Rev 2 to Electrical Separation Practices.

ML17277A561
Person / Time
Site:	Columbia
Issue date:	03/21/1983
From:	Brastad G, Malland J WASHINGTON PUBLIC POWER SUPPLY SYSTEM
To:
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ML17277A560	List: ML17277A559 ML17277A561
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NUDOCS 8304260305
Download: ML17277A561 (82)
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ENG INEERING CRITERIA DOCUf'1ENT APPENDIX 3 WNP-2 ELECTRICAL SEPARATION PRACTICES THIS DOCUMENT FORMS A PART OF THE WNP-2 ENGINEERING CRITERIA DOCUf'lENT BUT IS CONTROLLED IN ACCORDANCE WITH ITS OWN COiVTROLLED DISTRIBUTION LIST, REV. NO, DATE PREPARED BY; REVIEWED BY: APPROVED BY:

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WNP-2 ELECTRICAL SEPARATION PRACTICES

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I. Purpose XI. Electrical Separation Criteria A. Definitions BE Class .1E Redundant Circuit Design Requirements

1. Spatial Separation Between Raceways

2. Spatial Separation Within Enclosures and Equipment 10

3. Separation for Fail-Safe Systems 10

4. Separation Within Divisions 12

5. Raceway, Cable, Equipment, and Enclosures 12 Identification

6. Transient Data Acquisition System (TDAS) 14

7. General Plant/PGCC Interface 14

8. Isolation Devices 14 C. Associated Circuit Design Requirements 15

1. Prime Circuits 15

2. Proximity Circuits 16 3~ Prime and Proximity Circuit Identification 17 D. Non-Class 1E Circuit Design Requirements 18 III ~ Cri teri a Implementation 20 A. Class 1E Circuits 20 B. Prime Circuits 21 C. Non-Class 1E Circuits D. Non-Class 1E, Non-Divisional Circuits 22 E. General Plant/PGCC Interface 22 IV. Ref erences 22 V. .Tables and Figures 23 Appendix 'A - Field Verification A-1/

A-13

I. Purpose The purpose of this document is to clarify the WNP-2 electrical separation cri-teria, describe practices used to implement the criteria, and to provide suf-ficient information in a manner to simplify verification of implementation in the field. There are no differences in the design criteria between this docu-ment and the WNP-2 FSAR.

This document should be used by engineers, designers, contractors, QA/QC per-sonnel and operations personnel.

II. Electrical Separation Criteria A. Definitions Class 1E Class lE is the safety classification of the electrical circuits, components, equipment and systems that are essential to emergency reactor shutdown, containment isolation, reactor core cooling, and containment and reactor heat removal, or otherwise prevent signifi-cant release of radioactive material to the environment.

20 Power Cizcuits Power circuits provide electrical energy for component motive power and heating requiring 14.4 kV, 6.9 kV, 4.16 kV, 480 volts, 240 volts, 120/208 V AC, 250 and 125 V DC (see Table I for details) ~

3 ~ Control Circuits Control circuits use 120 V AC (or below) or 125 V DC (or below), and are designed to supply control power for plant systems. The largest control circuit protective device (fuse/breaker) has .a 35 amp rating.

The majority of the control circuits are intermittent in operation'.

Control circuits include the following functions (see Table I for details):

. a. 125 V DC or 120 V AC control to switchgear, control zoom and local panels, and logic interlock circuits.

b. 125 V DC or 120 V AC control power to solenoids.

c. Annunciator/computer digital circuits'.

Space heaters including motor heaters.

Three exceptions to the 35 amp maximum rating exist; two 100 amp circuit breakers and a 60 amp breaker for circuits in the Reactor Protection System and the Reactor Manual Control System. Within the General Plant Areas these circuits are routed separately in rigid conduit. Within PGCC these circuits are routed separately 'n flexible conduits with an attached ground conductor.

4. Instrumentation Circuits Instrumentation circuits are low level analog or digital signals.

5. Low Energy Circuits Low energy circuits are control and instrumentation circuits'.

Isolation Device An isolation device prevents an electrical event in one section of a circuit from causing unacceptable consequences in other sections of the circuit or other circuits.

7. Raceway For the purposes of this document, raceways shall include open or.

enclosed cable trays, flexible and rigid conduit (not EMT) and PGCC modular flooi dupts. Device/component nipples and conduits up to the first tee are not included in this definition but shall be considered as part of the device/component.

8. Associated Circuits Associated circuits are defined as either prime or proximity circuits as follows:

a. Prime Circuits A NonMlass 1E circuit which receives power from a Class 1E source The circuit begins at the load side of the source circuit protective device (isolation device), through the interconnecting .

cables, and up to the final connected load. The portion of a prime circuit which is routed in a Class 1E raceway is addi-tionally termed "Associated By Proximity".

b. Proximity Circuits A proximity circuit is a NonWlass lE circuit which is routed (along any portion of its length) in a raceway with a Class lE circuit or is contained in an enclosure with Class lE circuits and .

physically routed less than 6" from a Class 1E circuit (without barrier) The portion of the proximity circuit which

~ an'ppropriate is routed in a Class 1E raceway is termed "Associated By Proximity". Ef the circuit leaves the Class 1E raceway, the cir-cuit is termed and treated as Non&lass lE unless the circuit is also prime (see Figure 4).

9. Redundant For the purposes of this document redundant, shall refer to the collec-tion of Class 1E circuits, components, equipment, etc. (system(s ) )

performing a specific plant safety function which is a backup to other Class 1E system(s) independently performing the same safety function.

Safety functions, are Emergency Reactor Shutdown, Containment Isolation, Reactor Core Cooling, Containment, and Reactor Heat Removal, and Offsite Radioactive Release prevention. For example, the Low Pressure Core Spray System is redundant to the Residual"Heat Removal System (Low Pressure Coolant injection mode) Loop C for the "Reactor Core Cooling" safety function.

10.'ntruding Circuits Intruding circuits are of two types: 1) Class 1E or prime circuits which enter equipment or an enclosure or an area (either sub-enclosures or as defined by lines of demarcation) of an enclosure assigned to a redundant Class 1E or prime division, 2) Redundant prime circuits which enter common equipment or enclosures assigned to a NonMlass 1E divisions one of these becomes intruding. For example, Division A prime and Division B prime circuits within a Division A panel requires the Division B prime circuit be treated as an intruder.

11 'arrier A barrier is material or a structure placed between redundant Class lE or prime equipment or circuits to limit damage to Class 1E cir-cuits from internally generated fires. Within enclosures and equip-ment barriers are Haveg Siltemp tape or sleeving, conduits (flexible or rigid) and sheet metal enclosures or metal plates. Outside enclo-sures and equipment barriers are solid steel tray covers and bottoms, sheet metal panels, Thermolag insulation, and conduits (flexible in miniducts, PGCC periphery, or where flexibility is necessary, or rigid).

12. Power Generation Control Complex (PGCC)

The PGCC located in the Main Control Room is defined for the purposes of this document as a modular assembly of termination cabinets inter-connected'y floor sections comprised of multiple, separate cable ducts on which are mounted control room panels. ThePGCC forms an interface between the incoming plant cables and control zoom panels.

13. Periphery of PGCC The periphery of the PGCC is defined as the subfloor area between the termination cabinets and the Main Control Room wall.

14. Direct Bridging Direct bridging is defined as a circuit which routes between redun-dant Class 1E raceways (see Figure lA). Direct bridging is prohi-bited'5.

Secondary Bridging By Proximity Secondaz'y bridging by proximity is defined as:

a. Bridging of redundant, Class 1E circuits by two (or more) NonMlass 1E (Division A, B, XXX1, XXX2, or XXX3) proximity circuits, routed together in a common enclosure or raceway, and each having part of their routing in a redundant Class 1E raceway (See Figure 1B).

b. Bridging of redundant Class 1E circuits by Non-Class 1E (Division A, B, XXX1, XXX2, or XXX3) proximity circuits within enclosures oz equipment. These proximity circuits may also be extensions of circuits originating from Class 1E raceways (See Figure 1C) ~

,16. Fail>>Safe Systems 2 4 Systems used to shutdown (SCRAM) the reactor are designed to fail-safe upon loss of power(de-energize-to~perate) ~ These systems are the Reactor Protection System (RPS) and those portions of the Neutron Honitoring System (NHS) i.e., Source Range Monitoring (SRH), Inter-mediate Range Monitoring (ZRM), Average Power Range Monitoring (APRM) f, and Local Power Range Monitoring (LPRM) providing input to the RPS.

In addition, system inputs and logic'associated with the containment isolation function are designed to be fail-safe.

17. Equipment and Enclosures For the purposes of this document equipment and enclosures are defined as panels, racks including open faced instrument racks, ter- 2 minal boxes, etc. Individual device/component housings which include the conduit nipple up'to the first tee are not included in this definition-

18. Residing/Compatible Division Wiring Wiring of the same division as that designated for the equipment/enclosure (residing) or is acceptable to be routed with equipment or enclosure residing wires (compatible) ~ All other wiring is intruding.

f B. Class 1E Redundant Circuit Design Requirements Each Class 1E component and interconnecting cabling shall be assigned to one of seven Class lE divisions as noted in Table 'IZ. Class lE components of one division are separated from Class 1E components of other redundant divisions. .Minimum separation distances for trays, conduits, cables, and 2 cables/wires within enclosures are described below. Note that the separa-tion distances specified are to preclude internally generated fire propa-gation between redundant Class 1E divisions and do not consider effects of

'externally generated fires or pipe'reaks and missiles.

1 ~ Spatial Separation Between Raceways a) General Plant Areas (Outside PGCC)

'Distances shown consider the ideal arrangement of two (2) raceways only. If more than two (2) raceways exist in any par-ticular arrangement, physical separation distances chosen must be based on'he complete configuration. Additionally, minimum

'istances are shown assuming that there are .no equipment or materials in that distance that can aid in the propagation of fire.

(1) Minimum horizontal separation requirement between any two redundant Class 1E divisions is 3 feet. This is also appli-cable if one raceway is enclosed and the enclosed raceway is not lower than the open raceway.

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OPEN TRAY

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(2} Minimum vertical seeparation requirements between any two redundant Class 1E divisions are shown belo~.

B arrier or solid DIV I I bottom ~ I 8'IV

~DXV 7 zzzzzz.m M OPEN OR ENCZDSED iz; TRAY OR S DIV Xf CONDUIT CONDUCT (TYP ICAL)

THREE OR NORE ~DIV ZI DIV XZ PER TIER AND 'WO QR LESS NO AUIMATIC FXRE DETECTION ~DIV IX DIV IX fc EXTINGUISHING AVAILABLE DIV IX (3)

! ) Where minimum separation re qu irem rements n between two raceways of redundant n an Cl ass 1E divisions are not met, one of the followinq methods shall be implemented.

(a) Horizontal Separation

1. Open/Enclosed Race~aye Installed Parallel h h DZY

~DIV II DIV I

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2. Enclosed Raceways Installed Parallel DZV I( DIV II a I I

I I I I I Tray Covers or Barriers

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DIV I I B ~ 12" Minimum or Flush to Ceiling C ~ 12" Minimum or Flush to Floor D ~ 1" Minimum Note 1 - No minimum separation distance is required be-tween redundant division conduits or enclosed trays but they must not, physically touch.

(b) Vertical Separation

1. Open/Enclosed Raceways Installed Parallel

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2. Enclosed Raceways Installed Para11e1 DIV II DIV, II 0 A = 12" Minimum or Flush to Wall.

Note 1 - No minimum separation distance is required bet-ween redundant division conduits or enclosed trays but they must not physically touch.,

(4) Tray covers shall be used for all crossovers of redun-dant division raceway systems (where minimum vertical separation distance i's not met), except when the bottom raceway is a conduit. The schemes shown below shall be used regardless of the voltage level of the cables in a.

crossover raceway system.

3W W 3W

~DZV I DIU I 1" Min DIV,II DIV II "W" is defined as the nominal tray width of the widest tray involved.

3W ~ 3 times the nominal tray SECTION A-A width or flush to a wall

12n 1 2N DZV I DIV I 1" t4in DZV ZI B ~oiV ~rr SFCTION 8-R DIV I DIV I 1" Min DIV IZ DIV ZI 12" 12" SECTION CM (5) Open raceways assigned to route Non-Class 1E power cables (Division A or B) shall be separated from all Class lE raceways using the separation criteria spe-cified in a) ~ (1) through (4) above.

b) Unique Requirements For Certain General Plant Areas

1) Cable Spreading Room and Cable Chases The minimum separation distance between open trays of xedun-dant Class 1E divisions shall be one foot horizontally and three feet vertically. The minimum separation distance bet-ween conduits and open trays of redundant Class 1E divisions's one-inch with a barrier provided when the conduit is below or to the side of the open tray and three feet when the conduit is located above the open raceways. Where these distances cannot be maintained, fire barriers shall be installed. Automatic fire detection and suppression must be provided or these ax'eas become General Plant Areas.

2) Periphery of PGCC A modular floor raceway system is not provided in this area.

Cables in this floor area shall be routed in grounded flexible conduit with 3 feet; horizontal separation main-tained between redundant Class 1E flexible conduits. Where this distance cannot be maintained, one of the redundant divisions shall be routed in rigid conduit. The redundant conduits shall not touch (a barrier may be used to physi-cally separate the two conduits ).

3) Class 1E Underground Duct System Class 1E equipment located remotely from the plant (e.g.,

equipment located at the ultimate heat sink) is serviced by divi-sionally separated Class lE underground duct systems and manholes. The underground duct system for Class 1E systems is constructed of steel encased in reinfoxced concrete. The minimum hoxizontal separation between 9

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3) Class 1E:Underground Duct, System (Cont'd) redundant duct banks measured from the bank edges is 18 inches. Redundant duct banks do not crossover. Separation within manholes is provided by barriers.

c) Power Generation Control Complex (PGCC)

Separation is provided by the design of the modular floor in the PGCC. The modular floor is latticed and constructed of steel "I" beams and rectangular steel tubes forming longitudinal and lateral raceways. These raceways interconnect the control panels (which are bolted on the modular floor) and the termination cabi-nets. The network, including transition and extension raceways, 2 provides separation using vertical and/or horizontal barriers and ~

fire stops. Hiniducts (raceways within raceways ) are of similar construction to the floor raceways and provide separation within the longitudinal raceways. Cables in the miniducts are routed in flexible metallic conduit or wrapped with Siltemp tape.

When it is necessary to route cables between PGCC sections which are not directly connected by floor raceways it is permissible to route these cables through the cable spreading room. That por-tion of PGCC cables routed in raceways within the Cable Spreading Room shall be at least identified the same as General Plant Area cables with the interface occuring at the control room floor penetrations.

2. Spatial Separation Within Enclosures and Equipment Where devices of redundant Class 1E systems are mounted in or on the same enclosure or equipment, physical separation (six inches ),

barriers, or isolation devices shall be provided for the intruding devices and wiring. When it is necessary for a single device such as a relay to be connected to wiring from redundant Class 1E divisions, 2

the intruding division wiring shall be routed immediately away from the device to attain the required six-inch separation or to the extent where a barrier can be installed. Within open faced instru-ment- racks all wiring between terminal boxes and the instrumentation shall be routed in flexible metallic conduits.

3. Separation for Fail-Safe Systems Outside of equipment and enclosures,, circuits belonging to fail-safe systems or portions of systems designed to be fail-safe shall meet the following requirements ~

a) The fail-safe divisions do not provide redundant safety functions to Ne non-fail-safe divisions except as noted in 3) below.

Therefore, in general, no separation is required between the non-fail-safe divisions (Div 1, 2, 3) and the fail-safe divisions (Div 4, 5, 6, 7) ~ The following specific criteria applies to fail-safe circuits:

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1) External to PGCC fail-safe circuits shall be routed in grounded conduit (rigid or flex) or totally enclosed raceways carrying only fail-safe cables/wires; the grounded raceways are provided only to preserve the fail-safe nature of these circuits')

Within PGCC fail-'safe circuits shall be routed in grounded flexible metallic conduit carrying only fail-safe circuits and shall be, assigned to raceways as described below

3) Since the Nuclear Steam Supply Shutoff System logic out-puts control Divisions 1 and 2 valves and PGCC contains no Division 4, 5, 6, or 7 raceways it is necessary to route the fail-safe cables with non-fail-safe cables.

Hense, Divisions 4 a 6 cables are assigned compatibility with Division 1, and Divisions 5 6 7 with Division 2.

These Divisions are compatible in General Plant Areas as well as in PGCC.

Considering the above, Division raceways/cables/wires require 1

no separation from Divisions 4 or 6 raceways/cables/wires; Division 2 raceways/cables/wires require no separation from Divisions 5 or 7 raceways/cables/wires. Divisions 4 and 6 shall be separated from Division'2 and Divisions 5 and 7 shall be separated from Division 1. Divisions 4, 5, 6, or 7 need not be separated from Division 3 except to preclude direct bridging bet-ween redundant Class 1E raceways.

b) RPS SCRAM Solenoid Cabling Wires from both RPS trip system trip actuators to a single group of SCRAM solenoids are permitted to route in a single conduit. A single conduit shall not contain wires to more than one group of SCRAM solenoids Wiring for the A and B solenoids for the same control rod can run in the same conduit. See Figure 2.

c) NMS and Main Steam Line Cabling Cables routed through the containment penetrations are grouped so that failure of all cabling in a single penetration cannot pre-vent a SCRAM. This applies specifically to the NHS and main steam line inboard isolation valve position switch cables. See Figures 2 and 3.

d) RPS Power Supplies Power supplies to systems which de-energize to operate require only that separation which is deemed prudent, to ensure reliable operation. Therefore, the RPS motor generator sets output cabling are not required to comply with Class 1E separation requirements.

e) Four Division Separation Wiring for the four RPS SCRAM group outputs and the NMS LPRH inputs shall be routed as four separate divisions See Table XV and XVI 'and Figure 2.

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f) The NMS ling in the area immediately un neath the reactor need not be completely routed in enclosed raceways nor separated in accordance with Section ZI.B.la due to space limitations and the need for cable flexibility.

g) Class 1E logic inputs to the RPS and Containment Isolation System from main steam turbine process and status sensing instrumen-tation (Load Rejection or, Turbine Trip), Turbine Generator Building leak detection and Main Steam Tunnel high radiation instrumentation, their associated instrument racks, cabling and raceways are located in the Turbine Generator. Building. This equipment, even though located in a non-seismic Category I struc-ture, shall be mounted to seismic Category I requirements and all related cabling routed to Class 1E requirements'.

Separation Within Divisions ln order to preserve functional integrity and to meet single failure criteria the MSLCS, the SGTS, and the RRCS contain certain system portions (RRC and MSLCS isolation valves/controls and.the SGTS discharge dampers/controls) that require separation within a single division. In these instances separation shall be maintained between the redundant portions as though the portions were in redundant divi-sions or an analysis shall be performed to show that lesser separa-tion is acceptable.

5. Raceway, Cable, Equipment, and Enclosure Identif ication V

a) Class 1E cables routed within conduits need not be identified within the conduit.

b) Cla'ss lE General Plant. raceways shall be uniquely identified with a color coded marker every 15 feet, at the beginning, end, at pull boxes, and discontinuities (walls, structures, etc.) as shown in Table ZZI.

c) Class 1E cables routed in Division 1 through 7 raceways in General Plant Areas shall be uniquely identified with a color coded marker every 15 feet and at their terminations as shown in Table IIZ except as noted in ZZ ~ B.1.C. These markers shall be provided on the cables up to the first termination within equip-ment and enclosures.

d) Class 1E cables routed in PGCC raceways shall be uniquely iden-tified with a color coded marker every 5 feet near the cable divisional marker as shown in Table V. These markers are pro-vided on the cables up to the first termination within equipment and enclosures. PGCC longitudinal raceways shall be identified with a color coded marker at approximately 5 foot intervals as shown on Dwg. E775. Each lateral raceway shall be identified at the longitudinal raceway lip centered above the lateral raceway.

e) Conduits in the periphery of the PGCC floor area are identified by metal tags which identify the cable number and division.

Since these tags are not color coded, an additional color-coded marker shall be attached near the metal tag to identify the con-duit divisional assignment.

f) Within enclosures and equipment Class lE intruder circuits shall be uniquely identified with a color coded marker at 12 + 2 inch intervals as shown in Table VZI.

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g) Circuits that have been upgraded from NonClass 1E to Class 1E and are already installed in raceways shall be identified with a Class 1E color coded marker at terminations, pull boxes, and entrances and exits to raceways. Upgraded cables shall be routed in Class 1E raceways. Cable installation records shall be reviewed to provide assurance that these cables are routed in Class 1E raceways and installed to Class 1E requirements (cable installation parameters). Otherwise, megger and continuity tests shall be performed, termination and routing reinspected to Class 1E requirements, and documentation prepared verifying the upgrade.

h) To differentiate between cables and wires where tracing cables inside- equipment and enclosures is difficult, color coded wire markers are utilized as shown in Table VI.

i) Equipment and enclosures shall be uniquely identified with two color coded markersr one marker with the identification number and a second with the assigned separation division of the residing components, cables, and wires. These markers shall be ~

color coded as shown in Tables III, IV and V- Individual com-ponents located on or in equipment and enclosures require iden-tification markers only and are not necessarily color coded, but need not have individual divisional separation markers. For example, an instrument rack shall be uniquely identified with a color coded identification marker and a divisional separation marker. However, each separate instrument need not have a color coded identification marker or a divisional separation marker."

Open faced racks which contain components from more than one division shall be provided with appropriate divisional separation marker on each division terminal box The identification number marker for multidivisional equipment and enclosures shall be black lettering with a white background.

Single equipment and enclosures containing cables, wires, and/or devices of redundant divisions shall be provided with color coded divisional separation markers utilizing at least one of the following methods:

1. Equipment or enclosures containing intruding wires/cables/

devices may be identified by a residing division separation marker and all intruders identified and separated as such.

2. Equipment and enclosures containing an area(s ) or bay(s )

dedicated to intruding wires/cables/devices with 6" separa-tion (or barrier) from residing/compatible wires/cables/

devices may be identified with the residing division separa-tion marker. The intruder area, which may be enclosed par-tially or entirely by metal barriers, may be identified by an intruding division separation marker placed either within lines Of demarcation or on the separation barrier. Intruding wires/cables/devices within these areas need not be iden-tified as intruders.

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p j), Within open faced instrument racks wiring from terminal boxes to individual instruments is routed in flexible conduits. These conduits need not be identified with a cable identification number or with a divisional separation marker.

k) Two different equipment, enclosure, and cable identification schemes exist within PGCC; one for those provided within the General Electric NSSS scope and the other for those provided within the Balance of Plant scope Refer to Tables V, XZZZ, XZV, XV for details of these schemes. Those BOP PGCC cables that route directly between BOP and NSSS panels shall be identified using the NSSS designation scheme but, with BOP system designations 6 Transient Data Acquisition System (TDAS )

The TDAS is a Non-Class 1E, computer based, data collection and reduction system which receives the majority of its inputs from Class 1E systems. The system shall be designed as, follows:

a. All TDAS input. circuits within raceways shall be identifie'd and routed to Class 1E requirements up to a remote isolation device.

From the isolation device to the remote multiplexer the circuits are considered to be Non-Class 1E.

b. Remote multiplexer outputs are transmitted to the computer via a fiber optic cable which is inherently an isolation device. The fiber optic cable, therefore, can be routed in any raceway without regard to separation criteria.

c. TDAS Class 1E input isolators are supplied from Non-Class 1E 24VDC current limiting power supplies. The power source to these power supplies is Class 1E and provided with a Class 1E current interrupting device. The circuit to the power supply shall be routed as prime for Division and 2 isolators and as Class 1E 1

for the Division 3 isolators The power supply at the isolator is internally isolated from the Class 1E signal input circuit."

Downstream of the power supply, the circuits shall be treated as Non-Class 1E.,

7. General Plant/PGCC Interface For the purposes of cable identification General Plant, Area cabling entering the PGCC interfaces with PGCC cabling at termination modules within the termination cabinets. This cabling shall be designed to the divisional compatibilities and designations as shown in Tables XIII and XIV.

8. Isolation Devices Where circuit isolation devices are required, consideration shall be given to types of devices available and the type of circuit protec-tion required.

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Isolation device types shall 'be applied as follows:

a) Class 1E power circuits shall be isolated from Non-Class 1E circuit faults by devices which provide adequate circuit interrupting capability. Class 1E circuit breakers tripped by an 2 accident signal are preferable; all circuits downstream of except the accident tripping portion of the trip circuit the'reaker, itself, shall be considered Non-Class 1E. However, where NonClass 1E. circuits are helpful to operations personnel following an accident, coordinated circuit breakers or fuses actuated by time overcurrent trips shall be used. Trip charac-teristics shall be such that for all faults the downstream device will interrupt current prior to trip of any upstream breaker or fuse. Various combinations of fuses and circuit breakers may be used.

In addition to current interrupting devices, current limiting devices may be used either alone or in conjunction with interrupting devices to isolate power circuits Current limiting

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shall be accomplished by using current limiting or isolation transformers.

b) Low energy Class 1E circuits shall be isolated from redundant low energy Class lE circuits by devices such as relays or isolation amplifiers. Low energy Class 1E circuits shall be isolated from non-Class 1E loads by resistors, fuses, circuit breakers, or current and potential transformers.

When it is necessary to interface between redundant Class 1E divi-sions, relay coil-tomontact isolation is acceptable. That is, the coil of the relay may be powered from one division and the relay contacts can be used for interface with a redundant division.

The contacts shall not be used in more than one redundant divi-sion circuit since this condition would be contact-to-contact separation which is not acceptable-Class 1E instrumentation circuits may be isolated from Non-Class 1E portions of the circuit by a fuse, resistor(s), or an isola-tion amplifier.

Associated Circuit Design Requirements Prime Circuits

a. Redundant prime circuits shall be physically separated with the same requirements as redundant Class 1E circuits (See Section II.B) from the load side of the source circuit protective device to the final connected load except as noted in c. below. For example, a Division A prime (A ') circuit shall be separated from 2 a Division B prime (B') circuit and a Division 2 circuit; a Division B prime (B ') circuit shall be separated from a Division A prime (A ') circuit and Division 1 circuit.

b. Class 1E power sources shall be protected from failures within prime circuits by a Class lE isolation device.

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) c. Deviations to prime circuit separation criteria implementation are as follows:,

1) Circuits downstream of Class 1E isolation devices (circuit breakers) which are tripped by an accident signal shall be "treated as Non-Class 1E and not. as prime.

2) . Emergency lighting, obstruction U.ghting, main control room normal lighting, sync circuits, SLCS, meteorlogical tower supervisory, fire protection circuits, and the, UPS Inverters (IN-1 and ZN-4) shall be provided with two series Class 1E isolation devices (circuit breakers/fuses ) Downstream of

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the second isolation device the circuit shall be treated as.

Non-Class 1E and not as prime.

3) A single circuit supplies power to the Technical Support Center (TSC) ~ This circuit shall be routed as prime to the Motor Contxol Center located in the TSC. Downstream of the MCC feeder breakers the circuits shall be treated as Non-Class 1E and not as prime.

4) Circuits supplying power to the 24VDC power sources for the Transient Data Acquisition System remote multiplexers and the General Electric scope Regulatory Guide 1 '7 displays shall be routed as prime from the Class 1E isolation device (circuit breaker) to the current limiting 120VAC/24VDC power supply. Downstream of this power supply the circuits shall be treated as NonWlass 1E and not as prime.

5) Circuits supplying power to other Regulatory Guide 1. 47 displays from the Division 1 and 2 24VDC batteries shall be treated as NonMlass lE and not as prime.

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6) The Non-class 1E TDAS inverter input power circuit from the Class 1E 480 VAC supply shall be treated as prime to the inverter. Downstream of the inverter the output circuits shall be treated as Non-Class 1E and not as prime.

2. Proximity Circuits Proximity circuits when routed in a Class 1E race~ay ("Associated by Proximity" ) shall meet the same physical separation criteria as that applied to the Class 1E circuits as follows.

a. Routing criteria for proximity circuits are as shown in Tables X, XI, and XII external to PGCC and Table XZV within PGCC Proximity circuits may also be prime circuits'efer to Section IZ.C-1 for prime circuit separation criteria.

b. Proximity circuit sections routed in NonMlass 1E raceways shall be treated as Non-Class 1E and have no specific separation cri-teria applied except as described in Sections II.B.1.a.5 and ZI.C.1 (See Figure 4) ~

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I c. Within equipment or enclosures, no specific separation criteria is applied to proximity circuits unless they are also prime cir-cui ts ~

Effective April 1, 1983 each proximity circuit routed in Class 1E raceways and not protected by a Class 1E circuit protective device (fuse, circuit breaker) shall be analyzed to demonstrate that its failure and effect on Class 1E circuits cannot result in loss of abi-lity to safely shutdown the plant. Such cables that do effect safe plant shutdown shall be assigned alternate raceway routes.

d Bridging Circuits

1) Class 1E circuits, prime circuits, and proximity circuits, as shown in Figure lA shall not bridge between redundant Class 1E raceways'esign control to alert designers of a potential for cable direct bridging is provided by Note 4 in' the computerized cable schedule (BsR Drawings E550 and E551). Refer to Table XIV, Examples 1 through 4.

2) Secondary bridging within Class 1E equipment or enclosures is allowed for low energy circuits as shown in Figure 1C.

3) Secondary bridging by proximity circuits is allowed to occur within NonMlass lE or Non-Divisional raceways as shown in Figure 1B. It is acceptable to route Divisions A, B, XXX1, XXX2, and XXX3 cables together in the same PGCC Non-Divisional raceway.

Note 4 of the computerized cable schedule is assigned to any Non-Class 1E cable with the potential to become a direct bridge.

This occurs when this cabl'e is routed in a Class 1E raceway and has a continuing section routed in a Non-Class 1E raceway. For example, Note 4 would be applied to a Division B cable routed in a Division B raceway and subsequently routed into a Division 1 2.

PGCC raceway; potentially this cable, external to PGCC, could be routed into a Division B raceway and then into a Division 2" raceway creating a direct bridge.

3. Prime and Proximity Circuit Identification a~ Prime cables routed in Divi,sion A and B raceways in General Plant Areas shall be uniquely identified with a color coded marker every 15 feet as shown in Table IV except as follows:

1) Prime cables routed in conduit need not be uniquely iden-tified with the color coded marker.

2) Enclosed and open raceways shall be identified every 15 feet, at discontinuities, at pull boxes, and at end points with the appropriate prime color coded marker except as

'oted in II C 3.f.

17

~ ~ ~

3) Cables that have been upgraded from Non-Class 1E to prime and are already physically installed in plant raceways shall not be retrofitted with the prime color coded marker except at all terminations, pull points, and entrances and exits to raceways.

b. Prime cables routed in PGCC raceways shall be uniquely identified with a color coded marker every 5 feet near the cable divisional marker as shown in Table V except as follows:

Circuits that have been upgraded from NonMlass 1E to prime and are already'physically installed in the PGCC raceways shall be identified with the prime color coded marker only at entrances and exits to PGCC raceways and at terminations within enclosures.

c. Within Class 1E enclosures and equipment intruding prime circuits shall be identified the same as Class 1E intruding circuits as in IZ.B.5.f above. I 2,

d. Within NonMlass 1E multi-divisional enclosures and equipment assigned to either Division A, B, XXX1, or XXX2, an intruding prime circuit shall be uniquely identified as in II.B.S.f above.

e. Proximity circuits shall have a unique color coded marker as described in Table ZV.

f. Raceways which contain prime and proximity cables with a Di.vision 1 through 7 compatibility shall be identified with the appropriate divisional separation marker (Division 1 through 7) l2 even if these raceways route to Non-Class 1E enclosures or equip-ment. Raceways routing prime cables and identified with Division 1 thru 7 separation markers require no prime checkered markers. Z.

Prime cables routed in these raceways shall be identified with prime checkered markers except as noted in II.C.3.a.3.

Do NON-CLASS 1 E CIRCUIT DESIGN REQUIREMENTS Non-essential circuits or portions of circuits, which are not prime or "Associated By'Proximity" are termed and treated as Non-Class 1E. Refer also to Figure 4. Electrical separation criteria shall not apply to Non-Class 1E circuits except as noted in Il.B.l.a.5 or below for utility power circuits. Non-Class 1E circuits shall be assigned to NonMlass 1E divisions as shown in Table XZV. Non-Class 1E raceways need not be physi-cally separated from each other or from any Class 1E raceways unless they contain power circuits. Deviations to standard divisional assignments are as follows:

Digital computer signals in the reactor building are routed in Class 1E divisional raceways as applicable by the device being served.

NonWlass 1E digital signals in other areas are routed in instrumen-tation raceways of Division B irrespective of the diviszon by which the device is being served.

18

) ~

~

l ~

~ I ~

2. Analog computer signals in the reactor building are routed in Class 1E divisional raceways as applicable by the device being served.

Non-Class lE analog signals in other areas are routed in instrumen-tation raceways of Division A.

Non-Class 1E Division A and B raceways, excepting conduits, do not exist within the Reactor Building or the Cable Spreading Room. This requires that most NonWlass 1E cables be routed in Class 1E raceways; these cables become "Associated by Proximity" ~ Division,A and B conduits routed within these areas are designated with separation markers as shown in Table IV.

Zf cables within these conduits have a Division or 2 "compatibility" 1

then the separation markers shall be in accordance with Class 1E require-ments (see Section IZ.B.4).

Within PGCC, raceways are designated Division 1, 2, 3, or Non-Divisional.

No Division A or B raceways exist. Thus, Division A and B cables shall be assigned to Division and 2, respectively, and/or to a Non-Divisional 1

raceway.

Within Class lE Main Control Room panels Non-Class 1E utility power cir-cuits shall be separated by 6" or a barrier from all other wiring.

Non-Class 1E circuits need not be uniquely identified inside enclosures or equipment except for wizes downstream of the first termination as shown in 2 Table VZ NonWlass 1E cables routed in open raceways shall be uniquely identified as described in Table ZV. NonClass 1E cables shall be tagged with color coded markers at their terminations, pull points, entrances and exits to raceways, and every 100 feet. Division A and B raceways are tagged every 100 feet, at discontinuities, entrances and exits to rooms, pull boxes, and end points.

Non-Class 1E cables routed in PGCC raceways shall be uniquely identified with a cable I.D. marker every 10 feet and with a color coded cable separation marker every 5 feet as shown in Table V The Non-Class lE cables which wholly route in compatible Non-Class 1E raceways (Div. A or Div. B) are routed in accordance with cable routing criteria stated in Tables X, XZ and XIZ. Division markers for equipment/raceways and cables are color coded per Table IV.

19

III. Criteria Implementation The purpose of this section is to assist the desi.gn engineer in the implemen-tation of the design criteria. The principal elements for design consideration include:

Device service requirement, Provi.ding an appropriate power supply based on device service requirements, Assigning the cables to meet device/power source compatibility, Routing of the cables in raceways to meet the separation criteria requirements, and Enclosure/equipment/raceway/cable identification.

The following details explain the steps to be followed to assure proper imple-mentation of the criteria.

A. Class 1E Circuits Class 1E systems are listed in Table ZI.

All Class 1E electrical equipment and enclosures are tagged with an iden-tification number. In addition, a di.vision identification marker is provided which indicates the assignment to one of seven divisions (Divisions 1, 2, 3, 4, 5, 6, and 7). This division marker is inscribed with color coded characters using the color scheme shown in Table ZII for all equipment external to PGCC and per Tables V, XIII, and XZV for equipment internal to PGCC including control room panels.

All devices required to VIZIER power sources of the compatible division as shown in Table Loop A is supplied from the Division 1 Class 1E power source.

II'or preserve Class lE functions are supplied from Class example, 1E RHR The assignment of a proper cable number is key to the implementation of separa-tion criteria. Each cable number is guided by Class 1E division designation, the equipment of origin, and the circuit/cable identificati.on number. The metho-dology of cable number assignment and the significance of various characters are provided in Table In addition to the unique identification number, each cable is also identified with a divisional marker as shown in Tables ZZZ, V, XIII and XIV.

Routing criter'ia for Class 1E cables in General Plant Area raceways is provided ,

in Tables X, XI and XZI. Table XIII provides the routing requirements inside the PGCC raceways. As indicated in these tables, routing of Class 1E cables in non-compatible division raceways or Non-Class lE raceways is not permitted.

Divisionalized raceways are designed to meet the criteria requirements as stated in Section ZZ.B.1. The raceway identification scheme is provided in Tables IZZ and V.

20

E II

~ I ~ I ~

Class lE equipment and enclosures are identified with an appropriate divisional marker to show the residing Class 1E division of the internal cables and wires.

Zntruder cixcuits are identified with a color coded max'ker in accordance with Table VII 'ote that Table VZZ identifies cix'cuits. as intruders which are not described as such by the literal definition of intruder (refer to ZZ.A.10) 2 i.e., for ease of design criteria implementation'ot all those circuits iden-tified as intruders are Class 1E or prime.

Class 1E cables may contain non-Class 1E circuit.conductoxs. These cables shall be identified as Class 1E.

B. Prime Circuits Prime circuits are identified on the cable schedules by a A '1 or B '2 designation in the "SPTY CLR" field. See Table ZX Column 14 for details. A '1 signifies' cable that connects a Class 1E Division 1 power source to a Non-Class 1E Division A device. Similarly B'2 signifies a cable that connects a Division 2 power source to a Division B device.

A Division 1 power source is never connected to a Division B device via a Similarly," a Division 2 power source is never connected to a Division B'able.

A device via an A'able.

All prime cables and the Non-Class 1E divisional raceways in which they route, in addition to the Non-Class 1E'identification markers, are identified with a checkered marker as described in Tables ZV and V.

A '1 and B '2 circuits are not routed in the same raceway. The separation requirements for the prime cables in enclosures. is the same as that for the Class 1E cables as shown in Table VIZ.

Within PGCC prime circuits are required to be routed in Class 1E compatible divisional raceways as shown in Table XZV.

C. 'on-Class 1E Circuits NonWlass 1E circuits such as Turbine Generator, plant service circuits, etc.

are assigned to either Division A or Division B. As described in Section ZI D, Non-Class 1E raceways for routing of Non-Class 1E cables do not exist in all plant areas. Therefore, certain Non-Class 1E cables (prefixed with A or B) are required to be routed in Class 1E raceway systems. Such cables axe treated as "Associated by Proximity" and are divisionally marked as shown in Tables IV and Vo Within PGCC, Division A, Division B, XXX1, 2 and 3 Non-Class 1E circuits axe allowed to be xouted together in a Non-Divisional xaceway. Precautions must be taken to assure that these circuits do not cause direct bridging. Refer to Table XIV for further discussion.

21

Detail 1 Transition Point TP Non-Class 1E Class 1E Raceway Non-Class lE Non-Class 1E Device Raceway End Device

-AMlSC-9001 -AMZSC-9001

- Typical Cable Tag-AMISC-9002 Typical Cable tag-AMISC-9002

- Typical Tray Compatibility C1 Typical Tray Compatibility CA Detail 1 illustrates the treatment of a proximity cable with sections routed in both Class 1E and Non-Class 1E raceways Due to the programming limitation of the computerized cable schedule, such a cable is treated in two sections. The section routed in the Class 1E raceway is assigned a type, a divisional com-patibility, and an AXXX 9000 series number in the cable schedule. This entry (see Table IX, Column (2)) is developed as shown in Table VZZZ, Item (2) ~ The cable destination is called out to be TP - an imaginary Transition Point - with a note that the cable continues to be identified with a consecutive number.

Refer to Table ZX, Column (4) for details. The portion of the cable which is routed in a NonWlass 1E raceway has type/cable compatibility noted in Column 2 of Table ZX. This section of the cable is assigned a consecutive cable number.

The 9000 series cable as described above are color coded as shown in Table IV.

Note that both consecutive cable numbers appear along the entire, length of the cable in the Class 1E as well as the Non-Class lE raceways.

Do Non-Class 1E, Non-Divisional Circuits There are certain systems such as the security system, fire protection/

lighting, communications etc. which are not assigned to a division. These cables are routed either in dedicated conduits or they are assigned a Non-Class lE divisional circuit identification and routed in appropriate raceways.

Eo General Plant/PGCC Interface The requirements of General Plant/PGCC interface are shown in Table XIII and XZV. GE NSSS circuit design is based on the general details provided in Tables XV and XVI.

IV. References WNP-2 FSAR Section 8.3 Contract 218 Specification General Electric Specification 22A7416 22

TABLE A-9

') @~ISA Y IAI5PECTIOiVCRGEPIA i

p FDR /L4$$ IE SEFI4RAT7ON(EKTERNN /V Rr~)

Q'C64844CZ CLLH8VSLERAcEm rarzcF oesr Foe SPAT/Ac snARAnoH /S JPECIF/ED BFfPYEAt/

RACEWAY o4raraezS.

mr A44ccfe CDVDUIT ACF AJAR@

/A f1~~'

[mao~ j 8 ~

)~DI gg 7A 2

DFTAF".A'4RF

[oO3 SPREADING gOON 4'CA8LE CHASE Pgf4syRg 8 P,H 9

~avAY C4lMAP/FS ~<54 C b%

/A Z

/0 0 X 'L4 IA 0 0x 1 ~

X 0 X0 0 0 P X p( X 80 ~

~

~

C 0 OO 0 0 0 ISHoreraoieED m cownr Ylin/ rffE sPAQ4L SEPICRAfic/ti co/ITAIIIEP ffEEFlit/

X .IseEDV/xFDm CDIyUvy y/in/TRFSRtNL

$69teATIDI/ co/ITIUIIED /IEREIN. RR /7ERf OF UPN ZT@YS ~RTIERSOF3+~u+ORE.TRAn TED'/ TRAY-SH'LININGS DFTAII. 8 REDQID4/ITQ~

/HIUOIIIG ZruonuYCOrarSSR4u SnZau FFiVFBfl +MNIAFBfF(Er~'gpggg A g~g) 44GSYAY offeoieesezoFIumaware4ceiIRY 5PACIA( SEPARATION BETWFZiV FIVCLL5EP MYSOR I CQV :CDNPVITS iS rvAT r/Er /FIVS7-NOTPHYSINQP'/OIICIK D / Ig>> SEPAL 7 ION REOUIR&IENTS~EON Eff cO rViAY REOViVOAN'TOIVISIONSIN'TIIEP6OC~/BATE'ONOVITS'F PFR/F=RY ISZco" SEi9f44TIONR OVIR&IFIVIS Au liA A BFryvEFN FLENIB&cdNov/T.Ako EI6/o cdNPI//TDF RI ID CDA'DIIII /2>> RFOVNOANl Ol VIS/OAF L/N'TI/EP5'CC~RIFERV /S TII4T FCEl'CWDUII JOEY CVIIDT2VVCH' AN iurzVDIN6 /7/eRIFIOIAI-6EDRAczeav sofa BE

~TEDAS A AÃCBNYWIDIEARRIERANDy/ICLIYDT REOVIRE IIIEADDII7DNFR'/7s4Y cDVERS~

rvmpEDesseewrcIITm~m'z BeuAREeeDUIYaavrloE4cffonIER w Is'~aEDAS/ffEffwaAI.Iao'yi/or@ DzlffEPIIDEsra/4y /fflo/yap,

~W 3/I+a'VZ~WQ TR4YIYIP/ffOe RIISH IOA Ilu.

SYhfBOL Y IN THE'PETA/LS A/3OVEgEOUIRESA SOVD

-&'PLANATION'PEIiVCICATEOOPENTSf TRAYcoYER(~ssHowNINI7/E~vrr~i

~AY/AIR/IDES'/NII/IS'AeEA PlPIGfC)AND y/ffavweEDUI/o4HW ISNDTWBFAfG'CA66EO.

L II

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O.

c k

?

SKETCH B Division 2 Division 2 Devfceg Division 1 Circuit Device g<<'<<

-Conduit A

k

'?';

c>>?<<,"

A OIV I AREA Conduit~ >:<<'8 (Siltemp ~?:

tape may be used,) M Division 2 Devices we s<<><<?' <<? <<? >>>',,>> <<,;><<, ">w'>>4><<><<'?>'.,>

F~

~ <<>

Bairier P,

g v?

)C Division 2 Enclosure Div. 1 Intruding NOTE: OIVISION'I CIRCUITS ARE INTRUOERS ANO IOENTIFIEO AS SUCH EXCEPT IN THE OIVISION 1 AREA.

A-12 A -'EFER TO SKETCH A

0 /

(a I

C lp

TABLE I POWER CONTROL CABLE CLASSIFICATION LOAD TYPE HOTORS METERING, SHALL SERVIC ALL EXCE MOTOR- SPACE HEATE TRANS+ FDR 'S TO PROTECTIO MOTORS VOLTAG SHALL OPERATE SOLENOI (INC. MOTOR PROCES (INC PWR SWG'R 6 LOC, 8 CONTRO (SEE (VOLTS HOTORS VALVES VALVES HEATER) HEATER AND LIGHT'Ge CONT+ PANEL CKTS ~ NOTE 1 120 VA C C 125 (up to 900W (up to 35A 6 BELO circuits) 120 VA P&C NA 125 6 BELO ABOVE NA NA 120 VA 125 NOTES:

1 INCLUDED ARE: ELECTRO HYDRAULIC OPERATORS (EHO 'S ), HVAC DAMPERS, NMS STARTUP RANGE DETECTOR DRIVE MOTOR, HOTORS UP TO 1/3 HP LEGEND:

P POWER C CONTROL NA NOT APPLICABLE 23

TABLE II ASSIGNMENT OF SYSTEMS TO DIVISIONS OF SEPARATION Division I Division 2 Division 3 RHR A LPCS RHR C HPCS Standby Emergency Power Conta I nment Conta I nment Outboard I solat Ion Inboard I so I at Ion 125 VDC Va Ives Va Ives HPCS Battery Standby Emergency Standby Emergency HPCS Service Water Power I Power 2 HPCS Safety&elated RCIC Display Instr.

Automatic Depressurl za- AutomatIc Oepressur I za-tlon Olv. I controls tlon Olv, 2 controls Standby Gas Treatment I Standby Gas Treatment 2 250 volt DC Battery 125 volt OC Battery I 125 volt OC,Battery 2 24 volt DC Battery I 24 volt OC Battery 2 Standby Service Water Standby Service Water Pump A Pump 8 MSIV-LCS (Inboard) MSIV-LCS (Outboard)

Leak Det System I Leak Oet, System 2 CAC I CAC 2 Cont, Inst, Air I Cont Inst. Air 2 SLCS I Mn, Cont, Rm, HVAC I Mn Cont. Room HVAC 2 Remote Shutdown I Renate Shutdown 2 RPT I Output RPT 2 Output S af ety-Re lated Saf ety-Re I ated Display Instr. I Display Instr, 2 Suppression Suppression Pool Monlt, Monlt.

Pool'emp I Temp, 2 Power & Control for Power & Control for Selected non&lass IE Selected non&lass IE Equipment (prime'ircuits) Equipment (prime circuits)

Reactor Bldg, Pressure Reactor Bldg. Pressure Control I Control 2 Orywell and Head Area Orywel I and Head Area Recirculation Fans I Recirculation Fans 2 ASSIGNMENT OF RPS, NSSSS ANO %IS TO DIVISIONS OF SEPARATION (FAIL-SAFE WIRING)

+

Division 4 Division 5" Division 6 Division 7" RPS AI RPS A2 RPS 81 RPS 82 NSSSS Al NSSSS A2 NSSSS 81 NSSSS 82 NMS A NMS C NMS 8

+ Compatible with Division I

" Compatible with Division 2 24

TABLE III DIVISION HARKERS FOR CLASS 1E EQUIPHENT 6 ENCLOSURES, RACEWAYS, 6 CABLES EXTERNAL TO PGCC (INCLUDING FIELD SIDE OF PGCC TERHINATION CABINETS)

EQUIP/ENCLOSURE/RACE-WAY/CABLE HARKER CABLE ID RACEWAY ASSIGNED DIVISION DIVISION RACEWAY CABLE HARKING HARKING BACKGROUND CHARACTER TYPE DIVISION CHARACTER CHARACTERS COLOR COLOR H,P,C,S DIVe 1 *DIV1 YELLOW BLACK H,P,C,S DIVe 2 *DIV2 ORANGE BLACK H,P,C,S DIV 3 *DIV3 RED BLACK R,C,S CHA1 +CHAI LTe BLUE RED R,C,S CHA2 *CHA2 GREEN RED R,C,S CHB1 *CHB1 DRKe BLUE R,C,S CHB2 +CHB2 BROWN RED Raceway Types *Raceway type letter is located at beginning of marking characters H High Volt Power - 4.16 KV and above Example: PDIV1 = Power Raceway, Division 1 P Power 480/240/208/120 V AC 250/125 V DC C Control-120 V AC/125 V DC and below S Signal R - RPS Scram SOV Raceway Typical Division 1 Harkers (Yellow Background)

Assigned Cable Division 1LPCS-5-C-Div 1 ~DIV1 DIV 1 Black Characters z ~

(Typical)

Raceway Division Cable Harker Raceway, Pullbox, etc. Equip Enclosure Harker Harker The Cable Harker Includes (Voltage Level is Added Both the Cable Number 6 For Above 600 V The Raceway Division Application)

Harking Characters 25

TABLE III (Cont 'd)

NOTES

1. External to PGCC equipment and enclosure residing division separation markers shall on the front face. be'ocated

2. Board S (H13-P851) located in the Hain Control Room shall be identified with division markers the same as other equipment external to PGCC but the markers shall be placed on the inside rear door or on intruding device subenclosures (if required).

25a

4

/

TABLE IV Page 1 of 2 DIVISION HARKERS FOR PRIHE AND NONWLASS 1 E ENCLOSURES, EQUIPMENTS RACEHAYSi AND CABLES EXTERNAL TO PGCC (INCLUDING FIELD SIDE OF PGCC TERHINATION CABINETS)

ENCLOSURE EQUIP RACEHAYS CABLES RACEHAYS CABLES E550/E551 REPRESEN CABLE E 550/E551 PRIME CIRCUITS DIVISZONA HARKER CABLE TATIVE HARKER REFERENC (NOTE 2)

HARKER- 'ACKGROUN CHARACTE COMPATI- CABLE BACKGROUN NOTES E550/E551 ADDITION COLOR COLOR BILITY NUMBER COLOR SAFETY CLR CHECKERED FIELD HARKER AHISC402 Silver

• DIV A . Silver Black A'1 Red/Hhite AMISC900 Silver/

Yellow AHISC 900 Silver/

Yellow (NOTE 1) Silver/

AHISC 900 Yellow B BHISC402 Gold

• DIV B Gold Black B'2 Green/Whi t Gold/ ***

BMISC9001 Oran e Gold/

BHISC900 Oran e (NOTE 1) Gold/

BHISC900 Oran e no~es *See Note on Table III

• • See Table VIII, Page 4; Note 5 See Page 27 for Notes. ***See Table VIII, Page 4, Note 8 26

~ ~ ~

4

TABLE IV Page 2 of 2 DIVISION HARKERS FOR PRIHE AND NONWLASS lE EQUIP ENCLOSURES,. RACEHAYS AND CABLES EXTERNAL TO PGCC (INCLUDING FIELD SIDE OF PGCC TERHINATION CABINETS)

NOTES 1 a A NonClass 1E 9000 series cable .is routed partially or wholly in a Class 1E raceway (Associated by Proximity)-

b. 9000 series cables are non-Class lE cables, which are not physically separated from a Class 1E cable within its equipment. of origin or destination, but is never routed in a Class 1E raceway. These cables are marked with dual color tags the entire cable length.

2.a. Prime cables connect Non-Class 1E loads to Class 1E power sources.

A '1 signifies Div. 1 power feeder to Non-Class 1E Div. A device.

B'2 signifies Div. 2 power feeder to NonMlass lE Div. B device.

A '2 a B '1 circuits are not permitted.

bo An additional checkered marker, as stated in the table, is applied to prime cables as well as to the Non-Class lE raceways carrying prime cables. Refer to E947 for listing of prime tray nodes.

3~ Internal to PGCC equipment and enclosures residing division markers shall be located on the inside rear door, on intruding device subenclosures (if required), or within lines of demarcation.

4~ The Fire Control Panel, and the Security System Panel located in the Main Control Room shall be iden-tified with division markers the same as other equipment external to PGCC except that the markers shall be placed on the inside rear door.

27

s

~s s I ~

DIVISION MARKERS FOR EQUIPMENT, ENCLOSURES, RACEWAYS, CABLES ZN PGCC C CABLE MARKERS V V 0 C C

'rc 4J 4J

>>>>* CABLE SEPARA- Cl Cl ~

0 TION MARKER 4J 4J 0 00 0 C 00 C cd V Cl C ClW Cl 0 Cl 0 4J C al Cl 0 8 8 V O O cd g gO Cl Cl V C Cl 4J cd 'cd C C L Cd o' Cl C C 0 M 0 ccl cd V cd 0'l 4J cd 4J E Cl C4J Cl ld KCl C4 O Cl ld 0

C c0 c0 cd cm 0 cd Cd al Ce T C Cd V C0 00 'Jn C0 al JC 4J Cl Cl cd I Cd C0 CIJ T 0 4J C Cl V V Cl 8 C4 Cl Oe Cl cd Cl O 00 ~ cd Cl cd 4J W Cd CO Cl W Cl Cl W Cl E L cd C VM CA V Cl M ld rE V 0 cd 4J W V Cl al X U '4 0

cd O Cl 0

00 Jd cd oar cl 00 al cl R 0 Cl 4J Cl 8

~

Cl cd 44 Cl al W

cd U ld Cl

~ lJ Cl O

V 0 Cs Cl 4J Jd Cl 4J VA I R 8WW lJ 'U Cl O cd 4J Jd O 0 O

O O

A 0 0

CD O

O A

cd al C cd cd C cd N cd U C3 Cl Cl c0 cd cd Cle lcl OOO V O OZ al 8 c0 0d C0WW cle 8 v 8 G

A1 RPS I RED DIV-1A DZV I BLACK B1 RPS I RED DZV-1B DZV I BLACK N/A ESSI ESSZ BLACK NSSI NSS I BLACK DIV 1 YELLOW YELLOW SZ,CI DIV I BLACK xxxl 0 xx,x.I. N A N A RED HITE SA, CA, N A N/A RED HITE A2 RPS IZ RED DZV-2A DZV II WHITE B2 RPS ZZ RED

2. DIV-2B DIV'IZ WHITE N/A ESSZZ ESS IZ WHITE NSSIZ NSS ZZ WHITE DZV 2 BLUE BLUE SII,CI DZV ZI WHITE KXX.II x xxa1 N/A N/A GREEN/WHITE SS,C2 g C N/A N/A GREEN HITE 3 X ESSZIZ ESSIII WHITE N A XXXI xx1T1 N/A BLUE/YELLOW DZV 3 GREEN GREEN S CZZZ N/A WHITE N A Non X XXXZ XXXZ** YELLOW Div X XXXZI N/A N/A N/A XXXII>>> BLUE WHITE X XXXIZZ XXXZZZ**

X SAsCA DIV A>>>>

X SB,CB DIV B** BLUE

• Numbers which appear on cable markers may be either Arabic or Roman numeral; both are acceptable. Typical for all tables.

• • For equipment and enclosures only. For raceways no lettering exists'**

Cable separation categories enclosed by a box, sech'as ~XXX1 i indicate prime cables.

28

TABLE VI .

EXTERNAL TO PGCC AND FIELD SIDE OF PGCC TERHINATjON CABINETS INTERNAL EQUIPHENT AND ENCLOSURE WIRE IDENTIFICATION For the purpose of differentiating between wires and.cables, all individual conduc-tors of a multiconductor cable shall be defined as wires. In addition, single con-ductor cables 10 AWG and smaller shall be defined as wires within equipment and enclosures. Internal vendor supplied wiring is not required to follow this wiring identification method.

Wire markers shall be required only when circuits are not visually traceable to cable identification -markers within equipment and enclosures.

If wires of prime cables require wire markers for traceability they shall be iden-tified with the appropriate prime cable marker installed in a flag fashion adjacent to each wire marker.

The color of the character and marker sleeve background shall be derived from the cable number and prefix as follows:

Wire Harker Cable Functional Division Character Color Back round Color Prefix s (No. )

1 Black Yellow 2 Black Orange 3 Black Red 4 Red Gray 5 Red Green 6 Red Blue 7 Red Tan A Red White B Green White A (9000) Red White/Yellow B (9000) Green White/Orange 29

I' I ~

~ ~

\

I VII TABLE pg. I of 2 COHPATIBLE ANO INTRUDING CABLES/WIRES INSIDE EQUIPMENT ANO ENCLOSURES EXTERNAL TO PGCC CIRCUIT TYPICAL CABLE MARKER TYP. PRIME TYP. INTRUDING COMPATIBLE (0)h CATEGORIES MARKER tafARKER INTRUDING (X) CABLES/

WIRES INSIDE EQUIP/ENCL i EXTERNAL PGCC TERM.CAB, D O i I i* WW CC Q TO PGCC (FIELD SIDE I ONLY).

Wi RC EQUIP.!

~C I/I ENCLOSURE TERM. CAB.

wAlai all CC laJ OIV.HARK- OIV. MARKER D ~ CC CQ O i CCCC Cl ~C DD A WC O W a<<xI IW &I i/l,a/I i a

5 Cl O

~C W CO XXj au D D CJ CC I

I/I,CCl

~

Ca Vi I4Ji I laI I <<CI/I D WX iaa O laa O

CC <<C ca I/IiI I <<C 0

C XD CC CJ ~

E cJ CC X

. ~l CI.,C.DiD

<<Cl<<C~~ ' <<C D l<<<<l~

I,CJa I CJ i QlO D CJ Ca EJ

~ ~

IOIOIOI Xi 1 PCS-5 .'OIV 1! YELLOW BLACK YELLOW WHITE XIX X I 0 AOOA-9001 ~ OIV I I S LV R YELLOW BLACK REO WHITE YELLOW WHITE X OX X OX 0 X X AH7CA- 1I 1 I Y W N A 000 000 00 X 0 XXX X 0 X 0 XXX X 0 N/ 000 000 00 X X X X Xi 4 5- i H i t. H LU Y L W/WH 0 X

~ XI XI 6R 5- i HBI I 0 K BLU it/A YELLOW/WHITE 0 X XXX XXX X 0 X: W- Y W/WH X X X OX 0 X X: I LV X OX 0

'/

X X X XI B I L LA K WH X: V G / BU/ X 0 XXO X 0 X I /

XI NN- I V V L CK N/ 000 0 0 0 0 XI 0 0 000 ttN- VB L K N/ Ot 0 0 0 0 0 0 ttOTES:

I. The equipment and enclosure divisional separation "marker determines the compatible division of the residing (Unmarked) wiring and cabling. For example a "DIVA" equip.

marker (Not on a term. cab) indicates that the following cable types (see above table) are "Division A compatible" ADOA-9001, AM7CA-9001, BHBCA-9001, ARFWT-21, asM7-9035I AHISC-9001, AAtttt-l0, ASH7-9035,. BHISC-9001, BANN-ll. Also all the internal panel wiring which is not identified by individual separation markers is considered "Division A compatible" wiring.

2. Each enclosure is identified with an appropriate divisional marker to show the residing division of the internal wires/cables. If a Class 1E or a prime cable intrudes into an enclosure assigned to a redundant Class lE division or into a Division A, B, XXXl, XXX2 enclosure then that cable and the internal wiring extending from this cable shall be separated by 6" or a barrier from all enclosure/equipment residing/compatible cables and wires and shall be additionally identified with striped marker tape.

3. All cables identified as intruding cables within equipment/enclosure are identified with a striped marker, as stated above, every 12 + 2 inches beginning at the panel entrance point and continuing to the internal wire string associated with each conductor.

4. AP- Associated By Proximity 30

l I ~

i TABLE VII pg. 2 of 2 COMPATIBLE AND IHTRUDI!IG CABLES/WIRES INSIDE EQUIPMEHT ANO ENCLOSURES IN PGCC CIRCUI CABLE MARKERS EQUIP/ ENCLOS.

CATEG. OI VIS. MARKER

!iI i

I CABLE SEPARATION MARKERS CC CD O IAJ IAI CC IAJ

~ 0 cx-IAJ O

A I

I I Vl O CD 4J I

I LP CD l<<l 0

CJ CD O ~Q JC CD CC O iil JA' Ml 4J ) CAJ l 5O% CC IJl CC CC iil Of CAJ Fl aO cx'AJ iOI<<C'O

<<CC Ix)'M CAJ CXX IAJ I

I I

I I

CD CD lC O CJ ~ XOa CAJ CC CAJ

~ Cll CO IAJ I CD

!~IAC O . <<C <<C IAJ CAJ ~ CO CC O <<C 4l CJ I CD CJ D OIO!OIO X: Al CRPS I RED YELLOW H/A YELLOM/MHITE X X! CI XI X OIV-1A Dlv I BLACK YELLOW N/A YELLOW/MHITE I X XI d Xi X X~ ~ Bl RPS I 'ED YELLOW N/A YELLOW/WHITE I X X! CI X; X

'X' OIV- I 8 DIV I BLACK YELLOM H/A YELLOW/MHITE I X X Ol XI X X' I ESSI I ESS I BLACK YELLOW N/A YELLOM/WHITE X X OI XI X Xi I HSSI NSS I BLACK YELLOW N/A YELLOW/WHITE X X Ol XI X XI ' SI, CI,OIV I BLACK YELLOM N/A YELLOW/WHITE I X X a XI X X'. XXX I H/A N/A YELLO'W RED/WHITE YELLOW/WHITE I x xlx I! I I

m!! Ea AIA N/A YELLO'W RED/WHITE YELLOW/WHITE X XIX I

I I Xi ~ AZ ~

RPS II RED BLUE H/A BLUE/WHITE XlX XiIXX X'2 X' OIV-ZA OIV-ZB OIV

! RPS OIV I II II I,

MHITE RED WHITE BLUE BLUE BLUE H/A iN/A N/A BLUE/MHITE BLUE/WHITE BLUE/WHITE X X Xl Ol X X X XI Ol X XI XI X Ol X I

ESSI I ESS II WHITE BLUE N/A BLUE/MHITE I X Xl X Ol X XI iISSI I NSS II WHITE BLUE N/A BLUE/WHITE x Xlx OIX I XI SII. CII OIV II WHITE BLUE N/A BLUE/WHITE x xixlo X I XI I QXQj N/A H/A BLUE GREEN/'I!HITE BLUE/'WHITE X IXXIO X

'x XI IQ N/A H/A BLUE GREEN/WHITE BLUE/MHITE X OIXIO X

I QQQ N/A N/A GREEN BLUE/YELLOM GREEN/WHITE . X XI X X 0 XI I ESSIII I ESS III MHITE GREEN N/A GREEN/MHITE X XXXIO XI XI XXXIII N/A N/A GREEN H/A N/A 0 Ol 0 Ol 0 Xi S/C III N/A MHITE GREEN N/A GREEH/MHITE Xl Xl X Xl O I XI XI XXXI I N/A ii/A YELLOW H/A N/A 001000 XI XI XXXII N/A i'/A BLUE N/A N/A 0 0 0 0 "xl x SA, CA N/A N/A YELLOW N/A N/A olooo IXI XI SB, CB H/A N/A BLUE N/A H/A OIOOO

'(OTES'he equipment and enclosure divisional marker determines the comoatible division of the residing (unmarked) wiring and cabling. For example a "DIVA" equi marker indicates that the following cable "SEPN" types are "Division A Compatible" XXXI,~SA , ~C xxXI, XXXII, xxxIII, sA, cA, sB, cB. All internal panel wiring which is not identified by individual separation markers is considered "Division 1 Compatible" wiring.

Non-Class IE cables are routed in Non- Divisional raceways.

Cable separation categories enclosed by a 'box such as ~~x x indicate prime cables.

31

TABLE VII.I Page 1 of- 5 EXPLANATORY INFORMATION CONCERNING CABLE ROUTING CABLE LEGEND The legend for the column identification in Table IX is as follows:

(1) CABLE NUMBER Cable numbers have ten-spaces allocated.- Five spaces before the dash and four spaces after the dash. Each space has a specific meaning, as described below.

FIRST SPACE SIXTH SPACE I

1 DIVISION 1 Always to be the Dash (-)

2 DIVISION 2 3 DIVISION 3 4 DIVISION 4 SEVENTH'IGHTHS NINTH & TENTH SPACE 5 DIVISION 5 6 DIVISION 6 Numbers 1 thru 9999 as required 7 DIVISION 7 A DIVISION A B DIVISION B SECOND g THI RD g FOURTH & FI FTH SPACE System or Equipment Identification-The following are typical examples:

ADS AUTOMATIC DEPRESS. SYSTEM RHR RESIDUAL HEAT. REMOVAL IRlA INSTRUMENT RACK lA M7BA MOTOR CONTROL CENTER, NO. MC-7B-A MISC MISCELLANEOUS P8AE POWER PANEL, NO ~ PP-8A-E SH5= SWITCHGEAR 6 ' kV (HIGH), NO. SH-5 SM7 SWITCHGEAR 4.16 kV (MEDIUM), NO. SM7 SL71 SWITCHGEAR. 480 V (LOW)g NO ~ SL-71 EXAMPLES OF CABLE NUMBERS:

1M7BA-221 = 1 (DIV. 1) M- (MOTOR CONTROL CENTER) 7BA (MCC NO.) 221 (CABLE NO.)

32

~ ~ t I h

TABLE VIII (Continued) Page 2 of 5 2RHR-222 = 2 (DIV. 2) RllR (SYSTEM) 222 (CABLE NO ~ )

(2) T/C (TYPE AND COMPATIBILITY)

T = TYPE OF RACE'WAY WHICH CABLE IS COMPATIBLE TO IS AS FOLLOWS:

P POWER C CONTROL H HIGfl VOLT (6.9kV, 4.16kV) S .SIGNAL R RPS Rc RPS SCRAM SOV RACEWAY C = COMPATIBILITY (OUTSIDE OF PGCC) WHICH IS AS FOTLOWS:

1 COMPATIBLE CABLES ARE ROUTED IN DIV 1 RACEWAY SYSTEM ONLY 2 COMPATIBLE CABLES ARE ROUTED IN DIV 2 RACEWAY SYSTEM ONLY 3 COMPATIBLE CABLES ARE ROUTED IN DIV 3 RACEWAY SYSTEM. ONLY 4 COMPATIBLE CABLES ARE ROUTED IN DIV 4 RACEWAY SYSTEM ONLY 5 COMPATIBLE CABLES ARE ROUTED IN DIV 5 RACEWAY SYSTEM ONLY 6 COMPATIBLE CABLES ARE 'ROUTED IN DIV 6 RACEWAY SYSTEM ONLY 7 COMPATIBLE CABLES ARE ROUTED IN DIV 7 RACEWAY SYSTEM ONLY (3) FROM EQUIPMENT OR DEVICE IDENTIFICATION WHICH THE CABLE ORIGINATES FROM I

(4) TO EQUIPMENT OR DEVICE IDENTIFICATION WHICfl THE CABLE TERMINATES TO

( 5) FOR SYSTEM AND/OR SERVICE CABLE IS BEING USED FOR (6) RACEWAY ROUTING NUMBER INDICATED DENOTES NODES THROUGfl WllICli THE CABLE PASSES IN SEQUENCE. IF LETTERS ENTR APPEAR IN THE ROUTI NG i THE CABLE ENTERS AT A POI NT BETWEEN THE PRECEDI NG AND SUCCEEDING NODES ~ IF THE LETTERS "ENTR" DO NOT APPEAR, THE CABLE ENTERS AT FIRST NODE SllOWN. I F THE WORD "EXIT" APPEARS IN THE ROUTING i THE CABLE EXISTS AT A POINT BETWEEN TffE PRECEDING AND SUCCEEDING NODES ~ I F THE WORD EX IT DOES NOT APPEAR i THE CABLE EXITS AT TffE LAST NODE SffOWN ~ THE ABOVE MENTIONED NODES ARE LOCATED AND SHOWN ON RACEWAY DRAWINGS ~

WffEN NODES DO NOT APPEAR i RACEWAYS ARE NOT USED IN SUCH CASES i CABLES SHALL RUN FROM POINT OF ORIGINATION "TON POINT OF TERMINATION WITH OR WITHOUT CONDUITi AS INDICATED ON THE DESIGN DRAWING.

33 '(

~ f ~

I N

TABLE VIII (Continued) Page 3 of 5 (7) CABLE REQD.

NUMBER OF SINGLE OR MULTIPLE CONDUCTOR CABLES REQUIRED.

(8) CABIF. SPEC SEE CABLE TYPES AND DESCRIPTIONS BELOW. (TYPICAL)

CONDUCTOR OD AREA TYPE NUMBER SIZE INCHES SQ. IN.

8kV UNGROUNDED NEUTRAL POWER CABLE 1C 250 1.276 1.2788 (9) CONDUCTOR NO. CONDUCTOR'S NUMBER OF CONDUCTORS IN A CABLE ~ ( lC ONE 12C TWELVE CONDUCTORS g ETC ~ )

(10) CONDUCTOR SIZE WIRE SIZE IN EITHER AWG. OR MCM.

(11) CIRCUIT LENGTff INDICATES TOTAL LENGTH IN FEET FOR EACH CONDUCTOR INCLUSIVE OF THE DISTANCES CONDUCTOR'S NFROMN THE POINT OF ORIGINATION TO RACEWAY ENTRANCE AND FROM THE RACEWAY EXIT "TO" THE POINT OF TERMINATION'ffEN RACEWAY ROUTING IS OMITTED'ENGTH INDICATED REFERS TO DISTANCES "FROM" TffE POINT OF ORIGINATION TO THE POINT OF TERMINATION IN FEET FOR EACH THUS'F THE CABLE CONSISTS OF THREE SINGLE CONDUCTORS, THE TOTAL LENGTff WOULD BE THREE TIMES RUN LENGTH.

(12) REV S.

REVISION NO. OF THE CABLE ISSUE IS DESIGNATED BY THE REV. NO AS) DESIGNATES THE CONSTRUCTION ISSUE STATUS OF THE CABLE.

34

0 I ~

~

~

/

I I

TABLE VIII (Continued) Page 4 of 5

( 13) REFERENCE NOTES SEE DRAWINGS E550 AND E551 FOR REFERENCE NOTES ~ THE LISTED NOTES BELOW WHICH RELATE TO Ef ECTRICAL SEPARATION ARE REITERATED FROM TfIE ABOVE DRAWINGS ~

E550 REF. NOTES 4 THIS CABLE IS NON-CLASS 1E CABLE THAT DOES NOT ROUTE INTO REDUNDANT CLASS lE RACEWAYS'F THIS IS A DIVISION A CABLE AND IS TAGGED XXXII, SB, OR CB INSIDE PGCC IT S'ff ALL NOT ROUTE INTO A DI VISION 1 RACEWAY EXTERNAL TO PGCC ~ SI MILARLY FOR A DIVISION B CABLE AND A DIVISION 2 RACEWAY.

5 THIS CABLE IS CLASSIFIED IN THE SEPARATION GROUPING AS "ASSOCIATED BY PROXIMITY" ~

A) CABLE NUMBERS PREFIXED ( FIRST SPACE) WITH "A" AND ROUTED IN DIVISION 1 RACEWAYS.

(COMPATIBILITY 'IS 1)

B) CABLE NUMBERS PREFIXED (FIRST SPACE) WITff"B" AND ROUTED IN DIVISION 2 RACEWAYS.

(COMPATIBILITY IS 2) 0 I TH S CABLE MAY HAVE MORE THAN ONE DESIGNATION IN THE 9000 SERI ES NUMBERS ~ FOR ROUTING PURPOSES, THESE CABLES SHALL BE CONTINUOUS FROM ONE PIECE OF EQUIPMENT TO ANOTHER. THERE SHALL NOT BE ANY SPLICES OR TERMINATIONS AT TRANSITION POINTS, FIRE STOPS, OR CABLE NUMBER CHANGES. "TP" INDICATES A TRANSITION POINT+ "CONT" INDICATES CONTINUED ON CABLE SHOWN.

9 WHEN A CABLE CANNOT BE IDENTIFIED AS AN INTEGRAL PART OF A SPECIFIC SYSTEM, THE NUMBER "9999" WILL BE INPUT AS THE MECHANICAL SYSTEM NUMBER. THE CABLES ASSIGNED THIS NUMBER WILL BE REVIEWED PERIODICALLY.

13 ALL CABLES WITH PREFIX DIVISION 1 THROUGff 7 AND PRIME CABLES DESIGNATED UNDER THE "SFTY CLR" FIELD AS A'1 OR B'2 SHALL BE INSTALLED TO QUALITY CLASS 1 REQUIREMENTS (ONLY FOR PRIME CABLES INSTALLED AFTER 10-20-81) ~

35

TABLE VIII (Continued) Page 5 of 5 E551 REF. NOTES 4 SAME AS FOR E550 ~

5 SAME AS FOR E550.

8 SAME AS FOR E550 ~

9 SAME AS FOR E550.

21 TffIS CABLE REVISED FROM MULTI-CONDUCTOR TO MULTIPLE SINGLE CONDUCTORS DUE TO INVENTORY REQUIREMENTS'HASING TAPE SHALL BE USED FOR COLOR CODE LABELING ON CONDUCTOR ENDS ONLY. PHASING TAPE TO BE APPLIED APPROXIMATELY TWO INCHES FROM TERMINAL CONNECTOR. FOR COLOR CODE REQUIREMENTS SEE APPLICABLE CONNECTION DRAWING.

22 ALL CABLES WITH PREFIX ( FUNCTIONAL DIV. ) 1 THROUGff 7 AND PRIME'ABLES DESIGNATED UNDER TffE "SFTY CLR" FIELD AS A'1 OR B'2 SffALL DE QUALITY CLASS 1 (ONLY FOR PRIME CABLES INSTALLED AFTER 10-20-81) ~

14. SAFETY CLEARANCE FIELD THE DESIGNATION 'OF A'1 IN THESE FIELDS REPRESENTS A DIVISION A (NON-CLASS'lE) CABLE THAT IS POWERED FROM DIVISION 1 (CLASS lE) ~ AND SIMILARLY, B'2 SIGNIFIES A DIVISION B (NON-CLASS 1E) CABLE THAT IS POWERED FROM DIVISION 2 (CLASS 1E).

36

I TABLE IX SAHPLE CABLE SCNEOULE

( I) ~

(2) (3) (4) (5)- (7) (8) (9) (10) (14) (11) .(12) (13)

CABLE MECH FROM CABL CABL CONDUCTOR SFTY CKT REF NUMBER T/C FROM TO FOR SYSTEM OWG NO REQD SPEC NO SIZE CLR LGTH .-

REV S NOTES AM7A-0102 P A XF)41 1R-7A-8 PNL ELP-7A-B FEEDER 4150 4 Gl IC 2/0 0015 002 (9)

AH7A-0152 P A LOCAL DISC SW PUMP HOIST FEEDER 5110 3 Gl IC 2 A' 0050 002 " 13 r

MTM-6A AH7A-9010 P I NX 14 -7A RFS BUS HTG GEN FEEOER 2620 3 GI IC 4 A' 0044 002 + 5, 13 SET MG-I ENTRtCOLX K, I 13'06;COLY ll 22 06; EL 54t8>>

~(6) RTNG:6987-ENTR-'994-EXIT-6995 EXITtCOLX K I 6t00tt COLY 12 2 35t00<< EL 56t4n

~

AH7A-9100 P I MCC )C-7A TP FEEDER 4150 3 Gl IC I/O A' 0062 002 n 5, 13 CONT AM7A-9101 ENTRtCOLX K I 13 t06<<.COLY 11 22t06n EL 54 tBn

~

RTNG:6992-ENTR-6987-6966-EXIT-6969 EXIT:COLX J 16'06>>;COLY 10 6'06>>; EL 51'6't AH7A-9101 P A TP XFN TR-7A-B FEEDER 4150 3 Gl IC I/O A' 0366 002 " Bt 13 CONT AM7A-9100 ENTR.COLX J 16t06n;COLY 10 6t06<<, EL 48t6<<

RTNG:6696-ENTR-6582-6583-7054-7055-7058-7062-7063-7064-7065-1050-1051-1070-EXIT-1073 EXIT;COLX F 6t00>>ICOLY 14 )3t06<<. EL 73t6<<

AH7A-9110 P I NZ bC-7A TP FEEOER 5250 3 Gl IC 4/0 A' 0066 . 002 " 5, 13 CONT AM7A-9111 ENTR-COLX K, I 9t06n)COLY ll 22t06>>. EL 54t8n RTNG:6992-ENTR-6987-6966-EXIT-6969 EXITtCOLX J 16t06tt)COLY 10 6t06n; EL 51 t6tt AH7A-9111 P A TP COHPRE SSOR FEEOER 5250 Gl IC 4/0 At I 0278 002 <<Bt 13 r~

CONT AH7A-9110 CAS-C- IA ENTRtCOLX J 16t06n.COLY 10 6t06n. EL 48t6>>

RTNG: 6696-ENTR-6582-6583-6549-6548-6546-6545-0429" 0427-EXIT-0424 EXITtCOLX G 6t06>>.COLY 7 Bt00<<; EL 41t6>>

AM7A-9120 P I HCC PC-7A INVERT PKG IN-I FEEOER 4350 3 Gl IC I/O h' 0054 002 " 5, 13 ENTR,COLX K I 12tOOn.COLY ll 22t06>> ~

EL 54t8tt RTNG:6987-ENTR-6992-6994-EXIT-6995 EXITtCOLX K. I 6t00nICOLY 12,2 33t06<< EL 56t4n 37

TABLE X CABLE ROUTING CRITERIA POWER CABLES IN RACEWAyS CABLE APPLICATION 14 ~ 4K, 6~9K 4 ~ 16 KV POWER 480/240/208/120VAC POWER POWE 250 125VDC PWR CABLE DIVISION A B A B 1 2 3 A 1 2 3 B Hc Example 1 Hc B H Example 2 H B H 0 0 AP H Example 3 0 Example 4 0 AP X Non-Class 1E division cables.

0 Class lE division 1 and 2 cables.

+ High Pressure Core Spray (HPCS) Class 1E Division 3 cables.

AP "Associated by Proximity" cables - Non-Class 1E cables routed in compatible Class 1E raceway.

Hc High Voltage Raceway Conduit.

H High Voltage Raceway Conduit or tray.

480V or below Power Raceway Conduit or tray.

Example 14 ~ 4KV Div. A power cable can only be routed in Div. A conduit.

Example 2 It is permissible to route 6.9KV 6 4.16KV Div. A power cables in same Div. A raceway.

Example 3 4.16KV Div. 3 power cables can only be routed in Div 3 H raceways.

Example 4 It is permissible to route Div. A power cable in Div. 1 power raceway.

Such cables are identified by "NOTE 5" in the E550 Cable Schedule Reference Note Column. (For details, see Table IX, Column 13). These cables have raceway compatibility identified per Table IX, column 2.

38

TABLE XI CABLE ROUTING CRITERIA CONTROL CABLES IN RACEHAYS EXTERNAL TO PGCC CABLE APPLICATION Control RPS/NSSS Control RPS Scram Indic. Trip Logic Ind,Ann. SOV Control s Annun. Cables

• Ckts CABLE DIVISIONS 1 2 3 4 5 7 A 4 5 6 1 0 Example 1 0 AP

- Example 2 0

0 0

0 B

Rc 0 Rc 0 Rc 0 Rc 7 0 Digital Computer Signal in Reactor Building only.

C Raceway to route control circuits.

Rc RPS Scram Solenoid Raceway Conduit-X Non-Class lE Division Cables.

+ High Pressure Core Spray (HPCS) Class 1E Division 3 Cables.

0 Class 1E 1 S 2 Division Cables.

AP "Associated by Proximity" Non-Class '!E Cables routed in compatible Class lE raceway.

Example 1 Class lE Div. 1 Control Cables can only be routed in Div. 1 control raceways.

It is permissible to route non-Class 1E Div. A Control/Indication/Ann. Cables in Class 1E Div. 1 raceways Such cables are termed "Associated by Proximity" and are identified by "Note 5" in the E551 Cable Schedule Reference Note Column. (For details see Table VIII, Column 13.). These cables have raceway compatibility identified per. Table VIII, Column 2.

Example 2 Class 1E Div. 3 control cables can only route in Div. 3 raceways.

~ ~

TABLE XII CABLE ROUTING CRITERIA INSTRUHENTATION SIGNAL CABLES IN RACEHAYS EXTERNAL .TO PGCC CABLE APPLICATION 0

ANALOG NHS/NSSS/RPS TRIP SIGNA SIGNAL LOGIC SIGNAL CABLES CABLE DIVISION 1 2 3 4 5 7 A S 0 Example 1 S 0 S

'0 0 Example 2 0

S 0 X Example 3 B

X Non-Class 1E Division Signal Cables.

0 Class 1E Division 1 a 2 Signal Cables.

+ Class 1E HPCS Division 3 Signal Cables.

AP "Associated by Proximity" Non-Class lE Cables routed in compatible Class 1E raceways.

Signal Cable Raceway solid tray or conduit.

Example 1 It is permissible to route Div. A signal cable in Div. 1 raceway. Such cables are termed as "Associated by Proximity" and are identified by "Note 5" in the E551 Cable Schedule Reference Note Column (For details see Table VIII, Column 13). These cables have raceway compatibility identified per Table VIII, Column 2.

Example 2 Div. 5 RPS/NHS signal cable can only be routed in Div. 5 signal raceways.

Example 3. Non-Class 1E Div. A signal cables route only in Div. A signal raceways.

40

TABLE XIII GENERAL PLANT AND PGCC CLASS 1E CABLE INTERFACE CONTROL/INDICATION/SIGNAL INTER- NSSS BOP PGCC PGCC FACE PGCC CABLE RACEWAY BOP CABLE ID DIVISION CABLE ID DIV 2 3 ESSI SI,CI 0 ESSII SII,CII 0 Note 1 ESSIII S C III RPS A1 0 Note 2 RPS B1 0 RPS A2 0 RPS B2 0 NSSI 0 Note 2 NSSII 0 DIV1A 0 DIV1B 0 DIV2A 0 DIV2B 0 General Plant PGCC Area-Raceways Raceways 0 - Class 1E Division Cables

+ - High Pressure Core Spray (HPCS) Class 1E,Division Cables Note 1 Class 1E circuits are routed in compatible Class lE division of PGCC raceways.

Note 2 RPS/NSS Class 1E control and signal cables are considered compatible to either Div 1 or Div 2 PGCC raceway routing as stated in Table II.

TABLE XIV GENERAL PLANT AND PGCC NON-CLASS lE CABLE INTERFACE CONTROL INDICATION SIGNAL SEE NOTE 1 CABLE ROUTED IN GENERAL PLAN NSSS BOP PGCC RACEHAY CABLE ROUTED TO PGCC CIRCUIT PGCC PGCC DIVISION IN GENERAL INTERFACING CLASSIFICA- CABLE CABLE PLANT RACEHAY CABLE TION DIVISION DIVISION NON-DIVISION DIVISION (a) (b) DIV N/A DIV A PRISE (A'l l ~XXXl ~SA ~CA X Example 1 AP DIV A AP XXX1 SA, CA Example 2 DIV 1 DIV A AP XXX2 SB,CB X Example 3 2 1 N A DIV A AP XXX2 SB,CB X Example 4 DIV B PRIHE (B '2) XXX2 ~SB ~CB N A AP DIV B AP XXX2 SB,CB DIV 2 DIV B AP XXX1 SA,CA DIV B AP XXX1 SA,CA DIV 3 PRIHE (3) XXX3 S3,C3 AP DIV 3 AP XXX3 S3,C3 X X General Plant PGCC Area Raceways Raceways AP Associated by Proximity.

HOTES:

l. In PGCC there are two types of routing/cable tagging configurations. "NSSS" circuits (General Electric scope cir-cuits interfacing with 600 Series panel modules) follow the cable divisional tagging per column (a) All other cir-cuits (Balance of Plant circuits interfacing with 800 Series panel modules) follow the cable divisional tagging per column (b).

2. For examples see Sh. 2 of this table.

42

~ ~ ~

TABLE XZ p. Zc)F L Q E.kl. PLAklT pqcc AQUA EXAMPLE I PRIME DIVA-A I CABLE PGcc TERM ~xxx I CABlE END CABIN!KT DEVICE (RACE.V/AY) DIY A DIY I (PCICC i2ACC,WAY) hJOTE: PRIME CABLES Ix~~ll,~x>~,[XXxl CAN HN'E QOUTKD IN HOhJ-D)VISIOklAL PSCC DUCTS. PRIME CABLES ARK ALLOWE.D TQ ROUTE Ikl CIhlLY THG COMPATIBLE DIVISIONALDUCTS, ENMPLE 2 DIV A CABLE PGCG 'fERM XXX I CABI 6 END CABINKT DEVICE DIV I AD HOTEl INTERNAL TO PQCG DIV A CABLE QA'T BE lZOUTED IN DIV I CD@ NOh)-VIV WCC +AC EWAY.

EXAMPLE 9 DIV A CABLE PGCG TERM XXX 200 END CA&INH DEVICE DIV I DIV A RED QlhlOTE: INTERNAL TO PSC< DIVA CABLE MAY B6 fAQCIED AS XXXQ AND IZOUTBD IN T

IN DIV 'L WC[ RA~AY 'PBQEBY AVOIDILJCq DIRECT, 5RIDQlhlQ.

EXAMPLE 4 DIV A CABI 6 PGCC TERM XXX2 END CASINEf. DEVICE DIV A NO DIY '2 Qe NOTE'IIEN INTEQFACINCI P(jCG CABLE IS TAGGBD XXXZ AND QDUTBD IN NO/DIV 'E PGCC RA~ev4A'I S ~ SUCH CA9LE IS NOT ALLoWED $0 fZOUTB IN 6 DIVISION I PCIC~ RACEWAY IN,GOWN STREAM CIRCUITS 7IIERE'6'f AVOIDINCI- DIIZEC+ B RIOCIIIJ I'IOTE: Above examples are similar for DIV 8 and DIV 2.

43

Example I: NSSS PGCC Cable Info>><<ation Obtai>>ed IADIE XV Page I of 2 fram the GE System Cable POWER GENERAIION CDNIRUI CUHI'I EX Sm>><<ary: Cable No. 8708/C518-002, from: N13-P687 t(HCu1T OEKIGH To: N13-P608 GINNED lIII'DiUU(TirNI System: C518 PGCC CABlE SEPARATION CATEGORIES Signal: GE/HAC Separation: 82 NSSS OOP CODE CODE( I) DESCRIPTION SEPARAflON COOKS ESSI Olv I Core Standby Cooling System N Division I 0 PGCC POWER SUPPLY CLASSIfiCAIION ESS2 Dlv 2 Core Sta>>dby Cooling System N NE Division 2 I 5 5 INDEX OF SYSIEHS Olv 3 Core Standby Cooling System ESS3 2 SS N C1.1(~S'f CLASS Division 3 X 822A Nuclear Boiler Process Instrumentatla>> POWER SOURCE IE Al Oiv 4 Reactor Protection System/Nuclear Steaa ly Slmtof f Sys 2 822C Auto Oepressurlzatfon System (AOS) DESCRIPTION PR IHE Channel A Division I 822E Jet Puef'nst'<<ac>>tat lan AS SIOMN ON ELEHEHTARY

~4 88 4 BI Dlv 6 Reactor Protection Channel 8 Division System/Nuclear Steaa I

~Iy Shutoff System d a 822N N<<clear Steam Supply Shutoff System (NSSSS) 126lRC 1HS'lR BUS 3X A2 Olv 5 Reactor Protection System/Nuclear Steaa Supply Shutoff System 22 X

X 835A Reactor Recirculation C12A Reactor Hanual Control (RHC)

C128 Control Rod Drive Hydraulic (CRO NYO) 1?B VDC TRSTA EOS

?1VDC TASTE EC

?EVDC IIEIK EOK 1M VAC TAETIA~

2!

22 82 Oiv 7 Channel A.Division Reactor Protection Channel 8 Division 2

System/Nuclear Steav 2

~ ~

ly Shutoff System X Olv I Nuclear Steam Supply Shutoff System

~

NSSI X C34A feedwater Control 1?6 M 1RSTH 105WRK BOB-Z Division I Standby Liquid Control E'?MDC C41A NSSII Olv 2 Nuclear Steam Supply Shutoff System X CSIA Startup Range Neutron Honitoring '1?5"VOC IRK(K EOE F Division 2 C518 Power Range Neutron Honitarl>>g 24V~HSTH OIV IA OIV 4 Neutron Honltorlng System Trip X CSIC Startup Drive Control 2'49K1RSIF Logic Al Division IA X C51D Traversing In-Core Probe Calib (lip) 1?DVIC UPWK DIV 18 OIV 6 Neutron Ihnl torlng System Trip X C61A Remote Shutdown 126WC OPS"EO~ I.ogle Bl Division IB X C72A Reactor Protection System (RPS) 126VXC UPS BOS E OIV 2A OIV 5 Neutron Honl torlng System Trip X C728 RPS Hotor Generator Set Control '1MVKRH EKE x logic A2 Division 2A X C91A Computer Interconnection "1?DV)IC HPS'B05 0 2 OIV 28 OIV 7 Neutron Honltorlng System Trip X 017A Process Radiation Honltorlng 1?EVE'RSTVGUTM X Logic 82 Division 28 D21A Area Radiation Honitorlng (ARH) '1HSTH'BOS C  !'

X All other non-safety functions routed

'26VOC XXXI DIV A X E12A Residual Neat Removal (RNR) 22VDC lAKTA BIE c or OIV 8 with Division I PGCC raceways or Kon-X E21A low Pressure Core Spray (t PCS) Class IC PGCC raceways. (XXXI cable X E22A Nigh Pressure Care Spray (HPCS) In OIV I race~ay ls associated)

E228 NPCS Po~er Supply Safety-Related Systems XXXII OIV A All other non-safety functions routed B E3IA teak DetecLIon (NSSS) or OIV 8 with Division 2 cables or Non-Class E5IA Reactor Core Isolation Cooling (RCIC) IE PGCC raceways. (XXII Dlv 2 raceway X GIIA Radwaste Is assoc lated) 2 G33A Reactor Water Cleanup XXX111 DIV 3 All other non-safety functions routed H13A Annunciator System with Division 3 PGCC raceways.

X N64A Off Gas System - Law Temp.

(I) Ibis Bup code corresponds to the BUP cable seiara ep ration classification that Interfaces with the N555 separation code. This code Is also used in combinationn wwith the BOP PGCC C sl signal nal code to describe BDP pGCC cable signal/separation classification. I.e., "Cl I>>d<<a<> erface with w XXXI PGCC cables providing "bridging" between Rednlid>>t raceways does "

TABLE XV POWER GENERATION CONTROL COHPLEX Sheet 2 of 2 PGCC CABLE TYPES CIRCUIT'DESIGN

<Supplied by General Electric) GENERAL I NFORHAT ION NESS BOP Example 1: . BOP PGCC Cable InformatIon CODE DESCRIPTION Obtained from the MR BOP

~ cable routing SPI AWG 20 I Twisted Shielded Pair of l20 Mire Sumnary: Cable No. 64-K2-). IO SP4 AKG 20 GE-7A 4 Twisted Shielded Pairs ot KO Wire From: H13-P 891 SP7 AMG 20 GE-5A 7 Twisted Shielded Pairs of 820 Wire To: H13-P 811 SP13 AWG 20 13 Twisted Shielded Pairs of $ 20 Wire Signal A Separation: C2 GE-5 7 Twisted Shielded Pairs of ll6 Wire Cable Type: GE-I TC4 Cu/Cn 4 Shielded Pairs of Copper Constantan Raceway: Olv 2 Thermocouple Wire TCB Cu/Cn GE-6 8 Shielded Pairs of Copper Constantan Thermocoup le Wire TC8 Chr/Cn 8 Shielded Pairs of Chrome Constantan Thermocoup I e Wire GE-7 4 Twisted Shielded Pairs of l)6 Wire ST/I AWG 20 Twisted Shielded Triple Conductors of F20 Wire PGCC SIGNAL DESCRIPTION GE-4 12 Conductors of $ 14 Wire with Overall Shield NSSS BOP GE-3 7 Conductors of I14 lflre CODE CODE (I) DESCRIPTION HC7 AWG 14 GE-I 19 Conductors of l)4 Mire GE/HAC S Hl I I lamp Process Sl gnal HC19 AWG 14 Low A S Low, Level Analog Signal 8 Conductors of I)6 Mire Low D S Low Level Digital Signal HCB AWG 16 Comp A S 160 NV Computer Analog Signal 12 Conductors of $ 16 Wire Comp D S Computer digital Signal HC12 AWg 16 19 Conductors ot PI6 Wire H/R IN S Meter/Recorder Input HCI9 AWG 16 27 Conductors of f16 Wire ANN IN C/S Annunciator Input HC27 AWG 16 37 Conductors of l)6 Wire 28 VOC C 28 Volt OC Power HC37- AWG 16 7 Conductors of l20 Wire 120 VAC C 120 Volt AC Power HC7 AWG 16 12 Conductors of l20 Wire 125 VDC C 125 Volt DC Power HC12 AWG 20 19 Conductors of $ 20 Wire Cl 120A C 120 Volt AC Control 8, HC19 AMG 20 27 Conductors of f20 Wire Indication Signal HC27 AWG 20 37 Conductors ot AO Mire Cl 125D C 125 Volt DC Control L HC37 AMG 20 48 Conductors of J20 Wire Indication Signal HC48 AWG 20 Cl 280 C/S 28 Volt DC Control 6 7/C AWG 14 7 Separate Conductors ot ll4 Wire Routed In indication Signal Conduit 24 VDC 24 Volt DC Power 12/C AMG 14 12 Separate Conductors of i)4 Wire Routed ln CT 5A 5 Amp'urrent Transformer Conduit Circuit 2 COND FMR 2 Power Conductors Routed In Conduit ARH IN S Area Radiation &n)tor Input 3 COND PWR 3 Power Conductors Routed In Conduit COAX RG-6 Coaxial Cable Type RG-6 COAX RG-22 Coaxial Cable Type RG-22 COAX RG-59 Coaxial Cable Type RG-59 COAX RG-59AI4 Coaxial Cable Type RG-5%@

GE-8 6 3/c II6 Individually Shielded GE-9 2 I/c IIO Il) This BOP code corresponds to BOP cable signal classlf ication for GE-10 2 I/c II2 BOP PGCC Cables and for those cables that Interface with the NSSS GE-12 4 4/c II4 PGCC cab l es GE-13 4 4/c j16 Individually Shielded GE-14 7/c P)6 Overall Shield

TABLE XVI Page I of 2 NSSS VENDOR GENERAL DESIGN INFORHATION S'YSTEH CABLES AND ROUTING CRITERIA FIELD IN PGCC NODULAR FLOOR DUCTS NSSS SPECIAL CABLE REP DESCR I PT ION 4J Special REMARKS

>>c PI ~

fal M

M o>>cu W ch O g,N MOW Requ lr O OE4 OUQ C4 M 0 Q M X K'I C4 Olv I AI C1120A I2/CP14 Fa I I saf e cables 1PS/NSSSS TRIP LOGIC X Kl C6 Olv I 81 C1120A 12/CII4 routed In grounded ONTROL CABLES X Kl C5 Olv 2 A2 C1120A 12/CI14 flex CND wlthln PGCC X Kl C7 Dlv 2 82 C I 120A 12/CI14 X H2 R4 Ol v I Al C1120A 2CONOPWR SCRAM SOY CKT RPS scram SOV cables NEUTRAL TD BE trip logic Al d, 81 an)

)PS SCRAM X H2 R6 Dl v I 81 C1120A 2CONDPWR g6AWG FROM MAIN LPRH group I 8, 3 iOLENO I OS CONTROL PANEL cables are routed in

.ABLES X H2 R5 Olv 2 A2 C1120A 2CONOPWR TO SCRAM GROUP separate PGCC Ol vis lo)

PULL BOX AT I ducts, slmllarly fo$

X H2 R7 Olv 2 82 C1120A 2CONOPWR SOVS RPS scram SOV cables L2 S4 Oiv I Al GENAC SP4 trip logic A2 8 82 an)

CPS TRIP LOGIC L2 S6 Olv I 81 GEMAC SP4 LPRH group 2 f, 4 5 IGNAL CABLES L2 S5 Olv 2 A2 GEMAC SP4 cables, L2 S7 Ol v 2 82 GEMAC SP4 SENSOR CA 20 5 1000 COAX 3 SHLO Hl RAO, TEHP I PREANP SIG CA Nl LOW A COAX RG6 75 20>>0 1500 COAX STO PREAMP HV ~ CA L4 LOW A COAX RG59 47 37>>3 2000 SHLO PREAMP LY ~ CA L4 Cl 2M COAX RG59 47 37>>3 2000 SHLO SENSOR CA N6 130 9>> 8 I 000 COAX 3 SHLO, PREAMP S I G CA Ml LOW A COAX RG6 75 20 0 .1500 COAX STD FREAMP HV ~ CA, L4 LOW A COAX RG59 47 37>>3 2000 SHLO Neutron PREAMP LV ~ CA>> X L4 S4 Olv I Olv1 Cl 280 COAX RG59 47 37 3 2000 SHLD Monitor lng RANGE SW CA ~ Cl 280 NC1 9 System SENSOR/EPA>> CA 25>> 7 2300 COAX HI Group I RAO TEHP EPA/PGCC CA>> L4 LOW A COAX RG59 47 37>>3 2000 SHLD SENSOR CA Ml 75 20 5 1000 COAX 3 SHLD HI RAD, TEMP PREAMP S IG CA LOW A COAX RG6 75 20>>0 1500 COAX STD FREAMP HV ~ CA L4 LOW A COAX RG59 47 37>>3 2000 SHLO PREAMP LY ~ CA L4 LOW A COAX RG59 47 37>>3 2000 SHLO SAME AS NMS GRP, I S6 Dlv I Ol vl SAME AS NMS GROUP I NHS GROUP III SAME AS NMS GRP, I X vxn 55 Dlv 2 Olv SANE AS NMS CROUP I NMS GROUP II SAME AS NHS GRP I X en< S7 Olv 2 Olv2 SAME AS NMS GROUP I NMS GROUP IV 46

TABLE XVI

>ntlnued 'From Page I pg. 2 of 2 PROCESS RADIATION I X I I s[ S2( Olv 2] XXX2 SAME AS WS GROUP I MONITORING (017A) X I g<l SB I Olv 2I XXX2 l SAME AS NMS GROUP I AREA RADIATION L3 S2 Dlv 2 XXX2 ARM IN MCB MONITORING (021A) L3 SA I Dlv 2 XXX2 ARM IN INDEX MECH CABLE X L3 C2 27/C SHLD DRIVE MECH POS INO X L3 C2 01 v 2 LOW 0 MC48 48/C SHLD DRIVE NEW CONTRCA X L3 C2 Olv 2 LOW 0 37/C SHLD ORI VE MECH ANALOG Ll S2 Ol v 2 LOW A STI POS DRIVE MECH DET SIG X L4 S2 Olv 2 LOW A COAX RG59 47 37~ 200 SHLD DRIVE MECH CHAMBER X L3 C2 4/C SHLO DRIVE MECH BALL KI C2 2/c$ 16 VACA SHEAR VA ASSY CA+ X L3 C2 14/c SHLD ROO LEFT/RIGH POSITIOII BRANCH Gl CA Olv I XXXI i C1120A 2CONDPWR CABINET ) JUNCTION MB SA Ol v I XXXI LOW 0 COAX RG22 MODULES CRD FROBE/EPA CAB, X K2 S I RAYCHEM 13/C 60/7180 OR EOUAL EPA/RPIS CABLE L3 Sl Olv I XXXI LOW A MC48 EPA/H22W007 J2 Sl 28 PAIR OA SHLO H2 Cl Olv 'I C1120A .2CONOPWR Fallsafe Power Cables G2 PA Olv I C I 120A 2CONOPWR Routed In Grounded RPS POWER G2 C2 Ol v 2 C1120A 2CONDPWR Flexible Conduit Wlthln SUPPLY (C72B) G2 P2 Ol v 2 XXX2 C1120A 2CONOPWR PGCC, H2 C2 Ol v 2 XXX2 C1120A 2CONDPWR G2 PB Ol v 2 C1120A 2CONOPWR H2 CI Olv I C1120A 2CONOPWR The LPRM Cables are subdlvlded Into four groups as fol laws:

Group I (Olv IA) APRM CHE Group 2 (Olv 2A) APRM CHCIIO Group 3 (Olv IB) APRM CHAfB Group 4 (Dlv 28) APRM CHF 47

OlP.ECT BQIDGlklC 5E,TV/EBkl CLASS tC RAl" BVlAYS Dl VI'SICM 4 DIYISIOI4 A DIVISIOM A F MQ.OSURS QNCLOSUR6 EhKLOSUR5 QIVISIOM I DIVISIOM I QIVmlOM I.

ENCLOQJRE ENCLOIMRS } PIICLO~JJ l2$

DIVISIOM I DIVISIOH I OIVISIOhl I RACiKWAY RACEWAY RACEWAY GIVISIOM A DIVISIOM 5 QIVISIOM Z KMCLOSURE RACEWAY &ICLOSURK QIVISIOM 5 DIVISIOM QIVISIOH Z RACEW'AY RACKWA'f RACKWA (

O~ RZIMS OR DIVISIOM 4 CITS IK CIRCUI'f RACPP/A f CfYPCAL)

ASSOCIATEO BY FROXIMITY CRQJIT (TYPICAI )

HOW: GIRECf BRIQQIM6 8 MOY ALLO%ED

I I ~ ~

I

~ ~

FIGURE IE SE C 0NDAR BQI D Ikl eY PROX I M ITY DIVISIoH A DIVIGioM 5 EklCLOSUf2B ENCI OSURE DIVISION I IV I DIV 2, DlvlSIoN 2 I2ACEWA'( CLASS IE, CLASS IE R4CEWAQ Ca,5LB OIVI9IOH A DIVISloN 8

~6WAY RACEWAY secoN~RY hJohl-ONISIOHa ~ F%cc BRIDE ING RACKVvay OR BY PROXIMITY BNCQDQUl2E.

CIRCUITS EMOTE: SECOklDAI2'( 52IDQINQ IS ALLOWED ~P(HEQE.

ACCEPTABLE 5Y AhJALYSI5 49

I

~ I ~

I FICjURE IC SE.CONDARY BQIOCjlNCj WITH1kl UIPlvlEhlT AND ENCLoSUQE5 BNCLOSU86/gpss

~A'( QE Akl IP SEPARATION BARRIER 0% SAY(S)

DIVISIQN 1 D)VISION 2. CLASS IE.

CLASS IE COMPAY'i6LE Q)MPH lSLC.

DIVISION I OIVISION '2 DEVIl"E WlR>ag DKVICB UoN-CLA5S IE olvlsloN A o6vica, EcpuipMawf Ol2 5gl" LEISURE.

CAB'lviSION DIVI5IOH I CABLE 4 DlvlSIOxl 2 CALLE.

DIVISION i. DiViSION A DIVISION '2 RACEWAY ZAt"EM/A (

IZAC EWE MOTE: SECONDARY Bl2IDG1MQ 1kJ EklCLO-URER IS.ALLOV/ED WHERE ACCEPTABLE BY ANALYSIS

g > I

~ ~

)

1 FICjLII2E 2 OU~ PENETRATION RPS SE,PARATIOkl C,OkJCKPT CONDUCTS PKNSTRATION E)

WIREWAY DIV &

NON NEUTRON CONDUIT 5ENSORS I))S MC~

C))AHNSI S B OIV OIV OIV OIV XA APRth I Rth AP Rth 5 A SCP a CAPRI)I PWR PLANET N Q)I D IRlh ACE TRIP TRIP LOG ICA LOGIC 5I INDI VI OU A I OUTPUT LOGIC I Rth T RI P SXT INTN-CONNECTIONS TRI P Dgp LOGIC A GR5 LOGIC BI)

GRZ TRIP ~~+

WIRRWAY %4%

%II ~ TRI P ACTINIDR WIREWAY 4CTVA~ h)PRth I RQ APRth LOGIC i'll V'7 Cc& D OUTPUT 8 &muP I

SROVP I WIREWAY DIV PENET C SCRhM GROUP PULL BOX OR dCIUIVALSNT (BY AL)

ISCRhlh HKUP SuSWAV OR KCiIUIYAlJKNTTBY AIL+ gI ONR CONOUIT

&Olk A P ItOTSCTI ON TKRI)llN AL PER EACH F)QD BOX Ot) HCU SEPARATE TERth BOARDS) NO AIR. PILOT SCRAlh SOLENOID YALYGS 5ARRIER RE%WIRED FOR CIA ROO.

4 RS RPS SSNSORS Ala I

OR Cgb MAY 44 CONNECTED TO A COI)IMON PROCESS TAP RPS SENSORS) h)IG OR STC) )AUST )IOT COI)IISCTKD TO A COIhHON FROCII&6 TAP.

WlhEWAYS HA,)IS,ETC. IhAY St) A551GIIKD TO SSPhhAT8 bIYISIONS hS APPROPRIATE 'TO PLANT LAYOUT'.

h~ 545 FOUR, PENETRATION RP5 5'))ARATION CONCEPT 51

~ I h s ~

I COMMOH COMMCIN PROCESS P'ROCRS5 TAP TAP RPS SKNSORS CCtNOUITS RPS PAI LSAP8 I I OGIC OIVISIQN T.

I CQMOUIT 4 I I

OIVISIQN g

~RIP i~it ~ l

'TRIP, TRiP lASIC CC¹IOlJI T N IOCIC AI I LOGIC LOSIC ',

BZ, AR INOIVIOUAL CQNOUIl8 ILI ARY AUXILIARY RB LAYS MhHUAL I MANUh Pt CLAY5 SLNITCll IhtSOARO Wll%VIIII'UX OIV 'T OUTSOARb YAL VKS SWITCH I I VAI VQ+ bIV E WIRSWAY COIIOUIT COIIOUIT I MOTOh OIV X SI4 OIV E PQWKI% POWER AC AN~It OC, IIL.CI. HleOo OR CR SOI-. SOI ~

It475RCONNICTIN& CCIIOLllT5 USSCI POR MAIN S'TEA'M 1'50LATION vhl VK Y'2 LOGIC OHI

~ ) I I

r

l FIGURE 4 i

PQQXIMI TY CIRCU IT 5ECTIONALIZATION I2EACTOQ, QLDCI. TURBINE 5LDG.

CLASS IE RACEWAYS klOQ-CLASS IE RACK,'(VAYU NOMIC-CLASS IE ABSOCIATEO ~gOhl-CMS5 AF'f IP WITHIM BY PkoxlMITY I ER LE'AylMG

+UIPlvlE@/ CLASS IK QACEVIAY Sga osuah WITHIN CLASS IE RACEWAY QO FINAL ~D klohlKLAS5 I B POWBR SOUlK.E, LJ DIVISiotJ I DIVlslotJ A I

EQUIPMENT/FWCLDSUl2'6 ~>

FINAL ELECl @ICAL (DE,YICE. HOUSING g FLEX, <OhLDQLT INCLUDE)<Cz PLRGT YE< ')

53

APPENDIX A FIELD VERIFICATION I

The purpose of this Appendix is to provide a more simple and condensed form of the criteria in a manner to assist in field verification. This Appendix is not as comprehensive as Section ZZ and related tables and figures, but is intended to be a verification tool capable of addressing the large ma)ority of installations in the field.

For Contractor personnel, if during the course of construction first or in-process inspec-consult Section ZZ tion activities deviations from this Appendix are found, w'hich is more complete and/or request clarification from supervisory personnel. If a deviation still exists, the specific(s) should be brought to the attention of"Burns and Roe through normal project means.

Zt should be noted that this Appendix was principally written with assistance from

-Bechtel QC and Bechtel Engineering personnel to input: a construction perspective. Zt.'s recognized that there is duplication between this Appendix and the remainder of the document. This Appendix has been reviewed by Burns and Roe and determined to be consistent with the other sections. Zt has been incorporated into the Burns and Roe document to provide a single place for a baseline for WNP-2 electrical separation.

A. General