28 B>FAIRE 28 B,FIRE 22 8 ~ F ~ RE 22 Div I Div II Div I Div II N/a Div II Div I Div II Div I Amendment 15 8 of 24 Noveaber 198(

C:

El 4Pgg~

c~~4e Nine Mile Point Uait 2

FSAR TABLE 6.2-56 (Cont)

Pene-tration

~No 2-41 Z-42A SYstem Designation Reactor coolant recirc to sample cooler Fire protection for reactor recirc pump GDC or Reg.

Guide ESP System 55 56 No Fluid Water Size ging FSAR Arrange-ment Fi ure<))ater 2

6. 2-70 Sh 26 3/4 6 2-70 Sh.

25 Location of valve Inside/ Outside Primary Contain-ment Inside Outside Inside Outside Length of Pipe Contain-ment to Outside Isolation Valye p ~ pv 3 ~ p II Type Test C)) Potential Bypass Leakage Path C C No< a ~ ) C No<ac) C 2RCSvSOV}04 2RCSmSOV105 2PPWmSOV219 2FPWvSOV218 B35-F019 B35-F020 }}umber SWEC GE TIRe Globe G lobe Globe Globe Oper-ator SOV SOV SOV SOV Elec. Elec. Elec. Elec. 8/h 8/h N/h 8/h Actuator Node Normal <3) Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Valve< v) Position Post-'hutdovn Accident Closed Closed Closed Closed B C ~ RH BvCvRH B ~ P ~ RH BiF~R5 Isola-tion Pover Signal Pailure<< a) Closure Time 5/h 8/h 8/h 8/h Pover Source Hotes Div II Div I Div II Div I 2-42B Fire protection vater for reac-tor recirc pump Dryvell floor drains 56 56 No No Water 2 Water 6 6 2-70 Sh 26

6. 2-70 S}1. 27 Inside Outside Inside Outside 3 ~

0 II 20 ~-10v C C C C Noc 3<) Yes< *o) 2FPW+SOV221 2FPWvSOV220 20PReHOV140 2DFRm HOV139 Globe Globe Gate Gate SOV SOV HO V HOV Elec. Elec. Elec. Elec. 8/h N/h Hanual Hanual Closed Closed Open Open Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed FAI FAI B ~ P ~ RH BE FeRH BrFeRH BE FeRH 8/h 5/h 13 13 Div II Div I Div II Div I }5 2-44A Capped spare 2-445 Capped spare Z-44C Capped spare Z-44D Capped spare 2-44E 2-44P 2-45 Service air to drYvell Breathing air to dryvell Zguipment drain tank (2DER-TK1} vent to dryvell 56 No 56 No 56 No hir 2 hir 2 hir 2 6 2-70 Sh 22 6 2-70 Sh. 22 6.2-70 Sh. 27 Outside Inside Outside Inside Inside Outside p ~ 5m 0< 5v p< pe C C C C C C NoC m)) No< a)) 'YesC mo ) 2SAS+BCV160 2SASvBCV}62 2AAS+BCV135 2AASmBCV137 2DERm}}OV130 2DERmHOV i31 Globe Globe Globe Globe Globe Globe HOV HOV Elec. Elec Hanual Hanual Hanual Hanual Hanual Nanual Hanual Hanual 8/h 5/A 5/h N/h Hanual Hanual Closed Closed closed Closed } Open Open Open Open Open Open Closed Closed Closed Closed Closed Closed Closed Closed 8/h 8/A 8/h N/h FAI FAI LHC ~ LC LHCiLC LHC ~ LC LB'C B ~ P ~ RH B ~ F ~ BH N/h 8/h 8/h N/h 9 9 / Div I Div II Div I Div II Div II Div I 2-46A CCP supply to dryvell space cooler No Water 8 6 2-70 Sh 28 Inside Outside 7 ~ ON C C Noc m<) 2CCPvHOV273 2CCPmHOV265 Gate Gate HOV HOV Elec Elec. }}annal Hanual Open Open Open Open Closed Closed FAI FAI BiF~R5 B~F~RH 36 38 Div II Div I I L Amendment 15 9 of 24 Noveaber 1984

TI ERTURJP. CARD Nine Nile Point Unit 2 FSAR Pene-tration System Mo. Designation Z-468 Capped spare G.DC or Beg. Guide ESP ~Sste s Pluid Size gin} PS}LR Arrange-ment ~i<tureC)) Location of valve Inside/ Outside Primary Contain-ment Length of Pipe - Con-tainaent to Outside Type Isolation Test Valve Pote ntial Bypass Leakage Path SWEC Number Oper-ator Actuator Node Pri~mar Sec~ondar valveg>> Position Normal Post- <3) Shatdovn Accident Isola-tion Pover Signal FailureCio) Clos are Time Poser Soarce Notes TABLE 6. 2-56 (Cont} Z-46C Fire protection vater for con-tainment hose reel standpipe See Note 20 No 431) Z-46D Capped spare Z-47 C} z-ss CCP return from dryvell space cooler Purge erhaust from dryvell 57 56 No Air 14 No<3)) Rater 8 6.2-70 Sh 28 6 2-70 Sh 29 Inside Outside Inside Outside 7 ~ 3 II 7'-4' C No(31) 2ccpvHOV122 2CCP>HOV124 No43)) 2cpswAOV108 2CPSvAOV)10 Gate Gate Butter-fly Butter-fly HOV HOV AOV iLOV Elec. Elec. Pneu-matic Pneu-matic Hanaal Hanual Nanual Hansel Open Open Closed I closed open Open Closed Closed Closed Closed Closed Closed PAI P}LI Closed closed Bs Fs TrRH BsysysRH 5 Div II Div I 8',RH 38 Div II B,P,RH 36 Div I Z-50 Purge inlet to vetvell Z-51 Purge ezhaust from vetvell Z-49 Purge inlet to dryvell 56 56 56 No Air/Ns 12 Air 12 Air/Ns 14 6.2-70 S}L 29 6 2-70 Sh 29 6.2-70 Sh. 29 Inside Outside 4 ~ Oz Inside Outside 4 ~ 3 II Inside Outside 6s-es Notva) 2CPSsAOV106 2CPSvAOV)04 Nota)) 2CPSsAOV107 2CPSsAOV105 No43)) 2CPSvAOV109 2CPSsAOV111 Butter-fly Butter-fly 'utter-fly Butter-fly Butter-fly Butter-fly AOV AOV AOV AOV AOV AOV Pneu-matic Pneu-matic Pneu-matic Pneu-satic Pneu-matic Pneu-matic Hanual Hanual Hanaal Hanual Hanaal Hanual Closed Closed Closed Closed Closed Closed Closed Closed closed Closed closed Closed Closed Closed Closed closed Closed Closed Closed Closed Closed Closed Closed Closed BsFsyaRH B ~ FsysBH 5 Bays TsRH 5 B ~ FsysRH B sF ~IsRH B ~ PsT ~ RH 5 Div II Div I Div II Div I Div II Div I Z-52A Cap pe d spare Z-52B Capped spare Z-53A Instrument air-to ADS valve accumulators 56 No Ns 1 1/2 6.2-70 Outside 1 ~-0II C 2IAS 3'SOT 1 64 Sh. 30 Inside C Yes< 3LL) 2IASsV448 Globe Check SOV Elec N/A N/A Process N/A Open Open Open Open Open Open Closed N/A 8 F BH N/A Div I Reverse N/A N/A flov Amendment 15 10 of 24 November 1984

Nine Nile Point Unit 2 PSAR TABLE 6. 2-56 (Cont) Pene-tration No Z-53B Systea Desianation Instrument air to ADS valve accumulators GDC or Beg. Guide. 56 ESF System No }'la}.d Na Size ging 1 1/2 PSAR Arrange-ment }'i ureC>> 6.2-70 S}1 30 Location of valve Inside/ Outside Primary Contain-ment Outside Inside Length of Pipe - Con-tainment to Outside Isolation Valve 11 Pn Type Test C1) C C Potential Bypass Leakage Path YesC 30l Number SNEC GE 2IAS0SOV}65 2IASnV449 TYRe Globe Check Oper-atRR SOV N/A actuator Node Prim~ar seconda~r 5/A 5/h Elec. Process ValveCv) Position Normal Post-Shutdovn Accident OPEIL C)PE)L Open Open Open Open Pover PailureC 10 3 Closed 1)lA Isola-tion signal Ch) Clos ure Tiae Cv 0) 8 nF n R 5 N/A Reverse 5/h flov Pover Source Cv) Div II N/A Notes f Z-53C Instrument air to NSRV accumu-lator tank 56 No 1 1/2

6. 2-70 S}1 30 Outside Inside 1 ~

pn C C I Yesc 303 2IAS1'SOV166 2IAShSOV184 Globe Globe SOY SOV Elec. Elec. 8/A 5/h open open Open Open Closed closed closed Closed B)P,RN 8 ~ F)RH 5/A 8/A Div I Div II Z-54a Capped spare Z-55A , Hydrogen recoa-biner lA supply to vetvell 56 Yes air 3

6. 2-70 511 31 Inside Outside 21 PL)

A) C A) C NoC3 ~ ) 28CS050Vah 2BCSnNOVla Globe Globe NOV NOV Elec. Elec. Hanual Nanual Closed Closed Closed Closed Open Open FAI PAI 8 ~ P)BH B,PnR5 19 19 Div I Div I Z-558 Z-56A Z-568 Z-57A Z-578 Hydrogen recom-biner 18 supply to vetvell Hydrogen recom-biner 1A return from dryvell HYdrogen recom-biner 18 return from dryvell Nyrdogen recom-biner 1A return from vetvell Byrodgen recom-biner 1B return from vetvell 56 56 56 56 56 Yes Yes Yes Yes Yes lir 3 Air air 3 Air

6. 2-70 S}1.

31 6 2-70 Sh 31 6.2-70 S}L 31

6. 2-70 S}1 31
6. 2-70 S}1 31 Inside Outside Inside Outside Inside Outside Inside Outside Inside Outside 21 Pn 2 ~

Qff 2 ~ Qh 2 ~ Pll 21 Qh A>C A)C A,c A)C A,C Ac A,c A)c A)c A>c NoC 31) 'Noc 31') NC>C 313 Noc 313 NC>C 313 28CS350V48 28CSnNOV 18 28CSnHOVSA 2RCS050V3A 2BCS050V68 28CSnHOV38 2HCS1'HOV5l 2BCS350V2A 2BCSSNOV58 2BCSnNOV28 Globe Globe Globe Globe Globe Globe Globe Globe Globe Globe NOV NOV NOV NOV NOV HOV 50V NOV HOV NOV Elec. Plec. Elec Elec. Elec. Elec. Elec. Elec. Elec. Elec. Hanual }}anual 5 anual Nanual Ban ual Nanual Nanual Hanual Hanual 5anual Closed Closed Closed Closed Closed Closed Closed Closed IClosed Closed Closed Clo ed Closed Closed Closed Closed Closed closed Closed Closed Open Open Open Open Open Open Open Open Open Open PAI FAI PAI PAI PAI FAI PAI PAI PAI PAI 8 nP )RN 8 ~ F ~ RH BnPnRH 8 )P ~ RH 8hy)RN BnpnRH B,P,RH 8 ~ P ~ RN B)F ~ RH B,PhR}} 19 19 19 19 19 19 19 19 19 19 Div II Div II Div I Div I DiV II DiV II DiV I Div I Div II DiV II LZ, LZ.) }Z., Z-58 Containment purge to dry-vell 56 Air

6. 2-70 Sh 29 Inside Outside 3 ~

4)I NoC 31$ 2CPS 1'SOY 1 22 2CPSmSOV120 Globe Globe SOV SOY Elec. Elec. 5/h Closed Closed Closed Closed Closed Closed Closed Closed B)FBI RH B,Pny BH DiV II Div I amendment 15 11 of 24 November 1984

TI APERTURE ,CARD Nine Bile Point Unit 2 PSAR TABLE 6.2-56 }cont} Pene-tration System No. Designation GDC or Reg. ESP Guide ~S stem Plaid Size ging FS AR Arrange-ment Fioure(i) Location of valve Inside/ Outside Primary Contain-ment Length of Pipe - Con-tainaent to Outside Isolation Valve Type Test (1) Potential Bypass Leakage Path Number SWEC GE TYpe Oper-ator Actuator Node Pri~mar Seconda~r Normal (3) Valve(v) Position Post-Power Shutdown Accident Pailure( In) Isola-tion Signal (v) Closure Time Power Source Notes Z-59 Containment purge to vet-well 56 No Air 6 2-70 Sji. 29 Inside Outside 14 ~ 6n No(*i) 2cpsnSOV121 2CPSnSOV} 19 Globe SOV Globe SOV Elec. Elec. Closed Closed Closed Closed Closed Closed Closed Closed B,P,T, RH BIF,TI RH N/1 N/1 Div II Div I Z-601 CHS from dry-well Z-608 CHS from dry-well Z-60E CHS from dry-vel1 Z-60F CHS from dry-vell Z-60G CHS to dryvell Z-608 CHS to dryvell Z-611 Capped spare Z-618 CHS froa wet-well Z-61C CHS to vetwell Z-61D Capped spare Z-61E CHS from vet-vell Z-60C CHS to dry-well Z-60D CHS to dry-well 56 No 56 Tes 56 Bo 56 Tes 56 No 56 Tes 56 No 56 Tes 56 Tes 56 Tes 56 Tes Air 3/4 6.2-70 S}i 32 lir 3/4 6.2-70 Sh 32 Air 3/4

6. 2-70 Sh.

32 Air 3/4 6.2-70 Sh 32 Air 3/4 6.2-70 Sh 32 Air 3/4 . 6. 2-70 S}L 32 Air 3/4

6. 2-70 Sh 32 lir 3/4
6. 2-70 S}i 32 3/4 Air 3/4
6. 2-70 Sji. 32 Air 3/4
6. 2-70 S}i 32 3/4 Air 3/4 6.2-70 S}i 32 Inside Outside Inside Outside Inside Outside Inside Outside Inside Outside Inside Outside Inside Outside Inside Outside Inside Outside Inside Outside Inside Outside 1 ~

2n 1 ~-2n p ~ 3n pi 4n p ~ 7n p ~ 7n p ~ 7n 1 ~ pn 15 ~ -0n jB'3" 0 ~ 4n C C C C C C C C C C C C C C C C C C A C C NOC vi) Tes(am) No(vi) Tes( Vm) No(v() Tes(*v) No(3() Tes( mv) No(a)) No( 3() Noes)) 2CHSnSOV6 11 2CHSNSOV60A 2C HsvSOV2 4 A 2CHS*SOV24C 2CHS+SOV63A 2CHSnSOV62A 2CHSnSOV33A 2CHSnSOV321. 2CHSnSOV6 18 2CHSI'SOV60B 2CHSnSOV248 2CHSnSOV24D 2CHSnSOV638 2CHSnSOV62B 2C HSvSOV3 3 8 2CHSnSOV328 2CHSvSOV26A 2CHSc'SOV26C 2CHSnSOV341 2CHSnSOV35A 2CHSmSOV268 2CHSnSOV26D Globe Globe Glole Globe Globe Globe Globe Globe Globe Globe Globe Globe Globe Globe Globe Globe Globe Globe Globe Globe Globe Globe SOV SOV SOV SOV SOV SOV SOV SOV SOV SOV SOV SOV SOV SOV SOT SOV SOT SOV SOV SOV SOV SOV Elec. Elec Elec. Elec. N/1 N/1 N/1 N/1 Elec. Elec. 8/1 N/A Elec. Elec. Elec. Elec. N/A N/1 8/1 N/A Elec. Elec. Elec. Elec. N/1 N/1 8/1 N/1 Elec.'lec. N/1 8/1 Elec Elec. N/1 N/1 Elec. Elec. N/A N/1 Elec. '/1 Elec. N/1 Open Open Open Open I Open Open Open Open Open Opea Open Open Open Open Open Open Open Open Open Open Open Open Closed Closed Closed Closed Closed Closed closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Close d Closed Closed Closed Closed Closed Closed Closed Open Open Closed Closed Open Open Closed Closed Open Open Closed Closed Open Open Open Open Open Open Open Open Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Closed Bid RH BIF,RH BIP ~ RH B,P,RH BIFIRH BIPIRH BIPIRH 8 ~ P,RH BI PI RH 8 F RH BIPIRH BIFIRH BnPIRH BIPIRH BIPIRH BnFIRH BIPIRH BIPIRH BnPIRH BIP ~ RH 8 ~ P,RH BIF ~ RH N/1 N/1 N/1 N/1 N/1 8/1 N/1 8/1 8/1 N/1 N/1 N/1 8/1 8/1 8/1 N/1 N/1 N/1 N/1 N/1 Div II Dlv I Div I Div I Div II Div I Div I Div I Div II Div I Div II Div II Div II Div I Div II Div II Div I Div I Div I Div I Div II Div II Amendment 15 12 of 24 Noveaber 198LL

Nine Bile Point Unit 2 FSAB TABLE 6.2-56 (Cont) Pene-tration No GDC or System Feg. Designation Guide Z-67 Spare Z-61F CHS to 56 vetvell ESF ~Sstem Fluid Yes .Air Size mini 3/4 10 FSAR Arrange-ment Figare((> 6 2-70 Sh 32 Location of valve Inside/ Outside primary Contain-ment Inside Outside Length of Pipe - Con-tainment to Outside Isolation Valve 0 ~ 4ff Type Test ()) C C Potential Bypass Leakage Path No(>1) Number 2CHSsSOV34B 2CHSvSOV358 TIRE Globe Globe 0 per-ator SOV SOV Elec. Elec. N/a I N/a Actuator Bode P~rimar secon da~r Valve(v) Posztxon Post-accident Open Open Closed Closed Open Open Normal (v> Shutdovn Pover Failure Closed Closed IsoTa-tion Signal (v> BiF,RH BiFiRH Closure T ime N/a N/a Pover No~es i Div II Div II Z-68 Capped spare 10 Z-69 Spare Z-70 Capped sPare Z-71 Spare Z-72 Capped spare 3 14 Z-73 RBS relief valve dis-charge to suppression pool 56 No Water 6

6. 2-70 Sh.

33 Outside 48'6" h No(mv) 2RBSeRV108 E12-F036 BV N/A N/h 2RBSeRV20C E12-F025C N/h N/a N/a N/a None N/a N/a Z-74 Capped spare Z-75 Capped spare 3 Tl APggT~ Ching Z-76 Capped spare Z-77 Capped spare Z-78 Capped spare Z-79 Capped spare 1 1/2'. 1 1/2 1 1/2 Z-BO Z-81 spent fuel 56 pool cooling No Rater 1 1/2 1 1/2 6 2-70 Sh 40 Outside Inside C C No(31) 2SFCvV203 2SFCvV204 Globe Hanual

Hanual, N/h Globe Hanual Hanual N/a Closed Closed Closed Closed Closed Closed N/a N/A I-C N/a N/a LC N/a N/a Z-82 Capped spare amendment 15 13 of 24 Hoveaber 1984 Ai~iiOiS(

Nine Nile Point Onit 2 PSAR TABLE 6.2-56 (Cont) Pene-tration No. Systea Desiunation GDC or Reg. ESP Guide Svstem Fluid Size finl P SAR Arrange-mentt ~Pi ure(() Location of valve Inside/ Outside Primary Contain-ment Length of Pipe - Con-tainment to Outside Isolation Valve Type Test (() Potential Bypass Leakage Path Numb SMEC er TIRe Oper-ator Actuator Node Normal ( ')l Valve(v) Position Post-Shutdovn Accident Pover Pailure((e) Is ol a-tion Signal (a) Closure Pover Time Source Notes Z-83 Z-85 Z-86 Z-87 Z-BBA Capped spare Capped spare Capped spare C ap pe d spare RRS safety valve discharge to suppression pool 56 Yes Steam 12 6 2-70 Sh 34 Outside 116 ~ 2v No(av) See Note 23 TI ~mamgg CAR@ I-88B RNP safety valve discharge to suppression pool 56 Ies Steaa 12 6.2-70 Outside 106 '3" 1 No(av) Sh 34 See Note 24 'Z-891 LNS from dry-well Z-89B Capped spare 56 Ho lir 3/4 3/4 6.2-70 Sh 35 Inside Outside 0 ~ C C No(a) ) 2LHSvSOV)52 2LNSeSOV153 Globe SOV

Elec, N/1 Globe SOV Elec.

N/1 Closed Closed Closed Closed Closed Closed Closed Closed BvyeRH B,PERH N/1 Div II N/1 Div I Z-89C LNS from wet-well 56 No Air 3/4 6.2-70 Sh. 35 Inside Outside 0 ~ 2e C C No(a() 2L NseSOV 156 2LNSeSOV157 Globe SOV Elec. N/1 Globe SOV Elec N/1 Closed Closed Closed Closed Closed Closel Closed Closed B, Pe RN N/1 BepeMN N/1 Div II Div I Z-89D Capped spare 3/4 Z-90 Z-911 Z-91B ICS vacuum breaker Instrument air to drywell 56 Instrument air 56 to dryvell Ies lir No Na No 1 1/2 1 1/2 1 1/2 6.2-70 Sh 36 6 2-70 Sh. 37

6. 2-70 sh 37 Outside Outside Outside Inside Outside Inside 23-)o 29'- Ha 1 ~

Oe 1'Ov C C C C C C No(av) Ies(au) Ies(aa) 2IC S vNOV 148 2ICSeNOV 164 2IASvSOV167 2IASeSOV185 2IASvSOV 168 2IASeSOV180 E51-F086 E51-POBO Globe Globe Globe Globe Globe Globe HOV Elec. Hanual NOV Elec'anual SOV Elec N/1 SOV Elec N/1 SOV Elec. N/1 SOV Elec N/1 Open Open 0 pea Open Open Open Closed Closed Open Open Open Open Open Open Closed Closed Closed Closed PAI ', PAI Closed Closed Closed Closed F)eLeH RN Frwx Hs RN Be P~ RN B ~ P,RN B,P~RH B, PePH 9 9 Div II Div I 35 Div I Div II Div I Div II Z-91C Z-91D Capped spare Capped spare 1 1/2 1 1/2 Amendment 15 14 of 24 November 1984

Nine Nile Point Unit 2 FSliR TliBLE 6.2-56 (Cont) Pene-tration No System Desianation GDC or veg ESF Guide ~S stem Fluid Size gin) PSAR Arrange-ment Pi<iure<<A

Location, of valve Inside/

Outside Primary Contain-ment Length of Pipe - Con-tainment to Outside Isolation Valve Type Test Ci> Potential Bypass Leakage Path Number SW~C GE 0 per-ator Actuator Node Fr~lear Secondary valve<9> Posrti.on Post-Accident Noraal Shutdoyn Pover Pailure Isola-tion Signal <9 ) Closure Pover Tiae Source Notes I Z-92 Z-96 Z-98A Spare Spare RHR relief valve discharge to suppression pool 56 Yes Water 3

6. 2-70 Sh 38 Outside 2P7

~ 69 Noc 291 2CSL9RV123 2CSL9RV105 2RHS9PV611 2RHS9RV 110 2RHS9RV139 2RHS9RV20k E21 "F031 E21-F018 E12-F0881 E12-F005 E12-P030 E12-F0251 Relief N/1 H/li Valves H/1 H/1 N/1 None H/1 H/1 Z-98B BilR relief valve discharge to suppression pool 56 Yes Water 3 6.2-70 Sii 38 Outside 89'-8" No<<9> 2CSHeRV114 2CSH9RV113 2PHS9RV618 2PHS9VV61C 2RHS9HV208 E22-F035 E22-F014 E12-FOBBB E12-FOSBC E12-F0258 Relzef N/1 H/1 Valves N/1 N/1 H/1 H/1 Hone N/1 H/1 Z-991 Hydraulic unit 56 from recirc flov control valve HYV 171 (drain line) Hy-3/4 draulic 6.2-70 Sii. 39 Outside Inside 0 ~ pe N/1 'Ho< vi 9 2RCS9SOV681 2RCSvSOV821 Globe Globe SOV Elec. SOV Elec H/ii N/1 Open Open Closed Closed Closed Closed Closed Closed B,P ~ R H N/1 BrFeRH N/1 Div I 26 Div II Z-99B Hydraulic unit to recirc flov. control valve HYV 171 (open line) 56 No Hy-1 draulic 6 2-70 Sh. 39 outside Inside pi pa H/1 No<a<A 2RCS9SOV671 2RCS9SO V811 Globe Globe SOY SOV Elec Elec. H/1 H/1 Open Open Closed Closed Closed Closed Closed Closed B,PiR 8 H/1 B my 9 R H N/1 Div I 26 Div II Z-99C 'g Hydraulic unit to recirc flov control valve HYV 17A (pilot line) 56 Hy-1 draulic

6. 2-70 SII 39 Outside Inside pi pn N/1 NoC mv A 2RCS9SOV661 2RCS9SOVSOA Globe Globe SOV Elec SOV Elec Open Open Closed Closed Closed Closed Closed Closed BgF~RH H/1 BgF~Rll H/1 Div I 26 Div II

~<Remit 15 l5 of 24 November l984

Nine Nile Point Unit 2 PSAB TABLE 6. 2-56 (Cont) Z-99D Hydraulic unit to recirc flov control valve RYV 171 (closed line) Pene-tration System 56 No Hy 1 draulic GDC or Reg ESF Size Guide ~Sstem Plaid gin) PSAR hrrange-ment ~Pt. areC) ) 6 2-70 S}L 39 Location of valve Inside/ Outside Primary Contain-ment Outside Inside Length of Pipe Con-tainment to outside Isolation Valve P ~ P>> Potential Type BYpass Test Leakage CL) Path N/1 NOCs)) Number SREC GE 2RCSvSOV651 2mcs<<sov 7'9A Globe Globe 0 per-ator SOV SOV Actuator Node L PrimarI secondary Elec. Elec. Valve C>> ) Open Open Closed Closed Closed Closed Position Normal Post-c)) Shatdown Accident Closed Closed B ~ F ~ 85 BE F>>RH Isola-tion Pover Signal Pailure Clos ure Time Cv>>) 8/1 N/1 Power Soarce Div I 26 Div II I 2-1001 Hydraulic unit from recirc flov control valve HYV 17B (drain line) 56 No HY-3/4 draalic 6 2-70 Sh 39 Outside Inside P ~ P>> 5/1 'NL)C s c) 2RCSmSOV68B 2 ZCS + SO LI SZLS Globe Globe SOV SOV Elec. Elec. Open Open Closed Closed Closed Closed Closed Closed B>>P>>RH 8/1 B IP ~ RH N/1 Div I 26 Div II I 2-100B Hydraulic unit to recirc flow control valve HYV 17B (open line) 56 Hy-1 draulic 6 2-70 Sh 39 Outside Inside P ~ P>> 8/A NoCvc) 2RCS>>SOV67B Z Zc s <<)oLI SL8 Globe Globe SOV SOV Elec. Elec. N/1 8/1 Open Open Closed Closed Closed Closed B F,RH 5/1 Div I 26 Closed Closed B,P,RH 5/1 Div II ) 2-100C Rydraulic unit to recirc flov control valve HYV 178 (pilot) line) 56 No Hy-1

6. 2-70 Outside Q ~

Q II N/1 Noes)) 2BCSmSOV66B Globe SOV Elec ~ draulic S}L 39 Inside 2Lccs <<sovzcsB, Globe SOV Elec. Open Open Closed Closed Closed Closed BPIRH 5/1 Div I 26 Closed Closed B>>F>>RH 8/1 Div II .I 2-1000 Hydranlic unit . to recirc flov control valve HYV 178 (closed 'ine) 56 Hy-1 draulic 6 2-70 Sh 39 oatside Inside Q ~ P>> N/1 NoCv)) 2RCS>>SOV6 5B 2ZCS <<Sov 79LS Globe Globe SOV SOV Elec. Elec. 8/1 N/1 Open Closed Closed Closed B,P,RH 8/1 Div I 26 Open Closed Closed Closed BOP>>R5 5/1 Div II All instrument lines from reactor vessel 8 G 1 11 No Air/ 3/4 Rater 6 2-70 Sh 41 Outside (1 Q ~ Q>> NoCxx) EP check valves EPV Auto N/1 Open Open Open Open E xc ass 5/1 5/1 27 flow All instrument lines penetra-ting primary containment R G

1. 11 1ir/

3/4 Rater 6 2-70 Sh 41 Outside (10 ~-0>> 1 NoCv)) EFV 8/1 Auto Open Open Open TI ~ERTUgg CAgg Open Excess 5/1 8/1 27 flow Amendment 15 16 of 24 November 1984}}

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