Text

to Crbr Requirements for Environ Qualification of Class IE Equipment.
	ML20050J052
Person / Time
Site:	Clinch River
Issue date:	02/09/1982
From:	Clare G, Hamilton W, Mclane F; WESTINGHOUSE ELECTRIC COMPANY, DIV OF CBS CORP.
To:	;
Shared Package
ML20050H930	List: ML20050H915; ML20050J052;
References
	WARD-D-0165, WARD-D-0165-R06, WARD-D-165, WARD-D-165-R6, NUDOCS 8204140168
	Download: ML20050J052 (115)
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Clinch River Breeder Reactor Plant l

REQUIREMENTS FOR ENVIRONMENTAL QUALIFICATION OF CLASS 1E EQUIPMENT O .

i ENGINEERING RELEASE SY hLRM ERO L00139 DATE2/9/82 l

l Prepared for the Unitea States Department of Energy under contracts EY 76-C-15 2395 and l

, EY 76-C 150003.

i Any Further Distributiori by any Holdes of this Document or of l the Data Therein to Third Parties Representing Foreign Interest, Foreign Governments, Foreign Companies and Foreigt. Subsidia.ies or Foreign Divisions of U.S. Companies Should be Coordinated with the Director, Division of Reactor Research and Davelopment, U.S. Department of Energy.

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1 W) Westinglouse E ectric Corporation ADVANCED REACTORS DIVISION CLINCH RIVER SITE U 2 0414 01 '43 B204: P.O. BOX W r'Dn ADoch r < m o~ .

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El #RFD -d TfR&3 3 O REQUIREMENTS FOR ENVIRONMENTAL QUALIFICATION OF CRBRP CLASS 1E ,

EQUIPMENT O .

PREPARED BY:

$w F. E. McLane, Systems E?!gineering' o

G. th-tTa~rf, Systsifs Engineering APPROVED:

Nddm.dC,f O W. H. Hamilton,Jr., Man 2tgler, Systems Engineering J

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INFORMATION CONCERNING USE OF THIS REPORT PRELIMINARY DOCUMENT This report contains information of a preliminary nature prepared in the course of work for the U. S. Department of Energy. This information is subject to correction or modification upon the collection and evaluation of additional data.

NOTICE This report was prepared as an account of work sponsored by the O United States Government. Neither the U. S. Department of Energy, nor any of their employees, nor any of their contractors, subcontractors, or their employees, makes any warranty, expressor implied, or assumes any legal liability or responsibility for the accuracy, completeness of usefulness of any information, apparatus, product or process disclosed, or represents that its use would not infringe privately owned rights.

WESTINGHOUSE ELECTRIC CORPORATION ADVANCED REACTORS DIVISION P. O. 80X W 0AX RIDGE, TN. 37830 O

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_n TITLE DOCUMENT NO.

/4,d CHANGE CONTROL Requirements for l L LMFBR i ^. RECORD Environmental Qualificatior WARD-D-0165 b WESTINGHOUSE of CRBRP Class 1E Equipment ADVANCED REACTORS DIVISION CHANGE REV NO./ RELEASE PAGES AFFECTED REMARKS DATE DOCUMENT Rev. 1/

8/31/78 L-00032 All Initial Release (Rev. 0 was never released)

Rev. 2/ L-00049 3-10, 3-12 Incorporates ECP L10-087 5/1/79 Rev. 3/ L-00049 Title Page,11 Incorporates ECP L10-089 5/1/79 3-3 through 3-18 and comments of ECP L10-061 Rev. 4/ L-00076 Title Page, ii, 2-1, 2-2 Incorporates ECP L10-109.

5/28/80 3-1, 3-2, 3-4, 3-29 through 3-35, 4-1, 4-2, l l 4-3, 4-4, 4-9, 4-14 Rev. 5/ L-00115 Title Page,11, 3-3 Incorporates ECP L10-145.

4/2 1, // through 3-36 Alligns Tables 3-1 & 3-2

/,f/ wi th the 500's .

Rev. 5/ .

L-00139 Title Page, iii, 2-9, Incorporates ECP L10-165.

2/9/82 2-10, 3-1, 3-12c, 3-23, Clarifies the non-severe and

( 3-23a, 3-27a, 3-27b, severe sodium aerosol envi-

Av 3-29, 3-29a, 3-29b, ronments; reduces the non-3-30, 3-36, 4-1, 4-2, 4-3 severe sodium aerosol envi-ronment; establishes the non-severe sodium aerosol qualification requirements.

Establishes aging require-ments for equipment located in non-severe environments.

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l 5-73 PO1471-1

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TABLE OF CONTENTS SECTION PAGE 1 INTRODUCTION 1-1 to 1-2 2 ENVIRONMENTS 2-1 to 2-14 j 3 QUALIFICATION BASIS AND IMPLEMENTATION 3-1 to 3-18 4 QUALIFICATION PROCEDURES 4-1 to 4-12 l

i 5 DOCUMENTATION OF QUALIFICATION 5-1 ACRONYMS j -

REFERENCES l '

t APPENDICES A EQUIPMENT QUALIFICATION DATA PACKAGE A-1 to A-12 i

l l

1 0

4

)

T LIST OF TABLES Table Title Page 2-1 Normal Environmental Conditions 2-2 2-2 Design Basis Events Which may Produce Severe 2-3 to 2-5 Environments for Class 1E Equipment 3-1 Class 1E Equipment not Subjected to Severe 3-3 to 3-28 Environments R5 3-2 Class 1E Equipment Subjected to Severe 3-29 to 3-36 Environments L 4-1 Environmental Test for Equipment not Subjected to Severe Accident Environments 4-14 4

4 l

l 11 n.ca w,- A

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LIST OF FIGURES Figure Title Page 2-1 Temperature Transient (Pri Na Storage Tank Fire) 2-6 2-2 Pressure Transient (Pri Na Storage Tank Fire) 2-7 2-3 Radiation Dose Rates (Pri Na Tank) 2-8 2-4 Chemical Transient (Pri Na Storage Tank Fire) 2-9 R6 2-6 Dose Rate (Reactor Cover Gas Release) 2-11 2-7 Temperature af ter Steam /Feedwater 2-12 2-8 Pressure af ter Steam /Feedwater 2-13 2-9 Dose Rate in RSB Cells 352A and 353A 2-14 4-1 Environmental Test for Equipment Not Subjected to 4-9 Severe Accident Environments 4-2 Qua'lification Envelope for Equipment Located in 4-10 Severe Accident Environments 4-3 AGE Acceleration vs. Temperature 4-12 O

iii

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1. INTRODUCTION ,

This document establishes the qualification program which will be conducted g to qualify Class IE equipment located in different areas of the Clinch River Breeder Reactor Plant and sets forth the documentation to be completed for qualification. The entire program is designed to conform to IEEE Std. 323-1974 as clarified by the forward issued by NPEC on July 24, 1975 as IEEE Std. 323A 1975. When IEEE Std. 323-1974 is mentioned in this document, it is to be understood to include the clarification issued as IEEE Std. 323A-1975. -

Class lE equipment will be qualified to meet its performance requirements by analysis, type testing, operating experience or any appropriate combination thereof. The qualification will be based upon the most severe environment predicted to occur prior to and during those portions of the specific accident transients for which the component is required to perform its safety function.

Where it is practical to do so, CRBRP Class IE systems are designed with redundant channels located in separate cells. Consequently, redundant safety equipment located in separate cells is not required to be qualified for Design Basis Events and/or accident conditions if the effects of the DBE's are not propagated to the redundant cells. However, all of these equipment items shall, as a minimum, satisfy the seismic and aging qualification requirements of this document. Where the use of identical components in the rame or more severe environments makes it possible to do so, component qualification data from licensed nuclear power plants will be utilized for qualification of CRBRP components.

The CRBRP qualification program described herein will meet the applicable re-y quirements of Regulatory Guide 1.89. However, the CRBRP qualification program will use the radiological source term (site suitability source term) to define the radiation environment for qualification only for the Class IE equipment required to function during and following the SSST release to mit-igate the consequences of the release. For all other Class IE equipment, the radiation environment for qualification will be defined by the enveloping DBE (excluding the SSST) for which the specific Class IE equipment must perform a safety function. The DBE will include pressure, temperature, humidity, chemical, vibration, and seismic effects as well as those of radiation.

The nominal life of the CRBRP is 30 years and, consequently, the " aging" l requirement of IEEE Std. 323-74 will be met by appropriate procedures based l on exposure to normal environment for a maximum of 30 years. The specific procedures to be used are described in Section 4.

Electrical equipment that is part of the thermal margin beyond the design I

basis (TMBDB) is not included in this document. For treatment of the l

qualification of this equipment, see SDD-27 and CRBRP - 3 Volume 2.

The scope of this document is limited to environment qualification of CRBRP Class IE equipment. Section 2 of this document describes normal and accident environments in the five buildings of the Nuclear Island and for emergency cooling towers, f3 1O l-1 l

l

3 Section 3 states the basis for enviromental qualification to all

significant environmental parameters and lists (in table 3-2) curves of accident parameter transients from Section 2 that apply to each specific piece of Class IE equipment. The equipment that is not subjected to severe environments as a result of the applicable design basis events is also listed (in table 3-1) with locations and maximum anticipated temperatures . Tables 3-1 and 3-2 also define the length of time the equipment must operate during and/or after the DBE. The equipment information contained in these tables is subject to correction or modification upon changes to the individual System Design Descriptions which establish the equipment requirements. All Class IE equipment will be qualified to the appropriate seismic acceleration for its location within the plant.

Section 4 describes type test qualification procedures for Class IE equipment not subjected to severe accident environments and qualification procedures for Class IE equipment that is subjected to severe accident environments. This Section also describes qualification by operating experience and analysis.

Section 5 and Appendix A set forth the content and suggested format for the preparation of Equipment Qualification Data Packages which will be prepared for each piece of equipment qualified by type test, operating experience or analysis.

The qualification program for active pumps and valves is presented in p]

\

WARD-D-0174 (Active Pump and Valve Operability Verification Plan).

Class IE electro-mechanical equipment subject to the requirements of WARD-D-0174 must also be qualified according to the requirements of this document. ,

A list of the references upon which this document is based is provided at the end of the text. A listing of acronyms is also provided.

m 1-2

2. ENVIRONMENTS O The environments to be considered in Class IE equipment qualification procedures are set forth in this section for normal operating conditions and for those design basis events in CRBRP that produce severe environments in cells that contain safety related equipment. Radiation doses resulting from release of the SSST are considered where appropriate. The numerical values of environment parameters specified in this section do not include the margins to be added per IEEE Std. 323-1974 for qualification. These margins have been added to produce the dotted curves in figures 2-1 to 2-9. Equipment specifications are to include the appropriate margins, the time interval during which the equipment must be capable of performing its safety function, and the applicable parameter transients from Section 2.

Seismic event parameters are considered in accordance with IEEE Std. 344-1975 (Reg. Guide 1.100) and WARD-D-0037. The seismic and vibration environments for each equipment item are defined'in each equipment end-item specification and, therefore are not presented in this section.

2.1 Nominal Environments Nominal environments in the buildings of the Nuclear Island are shown in Table 2-1.

\ 2.2 Accident Environments b For the purpose of qualification of Class IE equipment throughout CRBRP, the design basis events listed in the PSAR were reviewed and those which might produce significant enviromiental effects in each building were tabulated in Table 2-2. Study of the environmental parameter transients resulting from these events has shown which events produce the most severe transients and, therefore, which set of transients will serve as the basis for environmental qualification. The resultant transients are shown in Figures 2-1 through 2-9 in this section.

A DBE which produces changes in environmental parameters that are so small l or otherwise of such a nature that they do not change mechanical, electrical, physical or chemical properties of any Class IE equipment is considered to produce a non-severe environment. The alternative concept is also used. A DBE which produces changes in environmental parameters which may significantly change the properties of Class IE equipment is considered to produce a severe environment.

I V

2-1

Table 2-1 (v) ._

NOMINAL ENVIRONMENTAL CONDITIONS Nomal** 30 Year Average Equipment Temp. % RH Pressure Radiation op Dose RADS Reactor Containment Building Head Access Area 85 30% -k" W.G.

I&C Cubicles 75 30% -k" W.G. < 50 Operating Floor 100 30% -k" W.G. < 50 Inerted & RAPS Cells 120 N/A -k" W.G.

All Other Areas 95

30% -k" W.G.

Reactor Service Building Operating Floor 100 30% -k" W.G. < 50 Refueling Cormiunication Center 80 30% -k" W.G. < 50 Fuel Handling Cell Op. Gallery 80 30% -k" W.G. < 50 Inerted Cells 120 N/A 3/4"W.G.

All Other Areas 110 30% -k" W.G.

am Generator Buildin Intermediate Bay Na Cells 100 30% ATM Intermediate Bay All Other Areas 100 30% ATM Loop Cell Bays 100 30% ATM >< 50 Auxiliary Bay AFWP Cells 100 30% ATM Auxiliary Bay-All Other Areas 100 30% ATM ,

Diesel Generator Building

! Diesel Generator Room 105 30% ATM l All Other Areas 105 30% ATM g<50 Control Room Building Control Room 76 50% +k" W.G.

l I Control Room HVAC/ Filter Cells 100- 30% +k" W.G. , < 50 l Battery Rooms 95 30% ATM All Other Areas 105 30% ATM /

Emergency Cooling Tower Pump House 105 30% ATM 450 N/A = Not Applicable 1

l l r^?or normal radiation dose in 30 years for equipment in specific cells, refer to nomal i ( ladiation by area given on pages 7-190 to 7-201 of OPDD-10 and multiply area dose rate l ' vin MREM /HR by 250 to get equipment dose in RADS.

- Normal relative humidity range is 5 to 50 percent in all areas except the Control Room, which has a relative humidity of 50 percent continuous.

2-2

T f.

Table 2-2 -

DESIGN BASIS EVENTS WHICH MAY pts 0 DUCE SEVERE ENVIRONMENTS FOR CLASS lE EQUIPMENT I. Reactor Containment Building

1. Loss of off-site electrical power and failure of 1 diesel

2. Primary heat transport system pipe leak

3. Intermediate heat transport system pipe leak

4. Single fuel assembly cladding failure and subsequent fission gas release during refueling

5. Off-normal cover gas pressure in the reactor primary coolant boundary

6. Leakage from sodium cold traps

7. Maximum possible conventional fire

8. Primary sodium In-Containment storage tank failure during maintenance 9 Failure of ex-containment primary sodium storage tank

10. Safe Shutdown Earthquake

11. Maximum possible internal flood or water spray

12. RAPS surge tank failure (or high pressure pipe from surge vessel)

NOTE: The SSST release will produce a severe radiation environment for some of the electrical equipment which must function to mitigate the consequences of the SSST release.

II. Control Building

1. Intermediate heat transport system pipe leak

2. Maximum possible conventional fire

3. Safe Shutdown Earthquake

4. Maximum possible internal flood or water spray

5. RAPS surge tank failure (or high pressure pipe from surge vessel) 2-3

TABLE 2-2 N DESIGN BASIS EVENTS WHICH MAY PRODUCE SEVERE ENVIRONMENTS FOR CLASS lE EQUIPMENT III. Turbine Building None ( no safety related equipment )

IV. Steam Generator Building

1. Loss of off-site electrical power and failure of one diesel

2. Steam or feed-line pipebreak

3. Intermediate heat transport system pipe leak

4. Maximum possible conventional fires

5. Safe shutdown earthquake f

6. ~ Maximum possible internal flo6d and w'atsf ' spray

7. RAPS surge tank failure (or high pressure pipe from surge vessel)

V. Diesel Generator Building

1. Intermediate Heat Transport system pipe leak

2. Failure of RAPS / CAPS Cold Box (or high pressure pipe from surge vessel)

3. Maximum possible conventional fire

4. Safe shutdown earthquake

5. Maximum possible internal flood and water spray VI. Reactor Service Building

1. Loss of off-site electrical power and failure of I diesel

2. Intermediate heat transport system pipe leak

3. Single fuel assembly cladding failure and subsequent fission gas release during refueling

4. Cover gas release during refueling

( 5. Cover gas release during operation

6. Failed fuel element in FHC

7. Primary sodium in containment, storage tank failure during naintenance 2-4

TABLE 2-2 l DESIGN BASIS EVENTS WHICH MAY PRODUCE SEVERE ENVIRONMENTS l FOR CLASS lE EQUIPMENT l

8. Failure of ex-vessel sodium cooling system during operation j

9. Maximum possible conventional fire

10. Maximum possible internal flo'od and water spray .

l

-11. Safe shutdown earthquake

12. RAPS surge tank failure (or high pressure pipe from surge vessel) I

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FIGURE 21 RCB ATMOSPHERE TEMPERATURE TRANSIENT (RESULTING FROM PRIMARY Na TANK FAILURE DURING MAINTENANCE) 220 -

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WHEN THE SUSPENDED Nag 0 HAS SETTLED TO THE FLOOR AND PLATED ON THE VERTICAL SURFACES,THE FOLLOWING CONDITIONS WILL EXIST:

RCB VERTICAL SURFACES LAYER THICKNESS = .00231NCHES Na20 MASS PLATED =.00019 LES./IN2 Na20 T .00014 equiv.

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RCB HORIZONTAL SllRFACES Na LBS./IN2 ) R6 LAYER THICKNESS = .2 INCHES Na20 ( .012 equiv.

MASS SETTLED =.016 LBS./IN2 Na LBS./IN2 )

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E 1. In the actual environ nt, sodium will be

$ present as a mixture o. sodium oxide (Na20 ),

0; sodium peroxide (Na202) sodium hydroxide 8 10 (Na0H), sodium bicarbon e (NaHC03), and l

sodium carbonate (Na2CO3s-

2. Since analytical differen iation of the compounds present is totally impract cal, samples and surfaces should be analyzed for total sodium R6 content.

3. Users of the curve should con rvatively simulate the suspended aerosol - ncentrations.

10 After obtaining the specified mas settled, the generation of sodium aerosols be terminated.

4. The horizontal and vertical surface lay -

thickness assumes aero porosity of Na20 A

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i REACTOR COVER GAS ACTIVITY IS l i UNIFORMLY DISPERSED INSIDE THE 102" REACTOR CONTAINMENT.

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FIG U R E . 2-7 TEMPERATURE AFTER STEAM /

FEE 0 WATER LINE BREAK IN CELL 241 OR 242 OR 243' u .232 -

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CELLS 241,244,207 HAVE A COMMON ENVIRONMENT BECAUSE OF BLOWOUT PANELS CELLS 242,245,208 HAVE A COMMON ENVIRONMENT BECAUSE OF BLOWOUT PANELS CELLS 243,246,209 HAVE A COMMON ENVIRONMENT BECAUSE OF BLOWOUT PANELS l

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FIGURE 2-8 PRESSURE AFTER STEAM /

FEEDWATER LINE BREAK IN CELL 241 OR 242 OR 243*

PRESSURE TRANSIENT PLUS 10".0F GAGE (MARGIN)

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NOTE:

CELLS 241,244,207 HAVE A COMMON ENVIRONMENT BECAUSE OF BLOWOUT PANELS CELLS 242,245,208 HAVE A COMMON ENVIRONMENT BECAUSE OF BLOWOUT PANELS CELLS 243.246,209 HAVE A COMMON ENVIRONMENT BECAUSE OF BLOWOUT PANELS 4 78 P01321111 2-13

FIGURE ' 2-9

.2.2 X 10 4 - : DOSE RATE IN RS8 CELLS 352A AND 353A FOR

ENVELOPE 0F REACTOR COVER G AS RELEASE

DURING REFUELING AND FUEL ASSEMBLY FAILURE i IN RSB.

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l FIGURE ' 2-9 12 X 10 4 - : DOSE RATE IN RSB CELLS 352A AND 353A FOR j : ENVELOPE 0F REACTOR COVER G AS RELEASE

'u : DURING REFUELING AND FUEL ASSEMBLY FAILURE i'

IN RSB.

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3. QUAL.'IFICATION BASIS AND IMPLEMENTATION -

The qualification requirements presented herein are based on applicable

/m General Design Criteria (GDC), Regulatory Guides 1.73,1.89 (as applicable),

Q) IEEE 323-1974, and IEEE 344-1975.

Equipment not subjected to severe accident env ;nmelts is listed in Table 3-1 and qualification procedures for it are di- assed in paragraph 4.2.1.

Class lE equipment subjected to severe enviror. 2nts is listed in Table 3-2 and qualification procedures are discussed in paragraph 4.2.2.

3.1 Chemical Class lE equipment not subjected to chemical severe environments in CRBRP buildingsandintheemergencycoolingtowersmaygesubjectedtosodium aerosol concentrations up to and including 15 mg/m Na) suspended equivalent sodium peroxide and 0.1 g/m{8.85 mg/m3 equivalent (0.059 Na) deposited equivalent sodium peroxide as a result of sodium spills. This sodium aerosol environment is the result of a sodium spill in an IHTS cell being ingested by other CRBRP air filled cells. The resulting suspended sodium aerosol environment, a mixture of sodium peroxide (Na20 2), sodium oxide (Na20 ), sodium hydroxide (N OH),

a sodium bicarbonate (N aHC03 ), and sodium carbonate (Na2 CO 3 ) existing in varying proportions, leaves the building con-taining the spill via air exhaust ducting and is ingested by surrounding air filled buildings for 10 seconds,before the ingesting building air intake vent is isolated by closure of the air intake vent dampers. Before the dampers R6 close, the peak suspended sodium aerosol concentration reaches 8.85 mg/m3 equiv-

,m alent sodium. This 10 second ingestion of godium aerosols results in a uniform

/ horizontal surface deposition of 0.059 g/m c of equivalent sodium. Since ana-V) lytical differentiation of the ingested sodium compounds is totally impractical, the air and horizontal surfaces should be sampled and analyzed for total sodium content in order'to quantify the environment surrounding the equipment. Equip-ment subject to this environment must be qualified by any one or a combination of the methods specified in paragraph 4.1 in accordance with paragraph 4.2-1,

" Class lE Equipment Subjected to Non-Severe Accident Environments," while equipment subject to higher than 15 mg suspended and 0.1 g/m2 deposited sodium aerosol concentrations must be qualified in accordance with paragraph 4.2.2,

" Class lE Equipment Subject to Severe Accident Environments.

3.2 Temperature, Pressure, Humidity, Chemical Class lE equipment will be qualified to the enveloping transient with added margins per IEEE 323 for environmental parameters of temperature, pressure, humidity, and chemical. The margin for the chemical parameter shall be 10%.

Figure numbers for the enveloping transients of each parameter, as it applies to specific equipment, are listed in Table 3-2 and the figures are in Section

2. These parameters will be used in the development of the qualification envelope in accordance with the procedures set forth in Section 4.

3.3 -Radiation The Class lE equipment will be qualified to the worst case envelope (with IEEE Std. 323 margins) based upon normal service exposure plus the most v

3-1

3.3 Radiation (Continued) severe radiation environment predicted to occur prior to and during those V) portions of the specific accident transients for which the component is required to perform its safety function. Worst case accident parameters are shown in Table 3-2. These parameters will be used in the development of the qualification envelope as described in the procedures of Section 4. .

3.4 Vibration The vibration parameter will apply to a few sensors and transmitters which are located on mechanical devices which vibrate due to slight un-balances in rotating systems or on fluid lines which are subjected to vibration will be qualified to that environment per IEEE Std. 323-1974.

Worst case parameters are not shown on Table 3-1, but will be developed on an individual component basis dependent upon the component location. In those instances where vibration is significant, the amplitude and frequen-cy of the vibration will be provided in the equipment specification and the equipment will be qualified to acceleration 10% greater than that cal-culated or measured at the mounting point of the equipment. Those equip-ment items being qualified to the vibration environment will be identified in Tables 3-1 and 3-2.

3.5 Seismic Qualification to the seismic environment is to be carried out in accor-(N dance with IEEE Std. 344-1975, 323-1974 and WARD-D-0037. Worst case para-meters are not shown on Table 3-1 or Table 3-2, but will be developed on (V l an individual component basis dependent upon the component location.

Acceleration shall be increased by 10% for qualification per paragraph 6.3.1.5 of IEEE Std. 323-1974. Guidelines for seismic qualification of active valves and pumps are provided in WARD-D-0174. The horizontal and vertical acceleration for the safe shutdown earthquake (SSE) is specified in WARD-D-0037. These ground motions are translated to the component location as described in WARD-D-0037 and will be provided in the equipment l

specification for each item of Class lE equipment.

3.6 Periodic Pressure Test The reactor containment will be tested with an internal pressure of 11.5 psig cne time during containment acceptance tests. During its 30 year lifetime, it will be subjceted to nine additional tests at 10 psig per 10CFR50, Appendix J. It is required that lE equipment in containment re-main functional after the leak rate tests, otherwise the equipment must be removed during the tests. Analysis, previous operating experience and type testing are acceptable methods for demonstrating that the equipment will remain functional after the leak rate tests. If equipment testing is required, then the tests shall be performed after the equipment is aged.

l

[

v 3-2 l

O '

O O Equipment TABLE 3-1(2) Maximum Time Accident Number Description Cell Number (I) Duration Temp (op)

System 12 f

12 NIB 011A 480-120/208VAC Power Dist. Panel DGB521 30 Days 120 12 NIB 011B 480-120/208VAC Power Dist. Panel DGB524

12 NIB 012A 120/208VAC Power Dist. Panel RSB352A I 12 NIB 0128 RSB353A j 12 NIB 013A RSB314 12 NIB 013B RSB TBD R5 i y 12 NIB 020A SGB271 w

12 NIB 020B SGB TBD

12 NIB 021C SGB273 12 NIB 024A CB413 12 NIB 024B u CB412 l

Pri. Pump Under Voltage Sensors 455, 457 U 7 I

(1) Location of cell numbers within each building may be readily detennined from the General Arrangement 1

Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

O O '

Equipment TABLE 3-1(2) Maximum Time Accident Number Description Cell Number (I) Duration Temp (DF) _

System 12 12 NIB 201A 120/208VAC UPS Panel CB423 30 Days 120 1

12 NIB 201B CB446 j 12 NIB 201C CB459 12 NIB 202A RCB165 l

12 NIB 2028 RCB163

! 12 NIB 202C RCB167 R5 i

w 12 NIB 203A SGB272A l E

12 NIB 203B SGB262 12 NIB 203C SGB272C 12 NIB 204A CB423

12 NIB 204B CB446

)

i 12 NIB 204C I CB459 y U i

i l

l j

(1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

I (2) Identification of IE equipment and equipment location shall be under the change control of the

responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

a - - - ~ ~ - - - - - - - - - - - - ~ - - - ~ - - - -, - - - - - - - - -

O O

\

Equipment TABLE 3-1(2) Maximum Time Accident Number Description Cell Number (I) Duration Temp ( F)

I System 12

{ 12 NIB 401A 125V DC Panel CB421 30 Days 120 12 NIB 401B CB446

12 NIB 402A CB521 i

12 NIB 4028 CB524

12 NIB 403A RSB305F 1

12 NIB 403B RSB305E R5

) { 12 NIB 404A SGB271 l 12 NIB 4048 U SGB262

12 NIB 601A 480/277 Standby Lighting Panel RCB161A 12 NIB 601B RCB171 I 12 NIB 602A RSB325 12 NIB 602B RSB306A i

i 12 NIB 603A if SGB TBD 1! U l

! (1) location of cell numbers within each building may be readily determined from the General Arrangement

] Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

1

O O (2)

O

! Equipment Maximum i

Time Accident i

Number Description Cell Number (1) Duration Temp (OF) _

j System 12 l

l 12 NIB 603B 480/277 Standby Lighting Panel SGB TBD 30 Days 120

! 12 NIB 604A CB413 12 NIB 604B CB412

! 12 NIB 605A DGB521 12 NIB 605B U DGB525 i

12NIE003A 4.16KV SWGR DGB521 H5 i w l h 12NIE003B 4.16KV SWGR DGB524

! 12NIE005A 125V DC Bus CB454

! 12NIE005B 125V DC Bus CB460 12NIE005C 250V DC Bus CB459 12NIE008A 120/208V UPS Vital AC Bus CB454 i 12NIE0088 CB460 12NIE008C 4 CB459 y U I

1

(1) Location of cell numbers within each building may be readily detennined from the General Arrangement Drawing.

j (2) Identification of IE equipment and equipment location shall be under the change control of the

responsible system designing the component. Components which will be qualified to vibration

environments will be indicated on this table at a later date.

Eqpipment TABLE 3-1(2) Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF)

System 12 l

12NIE010A 125V DC Battery CB451 30 Days 120 12NIE010B 125V DC Battery -

CB458 l

12NIE010C 250V DC Battery CB453 12NIE012A 480VAC-125V DC Battery Charger CB454 12NIE012B CB460

! 12NIE012C CB454 y 12NIE0120 CB460 R5 12NIE012E CB459 12NIE012F y CB459 12NIE014A 125V DC-120/208VAC Vital Inverter CB463 12NIE014B CB454 12NIE014C 4 CB459 j 12NIE014D 250V DC-480V Vital AC Inverter CB459 12NIE016C Unit Substation CB460 y y i

(1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing .

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration i

. environments will be indicated on this table at a later date.

1

O O O Equipment E M(2) g,x;,y, Time Accident i Number Description Cell Number (I) Duration Temp (OF)

I j System 12 i

r

! 12NIE019A Diesel Gen. Control Panel A CB431 30 Days 120 12NIE019B Diesel Gen. Control Panel B - CB431 12NIE027A 4.16KV/480V Unit Substation DGB521 i 12NIE027B DGBS24 12NIE028A DGB521 R5 12NIE028B DGB524

)

w 12NIE032A RSB305E 12NIE0328 RSB305E 12NIE033A SGB TBD 12NIE033B U SGB247 12NIE040A 480V Motor Control Center DGB521 12NIE0408 DGB522

) 12NIE041A RSB306A 12NIE041B E RSB305B U P i

(1) location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the i responsible system designing the component. Components which will be qualified to vibration j environments will be indicated on this table at a later date.

O '

O O i Eqpipment TABLE 3-1(2) Maximum 1 Time Accident Number Description Cell Number (I) Duration Temp (OF) _

I System 12 I

i 12NIE042A 480V Motor Control Center CB413 30 Days 120 l 12NIE0428 CB412 12NIE044C SGB273 12NIE050A SGB271 R5 i 12NIE0508 SGB247 i

12NIE052A SGB271 w

tn 12NIE0528 SGB247 a.

I 12NIE058A RSB305F 12NIE0588 RSB305E 12NIE060A ECT 12NIE0608 U ECT l

. ~

12NIE102A DG Jacket Water Heater DGB TBD j 12NIE102B DG Jacket Water Heater DGB TBD y "

I i

i i (1) Location of cell numbers within each building may be readily determined from the General Arrangement

Drawing.

! (2) Identification of IE equipment and equipment location shall be under the change control of the i

responsible system designing the component. Components which will be qualified to vibration j environments will be indicated on this table at a later date.

4

,., - ~

(x

(

Equipment TABLE 3-1(2) g,xi,,,

Time Accident Number Description Cell Number (I) Duration Temp (DF) l, l System 12 12NIE104A DG Lube Oil Reserve Heater DGB TBD 30 Days 120 1

) 12NIE104B DG Lube Oil Reserve Heater DGB TBD 12NIE110A Exciter DG Field Flash DGB TBD

! 12NIE110B Exciter DG Field Flash DGB TBD

! 12NIE111A DG Seq. Logic Cab DGB522 R5 12NIE111B DG Seq. Logic Cab DGB523 i <f 12NIK001A Fuel Oil Transfer Pump DGB526 4 <n

12NIK001B DGB527 f 12NIK001C DGB526 12NIK001D M DGB527 i

l 12 NIX 011A 480-120/208VAC Power Dist. XFMR DGB521 i

! 12 NIX 011B DGB524 12 NIX 012A DGB521

! 12 NIX 012B U DGB524 U "

(1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

t l

O O O Eq'ipment 5-1(2) Maximum Time Accident l Number Description Cell Number (I) Duration Temp (OF) _

System 12 9

12 NIX 013A 480-120/208VAC Power Dist. XFMR RSB TBD 30 Days 120 12 NIX 013B RSB TBD 12 NIX 020A SGB TBD 12 NIX 020B SGB TBD

]

i

12 NIX 021C SGB TBD

} 12 NIX 024A CB413 R5 i

, 12 NIX 024B U CB412

! k 12 NIX 040A 480-120/208V Vital AC XFMR CB454 12 NIX 040B CB460 1 12 NIX 040C 'f CB459 12 NIX 601A 480/277V Lighting Panel XFMR RCB161A 12 NIX 6018 RCB171 12 NIX 602A RSB325 12 NIX 6028 7 RSB306A '

t y i

(1) location of cell numbers within each building may be readily detennined from the General Arrangement

, Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration i environments will be indicated on this table at a later date.

I I

O O O Equipment E 3-1(2) Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF)

System 12 12 NIX 603A 480/277V Lighting Panel XFMR SGB TBD 30 Days 120 12 NIX 603B SGB TBD 12 NIX 604A CB413 12 NIX 604B CB412 12 NIX 605A DGB521 12 NIX 605B U DGB525 R5 w 12SSB250A SSPLS Logic Cabinet SGB271 12SSB250B SGB247 12SSB251A SGB271 12SSG251B SGB247 12SSB350A RSB305F 12SSB350B RSB305E 12SSB351A RSB306A 12SSB351B 1r RSB305A P 1r (1) location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

O O O Eq ipment

~1(2) Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF)_

, System 12 l 12SSB550A SSPLS Logic Cabinet DGB521 30 Days 120 l

12SSB550B DGB524 12SSB551A DGB522

, 12SSB551B U DGB523 4

12TCB250A Termination Cabinet SGB271 RS 12TCB250B SGB247 y 12TCB251A SGB271 m ,

12TCB2518 SGB247 12TCB350A RSB305F 12TCB3508 RSB305E 12TCB351A RSB306A 1 12TCB351B RSB305A 12TCBS50A DGB521 12TCB550B " " "

, DGB524 4 (1) Location of cell numbers within each building may be readily detennined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the ,

i responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

2 O '

O s Equipment TABLE 3-1(2) Maximum i Time Accident l Number Description Cell Number (I) Duration Temp (OF)_

l System 12

, 12TCB551A Termination Cabinet DGB522 30 Days 120

, R5 12TCB5518 Tennination Cabinet DGB523 30 Days 120 l

1 i

i

w

)

i k

i i

l l

i n

) (1) Location of cell numbers within each building may be readily detennined from the General Arrangement

Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the i responsible system designing the component. Components which will be qualified to vibration

) environments will be indicated on this table at a later date.

l

O h O G O Equipment

~1(2) Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF)

System 23 23ECNV353 & S0V353 Iso. Af ter Wtr. Leak Val . (0perator) 152 30 Days 120 23ECNV354 & S0V354 Iso. After Wtr. Leak Val. (0perator) 152 23ECNV400 & S0V400 Iso. Af ter Wtr. Leak Val . (Operator) 154 23ECNV401 & S0V401 Iso. Af ter Wtr. Leak Val . (0perator) 154 23ECP002A Emergency Chilled Water Pump Motor 216 RS 23ECP002B Emergency Chilled Water Pump Motor 217 23ECPCV17A Pressure Control Valve (Operator) 216 23ECPCV178 Pressure Control Valve (Operator) 217 TE9AA & TE9BA Chiller Outlet Temperature RDT 216 & 217 PDISH12A & B Chillei Diff. Pressure Switch 216 & 217 FSL20AA & FSL20BA Nonnal Chilled Wtr Low Flow Switch 271 & 262 FIT 36A & B Emergency Chilled Water Flow 216 & 217 LSLL41A & B Emerg. Exp. Tnk. Low Level Switch 216 & 217 23ECTV210 Temp. Control Valve (Operator) 262 23ECTV218A Temp. Control Valve (Operator) 272A y 1 (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

bi (O./ V V (2)

Equipment Maximum i Time Accident Number Description Cell Number (I) Dura tion Temp (OF) _

System 23 23ECTV2188 Temp. Control Valve (0perator) 2728 30 Days 120 23ECTV218C Temp. Control Valve (0perator)' 277C

23ECH001A Emerg. Chilled Water Chiller 216 23ECH001B Emerg. Chilled Water Chiller 217 23ECTV355 Temp. Control Valve (Operator) 271 23ECTV402 Temp. Control Valve (0perator) 271 RS 23ECA0V304A & S0V304A Unit Cooler Iso. Valve (Operator) 216 23ECA0V304B & S0V304B Unit Cooler Iso. Valve (0perator) 217 23ECA0V350 & S0V350 Unit Cooler Iso. Valve (Operator) 2048 23ECA0V351 & S0V351 Unit Cooler Iso. Valve (Operator) 202B 23ECA0V352 & S0V352 Unit Cooler Iso. Valve (0perator) 204A 23ECA0V356 & S0V356 Unit Cooler Iso. Valve (Operator) 202 23ECPSV42 Pressure Relief Valve (Operator) 216 23ECPSV43 Pressure Relief Valve (0perator) 217 U U, (1) location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

'~'N V U('] d Equipment

. TABLE 3-1(2) Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF)

Sys tem 23 4 23ECA0V13A & S0V13A EC Sys. Iso. Valve (Operator) 216 30 Days 120 23ECA0V13B & S0V13B EC Sys. Iso. Valve (Operator)' 217 23ECA0V18A & S0V18A EC Sys. Iso. Valve (0perator) 271 23ECA0V18B & S0V18B EC Sys. Iso. Valve (0perator) 262 23ECA0V19A & S0V19A 271 23ECA0V19B & S0V198 262 23ECA0V21A & S0V21A 216 R5 7

23ECA0V21B & S0V21B 217 23ECA0V22A & S0V22A 271 23ECA0V22B & SOV22B 262 23ECA0V23A & S0V23A 271 23ECA0V238 & S0V238 U 262 23ECA0V165 & S0V165 Containment Iso. (Valve Operator) 210 23ECA0V166 & S0V166 H 210 y u (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the i responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

l O O O Equipment TABLE 3-1(2) Maximum l

. Time Accident l Number Description Cell Number II) Duration Temp (DF) l System 23 l 23ECA0V167 & SOV167 Containment Iso. (Valve Operator) 271 30 Days 120 i, 23ECA0V168 & S0V168 271

! 23ECA0V211 & S0V211 262 I

23ECA0V212 & S0V212 262 23ECA0V79 & S0V79 210 23ECA0V80 & S0V80 210 R5 m 23ECA0V415 & S0V415 271 23ECA0V418 & S0V418 U 271 23ECPSV152A Pressure Relief Valve 321 l 23ECPSV152B Pressure Relief Valve 322

{ 23ECNV403 & S0V403 Iso. After Wtr Lk. Val . (Operator) 325

! 23ECNV404 & S0V404 325 i

I 23ECNV409 & SOV409 306A 23ECNV410 & S0V410 V 306A U. r .

i (1) Location of cell numbers within each building may be readily determined from the General Arrangement i Orawing.

I (2) Identification of IE equipment and equipment location shall be under the change control of the

responsible system designing the component. Components which will be qualified to vibration

environments will be indicated on this table at a later date.

p p rs Equipment TABLE 3-1(2) Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF) _

System 23 23ECTV408 Temp. Control Valve (Operator) 327 30 Days 120 23ECTV204A 359 4 23ECTV204B 391 23ECTV209A 398 23ECTV2098 y 395 23ECPCV181 Pressure Control Valve (Operator) 392 R5

, 23ECPCV182 Pressure Control Valve (Operator) 324 h 23ECW300 Temp. Control Valve (Operator) 412 23ECTV301 413 23ECTV302 410A

23EClV303 y 411A 23ICB001 Chilled Wtr. Sys. Cont. Cabinet CB431 23ICB003 Field Instrument Cabinet SGB216 23ICB004 Field Instrument Cabinet SGB217 Y Y (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

i (2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration 4

environments will be indicated on this table at a later date.

P l

O O O Equipment TABLE 3-1(2) Maximum l Time Accident l Number Description Cell Number (I) Duration Temp (OF) _

i System 23 23ICB007 Field Instrument Cabinet RSB314 30 Days 120

23ICB008 Field Instrument Cabinet RSB314 R5 23ICB015 Equipment Instrument Cabinet SGB216 23ICB016 Equipment Instrument Cabinet SGB217 y 'T I

i Y

l W 1

j 4

i I

s

} (1) location of cell numbers within each building may be readily determined from the General Arrangement ~

i Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the

, responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

1

O (2)

O O I

Equipment Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF) __

, System 25A 25 ARK 021 EI&C Cubicle Unit Cooler Motor 165 30 Days 120 25 ARK 022 EI&C Cubicle Unit Cooler Motor 163 25 ARK 023 EI&C Cubicle Unit Cooler Motor 167 25 AGK 223A Emerg. Chillers Unit Cooler Motor 216 25 AGK 223B Emerg. Chillers Unit Cooler Motor 217 25 AGK 244A & Intermediate Bay Supply Fan Motors 262 R5 w 25 AGK 244B

25 AGK 237A Sys. 56 Panel Unit Cooler Motor 272A l 25 AGK 237B Sys. 56 Panel Unit Cooler Motor 272B 25 AGK 237C Sys. 56 Panel Unit Cooler Motor 272C 25 AGK 249A & Intermediate Bay Supply Fan Motors 271 25 AGK 249B i 25 AGK 264A & Intennediate Bay Exh. Fan Motors 262

! 25 AGK 264B j 25 AGK 267A & Intennediate Bay Exh. Fan Motors 271 4 25 AGK 267B 25 AGK 222A Aux. Feed Pump Unit Cooler Motor 202 i7 'f (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration

environments will be indicated on this table at.a later date. <

p p n ,

d b U Equipment TABLE 3-1(2) Maximum Time Accident Number Description Cell Number II) Duration Temp (OF )

System 25A 25 AGK 222B Aux. Feed Pump Unit Cooler Motor 202B 30 Days 120 25 AGK 241 A&B Loop 1 Supply Fan Motor -244 i 25 AGK 242 A&B Loop 2 Supply Fan Motor 245 l 25 AGK 243 A&B Loop 3 Supply Fan Motor 246 25 AGK 261 A&B Loop 1 Exhaust Fan Motor 244 25 AGK 262 A&B Loop 2 Exhaust Fan Motor 245 R5 25 AGK 263 A&B Loop 3 Exhaust Fan Motor 246 E 25 AGK 221A Aux. Feed Pump Unit Cooler Motor 204A 25 AGK 221B Aux'. Feed Pump Unit Cooler Motor 204B t

25 ASK 104A ABHX Cell Unit Cooler Motor 327 25 ASK 104B ABHX Cell Unit Cooler Motor 326 i

i 25 ARK 172A Annulus Press. Maint. Fan Motor 395 25 ARK 173A RCB Annulus Fltr. Fan Motor 395 25 ARK 172B Annulus Press. Maint. Fan Motor 398 Y V (1) Location of cell numbers within each building may be readily determined from the General Arrangement i Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

l Equipment

. TABLE 3-1(2) Maximum Time Accident I Number Description Cell Number (I) Duration Temp (OF) _

System 25A 25 ARK 1738 RCB Annulus F1tr. Fan Motor 398 30 Days 120 r 25 ASK 132 Annulus Fltr. Cell Unit Cooler Mtr. 398 I

25 ARK 174A Annulus Cooling Fan Motor 392 25 ARK 174B 25 ARK 174C l 25 ARK 174D . R5 I

! y 25 ARK 175E i C 1 25 ARK 175F y if 25 ACK 441A Control Room F1tr Unit Fan Motor 410B 25 ACK 441B y 4118 25 ACK 451A Control Room Return Fan Motor 410A 25 ACK 4518 Control Room Return Fan Motor 411A 25 ACK 452 SWGR Return Fan A Mocor 413 25 ACK 453 SWGR Return Fan B Motor 412 If T 4

(1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing. '

l (2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

O O O Equipment TABLE 3-1(2) Maximum Time Accident I

Number Description Cell Number (1) Duration Temp (OF) _

i System 25A j 25 ACK 461 Battery #1 Room Exh. Fan Motor 412 30 Days 120 25 ACK 462 Battery #2 Room Exh. Fan Motor 413 25 ACK 463 Battery #3 Room Exh. Fan Motor 413 25 ACK 464 Battery Room Exhaust Fan Motor 412 f 25 ACK 410A Control Room A/C Unit Motor 410A i 25 ACK 410B Control Room A/C Unit Motor 411A .

25 ACK 411 SWGR A/C Unit A Motor 413 R5 25 ACK 412 SWGR A/C Unit B Motor 412 25 ARK 175A Cleanup Scrub Fan Motor 359 25 ARK 175B Cleanup Scrub Fan Motor 347 25 ARA 182A Annulus Filter Unit 395 l 25 ARA 182B Annulus Filter Unit 398

! 25 ASA 184A RSB Cleanup Filter Unit 391 25 ASA 1848 RSB Cleanup Filter Unit 347 y 7 1

)

! (1) Location of cell numbers within each building may be readily detennined from the' General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the i responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

O O (2)

O Equipment Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF) __

System 25A i l

25 ASA 185A C1eanup Fi1ter Fan Motor 391 30 Days 120 25 ASA 185B Cleanup Filter Fan Motor 347 25 ASK 146 Annulus Fitr Cell Unit Cooler Mtr. 395 25 ASK 133 RSB Cleanup Fitr. Cell Unit Cooler 391 Motor 25 ASK 134 RSB Cleanup Fltr Cell Unit Cooler 347 l Motor y 25 ASK 139A Containment Cleanup Pump Cell 305I g Unit Cooler Motor R5 a i 25 ASK 139B Containment Cleanup Pump Cell 305G Unit Cooler Motor 25 ASK 142 A&B Containment Cleanup Scrubber 359 Unit Cooler Motor 25 ASK 143 Containment Cleanup Pipe Chase 348 Unit Cooler Motor 25 ASK 145 Containment Cleanup Pipe Chase 349 Unit Cooler Motor 25 ASK 137 Electrical Equipment Cel1 Unit 305E Y V Cooler Motor (1) Location of cell numbers within each building may be readily detennined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

O Equipment Maximum 1 Time Accident

. Number Description Cell Number (I) Duration Temp (OF)

System 25A

, 25 ASK 138 Electrical Equipment Cell Unit 305F 30 Days 120 Cooler Motor j 25 ACA 471A Control Room Filter Unit (Heating CB410B R5

Coil, Instrumentation) 25 ACA 471B Control Room Filter Unit (Heating CB411B U U

! Coil Instrumentation)

Y M

er I

i (1) Location of cell nunbers within each building may be readily determined from the General Arrangement Drawing.

l (2) Identification of IE equipment and equipment location shall be under the change control of the

! responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

o ~ '

o (2) o

Equipment Maximum Time Accident Number Description Cell Number (1) Duration Temp (OF) 4 Sys tem 26 26SPB015 Zone Indicating Panel 431 30 Days 120 R5 26SDAE135A,B,C Aerosol Rel. Det. SGB Loop'l 244 120

136A,B.C 1 244 245A,B.C 2 245 R6 246A,B.C 2 245 335A,0,C 3 246

$ 336A,B.C '

f 3 246 9 y W

3 l

l 1

i (1) location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the

responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date. ,

\

b,)

'wd N 2

Equipment TABLF 3-1(._)

Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF)

System 27 l 271CB003(3) RCB TMBDB Instrumentation Panel 247 600 hours0.00694 days 0.167 hours 9.920635e-4 weeks 2.283e-4 months i RCB Hydrogen Channel A 500 hours0.00579 days 0.139 hours 8.267196e-4 weeks 1.9025e-4 months j RCB Temperature Channel A 500 hours0.00579 days 0.139 hours 8.267196e-4 weeks 1.9025e-4 months j CV Temperature Channel A 27ICB004(3) RCB TMBDB Instrumentation Panel 271 600 hours0.00694 days 0.167 hours 9.920635e-4 weeks 2.283e-4 months RCB Hydrogen Channel B 500 hours0.00579 days 0.139 hours 8.267196e-4 weeks 1.9025e-4 months RCB Temperature Channel B 500 hours0.00579 days 0.139 hours 8.267196e-4 weeks 1.9025e-4 months CV Temperature Channel B 27ICB002( Containment Instrumentation Panel 431 600 hours0.00694 days 0.167 hours 9.920635e-4 weeks 2.283e-4 months RCB Hydrogen Channel A '

500 hours0.00579 days 0.139 hours 8.267196e-4 weeks 1.9025e-4 months RCB Pressure Channel A 500 hours0.00579 days 0.139 hours 8.267196e-4 weeks 1.9025e-4 months

{ h RCB Temperature Channel A 500 hours0.00579 days 0.139 hours 8.267196e-4 weeks 1.9025e-4 months ,

CV Temperature Channel A

{

27ICB005(3) Containment Instrumentation Panel 431 600 hours0.00694 days 0.167 hours 9.920635e-4 weeks 2.283e-4 months RCB Hydrogen Channel B 500 hours0.00579 days 0.139 hours 8.267196e-4 weeks 1.9025e-4 months RCB Pressure Channel B 500 hours0.00579 days 0.139 hours 8.267196e-4 weeks 1.9025e-4 months CV Temperature Channel B 500 hours0.00579 days 0.139 hours 8.267196e-4 weeks 1.9025e-4 months i

i (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change con. trol of the responsible system designing the component. Components which will be qualified to vibration i environments will be indicated on this table at a later date.

{ (3) Although the instrument is located in non-severe environment, the environment monitored is '

described by Figures 2-1 through 2-4. The instrument must be capable of monitoring that range of parameters.

1

- - - - - a

1 N v Equipment Maximum Time Accident Number Description Cell Number (1) Duration Temp (OF) _

, System 28 28MAB001 Local Control Panel 105H 30 Days 120 j 28MBB001 Local Control Panel 105Z 28EATE10 Cell Temperature Switch 360 28EBK001 Fan Motor 306A 28EBMV001A Solenoid Drain Valve 306A 28EBMV001B Solenoid Drain Valve 306A m 28EBS0V001A Solenoid Val for Pneumatic Iso Val 306A R5 28EBS0V001B Solenoid Val for Pneumatic Iso Val 306A 28EBME1 Moisture Switch 306A 28EBNE1 Liquid Level Switch 306A 28EAB001 Subsys. EA Field Instr. Panel RSB325 28 EBB 001 Subsys. EB Field Instr. Panel RSB306A 28EAB001 Subsys. MA Field Instr. Panel RCB105L 28 EBB 001 Subsys. MB Field Instr. Panel RCB105Z U U (1) Location of cell numbers within each building may be readily determined from the General Arrangement

Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

O O (2)

O Equipment Maximum Time Accident 1 Number Description Cell Number (I) Duration Temp (OF) l System 28 28ICB001 Recirc. Gas Cooling Control Panel CB431 30 Days ~120 l 28EBTE12 Cell Temp. Switch 357 28MAK001 Fan Motor 105H

{

28MAMV001A Solenoid Drain Valve 105H

28MAMV001B Solenoid Drain Valve 105H 28 MAS 0V001A Solenoid Val for Pneumatic Iso Val 105H 28 MAS 0V001B Solenoid Val for Pneumatic Iso Val 105H R5 3 28MAME1 Moisture Switch 105H 28 MANE 1 Liquid Level Switch 105H 28 MATE 10 Cell Temperature Switch 103 28MBK001 Fan Motor 105H 28MBMV001A Solenoid Drain Valve 105Z 28MBMV001B Solenoid Drain Valve 105Z 28MBS0V001A Solenoid Val for Pneumatic Iso Val 105Z U U (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment a.nd equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

O O O Equipment TABLE 3-1(2) Maximum Time Accident Number Description Cell Number (1) Duration Temp (OF) i System 28 28MBS0V001B Solenoid Val for Pneumatic Iso Val 105Z 30 Days 120 28MBME1 Moisture Switch 105Z 28MBNE1 Liquid Switch 105Z 28MBTE10 Cell Temperature Switch 104 28FHMEIA Moisture Switch 342 28FHMElB Moisture Switch 343 28FHNE1A Liquid Level Switch 342 R5 y 28FHNElB Liquid Level Switch 343 28EAK001 Fan Motor 325 28EAMV001A Solenoid Drain Valve 325 28EAMV001B Solenoid Drain Valve 325 j 28EAS0V001A Solenoid Val for Pneumatic Iso Val 325 28EAS0V001B Solenoid Val for Pneumatic Iso Val 325 i 28EAME1 Moisture Switch 325 28EANE1 Liquid Level Switch 325 Y 4 (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

i O O O Equipment TABLE 3-1(2) .

Max 1 mum Time Accident Number Description Cell Number (1) Duration Temp (OF) j System 31 31SDR003 Solenoid Scram Valves--subassem- 151 30 Days 340 blies of the six Secondary Control RS

, Rod Drive Mechanisms (SCRDMs);

j three solenoids per SCRDM.

i i

$O N

o i

i l

l i

1 i

(1) location of cell numbers within each building may be readily determined from the General-Arrangement

! Drawing.

I (2) Identification of IE equipment and equipment location shall be under the change control of the i responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

I

l i

- O O TABLE 3-1(2)

! Equipment Maximum i Time Accident l Number Description Cell Number (I) Duration Temp (OF)

System 32 Cable serving System 90 SCRDM 151 30 Days 130 SCRAM Valves and System 96 Radiation Monitors -

l Cable serving System 92 Reactor 151 30 Days 220 i Coolant Operating Level Sensors t

1

't'

, 5: .

! CL i

i i

4 i

i l

l i

(1) Location of cell numbers within each building may be readily determined from the General Arrangement l Drawing.

1 (2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

l s

]

l Equipment TABLE 3-1(2) Maximum Time Accident i Number Description Cell Number (I) Duration Temp (OF) i System 44 44SRHV033A Containment (Iso Valve Operator) 305C 30 Days 120 R5 j 445RHV069B Containment (Iso Valve Operator) 305C 30 Days 120 I

l i

i 1

1 i

u>

b; 4

i i

l (1) Location of cell numbers within each building may be readily determined from the General Arrangement j Drawing.

, (2) Identification of IE equipment and equipment location shall be under the change control of the l responsible system designing the component. Components which will be qualified to vibration 4

environments will be indicated on this table at a later date.

I

(2)

~'

Equipment Maximum Time Accident Number Description . Cell Number (1) Duration Temp (OF)

System 52 i

1 52ACH001A, B, C Air Cooled Condenser 281,282,283 30 Days 125 R5 52AFK001A, 8 AFW Pump Motor 204A,204B 30 Days (5) 120 52AFN001 AFW Pump Drive Turbine (4) 202A 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months 52 AFT 001 (3) Water Storage Tank 215 30 Days 52AFD001A-F (3) AFW Flow Meter 202,206 i 52ACD002A,B,C(3) PACC Condensate Flow Meter 241,242,243 y 52AFV103A-F AFW Iso. Valve (Operator) 202,206 52AFV104A-F AFW Control Valve (0perator) 202,206

52AFV108A, B, C AFW Pump Recirc. Val. (0perator) 202,204

52AFV109A, B AFW Pump Inlet Valve Operator 215

52AFV110A, B AFW Pump Alternate Inlet Val (Oper 215 52AFV114 PWST Fill Valve (Operator) 215 U U (1) location of cell numbers within each building may be readily detennined from the General Arrangement Drawing .

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

(3) Instrumentation only.

(4) Including Governor Valve and Trip and Throttle Valve.

(5) The Pump motors will be on, intennittently, for no more than 20 hours2.314815e-4 days 0.00556 hours 3.306878e-5 weeks 7.61e-6 months total during the 30 day period.

)

( 0

(

2 Equipment TABLE 3-1(_ ) Maximum Time Accident Number Description , Cell Number (I) Duration Temp (OF)

System 52 52AFV115 Alternate AFW Supply Val (Operator) 242 30 Days 120 52AFV116A, B, C Superheater Vent Cont. Val (0per.) 241,242,243 11 hours1.273148e-4 days 0.00306 hours 1.818783e-5 weeks 4.1855e-6 months f

52AFV117A, B, C Steam Drum Vent Cont. Val (0per.) 241,242,243 11 hours1.273148e-4 days 0.00306 hours 1.818783e-5 weeks 4.1855e-6 months 52AFV118A, B, C Drive Turbine Steam Supply Iso. 241,242,243 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months Valve (Operator) 52AFV121 Drive Turbine Pressure Control 202 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months Valve (Operator)

[ 52AFV122 AFW Pump Inlet Valve (Operator) 215 30 Days

?

52AFV123 AFW Pump Alternate Inlet Val (Oper) 215 30 Days u

52ACV129A-F PACC Noncondensible Vent Val (Oper) 281,282,283 30 Days 125 R5 i

(1) Location of cell numbers within each building may be readily determined from the General A' rangement r Drawing. '

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

(3) Instrumentation only.

(4) Including Governor Valve and Trip and Throttle Valve.

(5) The Pump motors will be on, intennittently, for no more than 20 hours2.314815e-4 days 0.00556 hours 3.306878e-5 weeks 7.61e-6 months total during the 30 day period.

O O (2)

O Equipment Maximum Time Accident Number Description Cell Number (1) Duration Temp (OF) _

System 56 I

56HRB110A SGAHRS I&C Panel, Division I SGB272A 30 Days 120 56HRB110B SGAHRS I&C Panel, Division II- SGB2728 30 Days 56HRB110C SGAHRS I&C Panel, Division III SGB272C 30 Days q

56PRB111AP PHTS Primary PPS Panel, Channel A RCB165 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months

, 56PRB111BP PHTS Primary PPS Panel, Channel B RCB163 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months 56PRB111CP PHTS Primary PPS Panel, Channel C RCB167 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months R5 56PRB111AS PHTS Secondary PPS Panel, Channel A RCB165 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months G 56PRB111BS PHTS Secondary PPS Panel Channel B RCB163 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months 56PRB111CS PHTS Secondary PPS Panel, Channel C RCB167 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months 56SGB100A SGS/SGAHRS Logic Cabinet',Div. I MCB431 30 Days 56SGB100B SGS/SGAHRS Logic Cabinet,Div. II MCB431 30 Days 56SGB100C SGS/SGAHRS Logic Cabinet,Div. III MCB431 30 Days ,

j 56SGB001A OSIS I&C Panel, Loop 1 SGB272A 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months 56SGB001B OSIS I&C Panel, Loop 2 SGB272B 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months 56SGB001C OSIS I&C Panel, Loop 3 SGB272C 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months U i

(1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration '

environments will be indicated on this table at a later date.

i

O O O Equipment Maximum Time Accident Number Description Cell Number (1) Duration Temp (OF)

System 56 56SGB002A SWRPRS I&C Panel, Loop 1 SGB272A 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months 120 56SGB002B SWRPRS I&C Panel, Loop 2 -

SGB2728 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months 56SGB002C SWRPRS I&C Panel, Loop 3 SGB272C 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months 56HRPT228 Motor Driven AFW Pump "A" Outlet SGB204A 30 Days Pressure Transmitter 56HRPT328 Motor Driven AFW Pump "B" Outlet SGB204B 30 Days Pressure Transmitter w 56HRPT128 Turbine Driven Pump SGB202A 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months

,L 56HRPT125 Pump Outlet Pressure Transmitter SGB202A 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months R5

Steam Supply Pressure Transmitter 56 SIT 120 SGB202A 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months Pump Tachometer 56HRTE002 PWST Temperature Sensor and Level SGB215 30 Days 56HRLT103 Transmitter SGB215 30 Days 56HRFT138 AFW (Turbine Driven Pump) SGB202A 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months 56HRFT138B Flow Transmitters, Loop 1 SGB202A 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months 56HRFT238 AFW (Turbine Driven Pump) SGB206 , I hour 56HRFT2388 Flow Transmitters, Loop 2 SGB206 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months 56HRFT338 AFW (Turbine Driven Pump) SGB206 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months 56HRFT3388 Flow Transmitters, Loop 3 SGB206 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months U (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

O O O Equipment Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF)

System 56 56HRFT132 AFW (Motor Driven Pumps) SGB202A 30 Days 120 56HRFT1328 Flow Transmitters, Loop 1 SGB202A 30 Days 56HRFT232 AFW (Motor Driven Pumps) SGB206 30 Days 56HRST232B Flow Transmitters, Loop 2 SGB206 56HRFT332 AFW (Motor Driven Pumps) SGB206 56HRFT332B Flow Transmitters, Loop 3 SGB206 56HRXE100A PACC System Na Aerosol Detectors, SGB281 <

56HRXE100B Loop 1 SGB281 y 56HRXE100C SGB281 h 56HRXE200A PACC System Na Aerosol Detectors, SGB282 R5 56HRXE200B Loop 2 SGB282 56HRXE200C SGB282 56HRXE300A PACC System Na Aerosol Detectors, SGB283 5611RXE300B Loop 3 SGB283 56HRXE300C SGB283 g 56PRPT124AP Reactor Inlet Pressure RCB101C 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months 150 56PRPT125AP Transmitters, Loop 1 RCB101C 56PRPT224BP Reactor Inlet Pressure RCB101D 56PRPT225BP Transmitters, Loop 2 RCB101D 56PRPT324BP Reactor Inlet Pressure RCB101E 56PRPT325CP Transmitters, Loop 3 RCB101E y V (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

O O O Equipment Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF )

System 56 56PRTE128A IXil Outlet Temperature RCB121 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months 150 56PRTE128B Sensors, Loop 1, Channels A, B, C RCB121 56PRTE128C RCB121 56PRTE228A IXH Outlet Temperature RCB122 56PRTE228B Sensors, Loop 2, Channels A, B, C RCB122 56PRTE228C RCB122 56PRTE328A IXH Outlet Temperature RCB123 56PRTE328B Sensors, Loop 3, Channels A, B, C RCB123 56PRTE328C RCB123 w 56PRFE125AS PHTS Sodium PM Flowmeter Sensors, RCB101C

.L 56PRFE125BS Loop 1, Channels A, B, C RCB101C R5

@ 56PRFE125CS 56PRFE225AS PHTS Sodium PM Flowmeter Sensors, RCB1010 56PRFE225BS Loop 2, Channels A, B, C RCB101D 56PRFE225CS RCB101D 56PRFE325AS PHTS Sodium PM Flowmeter Sensors, RCB101E 56PRFE325BS Loop 3 Channels A, B, C RCB101E 56PRFE325CS RCB101E 56PRTE129A, B PHTS Sodium Pump Outlet RCB121 56PRTE130A, B Temperature Sensors, Loop 1 RCB121 56PRTE229A, B PHTS Sodium Pump Outlet RCB122 56PRTE230A, B Temperature Sensors, Loop 2 RCB122 If If (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

1

^

(C) (~')

( (~)

v Equipment Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF )

System 56 56PRTE329A, B PHTS Sodium Pump Outlet RCB123 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months 150 56PRTE330A, B Temperature Sensors, Loop 3 RCB123 150 56ItiTE128AS Evaporator (Sodium) Outlet SGB227 120 561NTE128BS Temperature Sensors, Loop 1, SGB227 56If1TE128CS Channels A, B, C SGB227 56INTE228AS Evaporator (Sodium) Outlet SGB228 56If1TE228BS Temperature Sensors, Loop 2, SGB228 561NTE228CS Channels A, B, C SGB228 l

i 56INTE328AS Evaporator (Sodium) Outlet SGB229 R5

. , 56INTE328BS Temperature Sensors, Loop 3, SGB229 l

4 56INTE328CS Channels A, B, C SGB229 56INFE125AS IHTS PM Flowmeter Sensors, Loop 1, SGB227 56INFE125BS Channels A, B, C SGB227 56INFE125CS SGB227 561NFE225AS IHTS PM Flowmeter Sensors, Loop 2, SGB228 561NFE225BS Channels A, B, C SGB228 561NFE225CS SGB228 561NFE325AS IHTS PM Flowmeter Sensors, Loop 3, SGB230 561NFE325BS Channels A, B, C SGB230 56INFE325CS V

56 PRE 101A, B, C PHTS DR. PPS Breakers DGB530 48 hours5.555556e-4 days 0.0133 hours 7.936508e-5 weeks 1.8264e-5 months U thru 104A, B, C (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the i responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

I

Equipment TABLE 3-1(2) Maximum Time Accident tbmber Description Cell Number (I) Duration Temp (OF)

System 56 i

561NE101A, B, C IHTS DR. PPS Breakers DGB530 48 hours5.555556e-4 days 0.0133 hours 7.936508e-5 weeks 1.8264e-5 months 120

) thru 104A, B, C DGB530 48 hours5.555556e-4 days 0.0133 hours 7.936508e-5 weeks 1.8264e-5 months l 561NK201A, B, C IHTS Na Pump Pony Motors SGB244, 245, 30 Days

246 R5 i

f 56 INK 112A, B, C IHTS Na Pump Drive ARD Bearing SGB244, 245, 30 Days j Fan Motor 246 i

56 INST 103AP, BP, IHTS Na Pump Tachometers SGB244, 245 24 hours2.777778e-4 days 0.00667 hours 3.968254e-5 weeks 9.132e-6 months U

CP thru 303AP, 246 BP, CP

't' 5;

o.

i t

t (1) Location of cell numbers within each building may be readily detennined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

j

q (w

Equipment TABLE 3-1(2) Maximum j Time Accident

! Number Description Cell Number (1) Duration Temp (OF) _

System 75 i

75EPK001A EPSW Pump Motor ECT 30 Days 120 75EPK001B EPSW Pump Motor -

75EPK002A ECT Fan Motor 75EPK002B i

75EPK002C R5 i 75EPK002D i

75EPK002E U 75EPK002F 1r 75EPK003A EPSW Makeup Pump Motor

! 75EPK003B EPSW Makeup Pump Motor 75EPTV67AA Temp. Control Valve (0perator) 75EPTV67AB j

75EPTV67BB 75EPTV67BA 1r 17 y 1r

~

(1) Location of cell numbers within each building may be readily detennined from the General Arrangement Drawing.

l (2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration t environments will be indicated on this table at a later date.

4

( ( O V

Equipment TABLE 3-1(2) Maximum 4 Time Accident i Number Description Cell Number (I) Duration Temp (OF)

System 75 75EPTT67A Temperature Transmitter DGB513 30 nays 120 75EPTT678 Temperature Transmitter DGB525 75EPTIC67A Temperature Indicator Controller DGB513 ll 75EPTIC678 Temperature Indicator Controller DGB525 R5

) 75EPDDISH92A Pressure Differential Switch High SGB216 i

75EPPDISH928 Pressure Differential Switch High SGB217 w 75EPLSL70A Level Switch Low ECT

L l 8 75EPLSL70B Level Switch Low ECT If If 1

i i

(1) location of cell numbers within each building may be readily determined from the General Arrangement

! Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration l environments will be indicated on this table at a later date.

O O O (2)

Equipment Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF)

System 81 81PPHV131 Val. (0per.) Makeup Pump Drain Tnk 1078 30 Days 150 81PPHV135 Val . (Oper.), Cold Trap A Outlet 157D 1

Val . (Oper.), Cold Trap A Inlet

! 81PPHV136 157D 1

! 81PPHV143 Val . (Oper.), Cold Trap A Outlet 157E

. 81PPHV149 Val (0per), Cold Trap Outlet Hdr 1078 81PPHV153 Val Oper, Overflow Vessel Return 1078 R5

'f Temperature, Overflow Heat 81PPTE100 1078 E! Exchanger Outlet (T/C) 81PPTE101 Temperature, Overflow Heat 107B Exchanger Outlet (T/C) 81EPB003B Local Panel, EVS Processing 311 120

81EPHV383 Val . (Operator), EVST Inlet, Loop 1 360 150 81EPHV384 Val . (0per.), EVST Outlet, Loop 1 360 81EPHV393 Val . (0per.), EVST Outlet, Loop 2 357 81EPHV397 Val . (0per.), EVST Inlet, Loop 2 357 81EPP002A Pump, EVS Na EM 360 Y U (1) location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration 4 environments will be indicated on this table at a later date.

l O O (2)

O Equipment Maximum 4

Time Accident Number Description Cell Number (I) Duration Temp (OF )

System 81 81EPP002B Pump, EVS Na EM 357 30 Days 150 i

81EPB003A Local Panel, EVS Processing 311 120 l

j 81PPE003B Cabinet, Variable Transformer Drive 105A 120 81 PPB 002A Local Panel, Primary Processing 105V 120 81 PPB 002B Local Panel, Primary Processing 105V 120 81PPP001A Pump, Primary Na Makeup 103 150 81PPP001B Pmp, Primary Na Makeup 104 150 R5 81PPE001A Cabinet, Makeup Ptsnp Control 105F 120 81PPE001B Cabinet, Makeup Pump Control 105A 120 81PPE002A Cabinet, Makeup Pump Capacitor 105F 120 81PPE002B Cabinet, Makeup Pump Capacitor 105A ,120 81PPE003A Cabinet, Variable Transformer Drive 105F 120 81PPHV102 Valve (Operator), Overflow Heat 1078 150 Exchanger Bypass 81PPHV103 Valve (Operator), Overflow Heat 107B Y 150 Exchanger Inlet (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

l O (2)

O O

~~

l Equipment Maximum i Time Accident Number Description Cell Number (1) Duration Temp (OF )

System i

81PPHV109 Valve (0perator), Cold Trap Inlet 107B 30 Days 150 Header 81PPHV128 Valve (Operator), Cold Trap B Inlet 157E 150 81EPHV357 Val Oper, EVST/DHRS Crossover Valv. 352A 120 4

81EPHV358 Val Oper, EVST/DHRS Crossover Valv. 352A 81EPHV359 Val Oper, EVST/DHRS Crossover Valv. 352A 81EPHV415 Val Oper, EVST/DHRS Crossover Valv. 353A 81EPHV416 Val Oper, EVST/DHRS Crossover Valv. 353A R5 81EPHV420 Val Oper, EVST/DHRS Crossover Valv. 353A 81EPHV421 Val Oper, EVST/DHRS Crossover Valv. 353A

81EPTE480 Temp. (T/C) EVST Na Outlet 331 150 81EPTE487 Temp (T/C) EVST Na Outlet 331 81EPTE388 Temp. (T/C) EVST Na Outlet 360 j 81EPTE389 Temp. (T/C) EVST Na Outlet 357

\ 4 I

81AAB018A Control Room Panel, System 81 431 4 120 l

(1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

O -

O (2)

O Eqpipment Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF)

System 81 81AAB018B Control Room Panel, System 81 431 30 Days 120 81PPilV102A Valve Accessory Package ~

105Y R5 81PPilV103A 105S 81PPHV109A 105Y 81PPHV128A 111 81PPHV131A 105E "g, 81PPilV135A 111 R6 w

81PPHV136A 111 81PPilV143A 111 81PPHV149A 105S 81PPHV153A 105S 81EPHV383A 352A R5 81EPHV384A 352A 81EPHV393A 'I 352A 't U R6 l

(1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

O O O Equipment Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF)

System 81 81EPHV497A Valve Accessory Package 353A 30 Days 120 R6 81EPE004A Cabinet, EVS Pump Control 352A 81EPE004B Cabinet, EVS Pump Control 353A 81EPE005A Cab., Variable Transformer Drive 352A 81EPE005B Cab., Variable Transformer Drive 353A 81EPE006A Cab., EVS Pump Capacitor 352A

{ 81EPE006B Cab., EVS Pump Capacitor 353A R5 81EPP003A Pump, EVS NaK EM 352A 81EPP003B Pump, EVS NaK EM 353A 81EPE007A Cab., EVS NaK Pump Control 352A 81EPE0078 Cab:, EVS NaK Pump Control 353A 81EPE008A Cab., Variable Transformer Drive 352A 81EPE008B Cab., Variable Transformer Drive 353A 81EPE009A Cab., EVS NaK Pump Capacitor 352A 81EPE009B Cab., EVS NaK Pump Capacitor 353A U U (1) location of cell numbers within each building may be readily determined from the General Arrangement Drawing. .

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

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2 i TABLE 3-1( ,)

, Equipment Maximum Time Accident j Number Description Cell Number (I) Duration Temp (OF) _

System 82 82CGHV154B Containment Iso. Valve (0perator) 317 30 Days 120 82CGPV501A 397 -

82NGPV351A 347 j 82APHV002 376 82CGHV153A 376 R5 i

i 82RPHV1378 380 o

I h 82RPHV138B y 380 82CGHV085 EVST NaK Exp. Tnk. Equalization 353A Y U Valve Operator 1

i (1) location of cell numbers within each building may be readily detennined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the

! responsible system designing the component. Components which will be qualified to vibration

! environments will be indicated on this table at a later date.

I

s Equipment IABLE 3-1(2) Maximum l Time Accident Number Description Cell Number (1) Dura tion Temp (OF )

1 l System 90

) Main Control Panel 90CSB016 431 1 second (4) 120 i ,

30 Days (3) R5 90CSB002A, B Scram Breaker Cubicle 457 .04 seconds 120 t

i w

i J

I i

i j (1) Location of cell numbers within each building may be readily determined from the General Arrangement

! Drawing.

! (2) Identification of IE equipment and equipment location shall be under the change control of the

) responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date. ,

(3) PAM Instrumentation (4) All other IE functions.

i

O O O (2)

Equipment liaximum Time Accident Number Description Cell Number (I) Duration Temp (0F)

System 92 92AAB002A Reactor Coolant Operating 151 30 Days 220 Level Sensor (Connector) _

92AAB002B Reactor Coolant Operating 151 30 Days 220 R5 Level Sensor (Connector) 92AAB002C Reactor Coolant Operating 151 30 Days 220 Level Sensor (Connector)

Y a

(1) location of cell numbers within each building may be readily determined from the General Arrangement Drawing. ,

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

O O O Equipment TABLE 3-1(2) Maximum Time Accident Number Description Cell Number (I) Duration Temp (OF)

System 95 i 95AAB006A, B, C Wide Range Preamplifiers 151 30 Days 130 R5 95AAB008A, B, C Wide Range Detector Assemblies 101A TBD 260 HOLD 95000003 95AAB003A, B, C Power Range Junction Boxes 151 30 Days 130 R5 95AAB004A, B, C Power Range Detector Assemblies 101A TBD 260 1

.l 95AAB041A, B, C Wide Range Log Count. Drawers (3) 431 N/A 120 Y 95AAB051A, B, C Wide Range Log MSV Drawers (3) 431 30 Days 120 0

95AAB061A, B, C Wide Range D.C. Linear Drawers (3) 431 30 Days 120 95AAB009A, B, C Power Range D.C. Linear Drawers (4) 431 30 Days 120 R5 95AAB001A, B, C Signal Conditioning Cabinets 431 30 Days 120 (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawi ng .

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will 'be qualified to vibration environments will be indicated on this table at a later date.

(3) Equipment drawers A, B, & C are mounted in cabinets 95AAB001 A, B, & C respectively.

(4) Equipment Drawers A, B, & C are mounted in Primary RSS Buffer Cabinets 99SB001 A, D, & G respectively.

1

(

l s ) J J l '

Equipment Maximum Time Accident -

Number Description Cell Number (I) Duration Temp (OF)

System 96 '

96PMB040A Control Room Main Air Intake (A) CB413 30 Days 120*

96PMB040B Control Room Main Air Intake (B) CB413 96PMB041 A Control Room Remote Air Intake (A) SGB246 96PMB041B Control Room Remote Air Intake (B) SGB246 96PMB072A Annulus Filter Discharge (A) RSB395A-i 96PMB072B Annulus Filter Discharge (B) RSB349 96PMB073A Annulus Filter Inlet (A) RSB395A

E 96PMB073B Annulus Filter Inlet (B) RSB349 96PMB074A RSB Clean-up Filter Discharge (A) RSB348 R6 96PM8074B RSB Clean-up Filter Discharge (B) RSB347A 96EMB018A TMBDB Effluent Activity (A) RSB395A 96EMB018B TMBDB Effluent Activity RSB349 96EMB019A TMBDB Effluent PU Activity (B) RSB395A i 96EMB019B TMBDB Effluent PU Activity RSB349 96AAB003A "

Class lE Panel A (Division I) CB431 V (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

s 2 i Equipment TABLE 3-1( ) Maximum j

Time Accident Number Description Cell Number (I) Duration Temp (GF) _

, 96AAB003B Class lE Panel B (Division II) CB431 30 days 120 96AAB003C Class IE Panel C (Division II) CB431 96PM8069A RSB OP Floor Exhaust Monitor RSB308A R6 96PMB0698 RSB OP Floor Exhaust Monitor RSB309 ,

96PMB070A FHC Exhaust Monitor RSB307B 96PM80708 FHC Exhaust Monitor RSB307B y V iY

C er i

l .

i (1) location of cell numbers within each building may be readily determined from the General Arrangement Drawing. .

, (2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration environments will be indicated on this table at a later date.

Equipment TABLE 3-1(2) Maximum (4)

Time Accident Number Description Cell Number II) Duration Temp (OF)

System 99 99ESB006C CIS Breaker Cabinet 1 271 30 Days 120

~

99ESB006D CIS Breaker Cabinet 2 262 99PSB001A, D, G Primary RSS Buffer Cabinets 431 99PSB001C, F, J Pri . RSS Comparator Cabinets 431 99PSB002A, D, G Secondary RSS Buffer Cabinets 431 99PSB002C, F, J Secondary RSS Comparator Cabinets 431 -

R5 Y 99PSB003A, C, E Primary RSS Isolation Cabinets 431 Es 99PSB0038, D, F Primary RSS Logic Cabinets 431 99PSB004A, B, C Sec. RSS Solenoid Driver Cabinets 431 99ESB005A, B, C CIS Comparator Cabinets 431 99PSB005A, C PPS Auxiliary Isolation Cabinets 431 99PSB005B, D PPS Auxiliary Logic Cabinets 431 U V (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawing.

(2) Identification of IE equipment and equipment location shall be under the change control of the responsible system designing the component. Components which will be qualified to vibration ,

environments will be indicated on this table at a later date.

(3) All components to be qualified to operate for a period of 30 days without margin after being exposed to the environmental envelope of Figure 4-1.

(4) This equipment does not experience the environmental conditions of design basis events. This equipment will be qualified to demonstrate operability under the expected extremes of its non-accident servile environment.

l .

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(, TABLE C /) ,

C)+

q Class 1E: Equipment Subject to Severe Environments environmental Figure numbers transients of enveloping or maximum values (3)

Description Cell Numbe Temp. Pressure ilumidityN) Rad. Chemical Number Sys tem 12 Connectors and Tenninations ,

Various (6) (6) (6) (6) (6)

Primary RSS Cable 161A(RCB) 2-1 2-2 100% 2-3 2-4 Secondary RSS Cable 161A (RCB) 2-1 2-2 100% 2-3 2-4 Cable Various 2-9 (RSB)

RSS/SGAHRS Cable Various 2-7 2-8 100%

(SGB) y Containment Electrical Penetration Va rious 2-1 2-2 100% 2-3 2-4 12 NIB 001A DG Local Control Panel DGB511 1200 F -NA- 30% -NA- (5 )

R5 12 NIB 001D DG Local Control Panel DGB512 12NIE002A DG Resistor and XFMR DGB511 12NIE0028 DG Resistor and XFMR DGB512 y y 9 y p (1) location of cell numbers within each building may be readily determined from the General Arrangement Drawings.

(2) Identification of Class 1E equipment and equipment location shall be under the change control of the system responsible for designing that equipment.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 100% humidities.

(5) Class 1E components in these locations are subjected to the following higher than normal sodium aerosol concentra tions: First Minute 14 gms/ cubic meter (8.269/m3 equiv. sodium) equiv., sodium perioxide(Na202) R6 Next Four Minutes 5 gms/ cubic meter (2.95g/m3 equiv, sodium) equiv. sodium perioxide(Na202)

Total Deposit 30 gms/ square meter (17.69 9 /m3 equiv. sodium) equiv. sodium perioxide(Na20 2)

See paragraph 3-1 for definition of environment. iiigner concentration attributed to obseace of Diesel Generator Building Isolation.

Endal _Aransients r for ec@ent utilizinj connectors / terminations. __ _ _ _ _ _ _ _ _ _

,n ,m (pv) TABLE (v !

(m- /

Class IE: Equipment Subject to Severe Environments envi ronmental Figure numbers transients of enveloping or maximum values (3) tiumbe r Description CellNumheb Temp. Pressure Humidity N) Rad. Chemical System 12 0

12flIE022A Diesel Generator A( DGBS11 120 F -NA- 30% -NA- (5) 12flIE0228 Diesel Generator B(6) DGB512 12NIK101A DG Jacket Wtr Htr Pump A Motor DGB511 12flIK101B DG Jacket Wtr Htr Pump B Motor DGB512 12flIK103A DG Oil Htr Pump A Motor DGB511 R5 12NIK103B DG 011 Heater Pump B Motor DGBS12 12NIK107A DG Fuel Oil AC Backup Pump A Motor DGB511 12flIK1078 DG Fuel 011 AC Backup Pump B Motor DGB512 12flIK109A DG Gov. Oil Booster Pump A Motor DGB511 12NIK109B DG Gov. Oil Booster Pump B Motor DGB512 y y V y y (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawings.

(2) Identification of Class 1E equipment and equipment location shall be under the change control of the system responsible for designing that equipment.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 100% humidities.

(5) Class 1E components in these locations are subjected to the following higher than normal sodium aerosol c ncentrations: First Minute 14 gms/ cubic meter (8.269/m 3 equiv, sodium) equiv. sodium perioxide N 02 RT flext Four Minutes 5 gms/ cubic meter (2.959 /m3 equiv. sodium) equiv. sodium perioxide Na 02 Total Deposit 30 gms/ square meter (17.699/m3 equiv. sodium)equiv. sodium perioxide (Na20 2).

See paragraph 3-1 for definition of environment. Higher concentration attributed to absence of Diesel Generator Building Isolation.

(6) Only [Elecftrrfcol rerts are subfect to Class lE qualifications.

(-) Class 1E:

TABLE 3-[v, J Equipment Subject to Severe Environments (v )

Figure numbers of enveloping nvironmental transients or maximum valuest rhnber Description Cell Numbe Temp. Pressure Humidity b) Rad. Chemical System 25A 25ADK341A "A" Emerg. Supply Fan Motor DGB511 120 -NA- 30% -NA- (5) 1 25ADK341B "A" Emerg. Supply Fan Motor DGB511 25ADK342A "B" Emerg. Supply Fan Motor DGB512 25ADK342B "B" Emerg. Supply Fan Motor DGB512 R5 25ADK343 Day Tank Cell Exhaust Fan Motor DGB511 25ADK344 Day Tank Cell Exhaust Fan Motor DGB512 4 v v y v (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawings.

(2) Identification of Class 1E equipment and equipment location shall be under the change control of the system responsible for designing that equipment.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 100% humidities.

(5) Class IE components in these locations are subjected to the following higher than normal sodium aerosol concentrations: First Minute 14 gms/ cubic meter (8.269 /m3 equiv. sodium) equiv. sodium perioxide (Na202 )

Next Four Minutes 5 gms/ cubic meter (2.959 /m3 equiv. sodium) equiv. sodium perioxide (Na20 2) R6 Total Deposit 30 gms/squaro meter (17.69 9 /m3 equiv. sodium) equiv, sodium perioxide (Na202)

See paragraph 3-1 for definition of environment. Higher concentration attributed to absence of Diesel Generator Building Isolation.

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( Class IE:

TABLE 3-( V ,

Equipment Subject to Severe Environments 0)

(

Figure numbers of enveloping environment 1

~

transients or maximum values (3)

Description CellNumbeh Temp. Pressure HumidityN k$d. Chemical Number _

System 56 56PRK201A PHTS Na Pump Pony Motor, RCB161C 2-1 2-2 2-3 2-4 56PRK201B Loops 1, 2, 3 RCB161D 2-1 2-2 2-3 2-4 56PRK201C RCB161E 2-1 2-2 2-3 2-4 56PRK112A PHTS Na Pump Drive ARD RCB161C 2-1 2-2 2-3 2-4 56PRK1128 Bearing Fan Motor, Loops 1, 2, 3 RCB161D 2-1 2-2 2-3 2-4 56PRK112C RDB161E 2-1 2-2 2-3 2-4 R5 56PRST103AP, BP, PHTS Na Pump Tachometer RCB161C 2-5 2-6 CP Loops 1, 2, 3, Channels A, B, C RCB1610 2-5 2-6 56PRST203AP, BP, RCB161E 2-5 2-6 CP 56PRST303AP, BP, CP 56SGB097A SGS Primary PPS Instrument Rack Channel A, Loop 1 SGB241 2-7 2-8 100%

56SGB097B SGS Primary PPS Instrunent Rack, Channel B, Loop 1 SGB242 2-7 2-8 100%

56SGB097C SGS Primary PPS Instrument Rack, Channel C, Loop 1 SGB243 2-7 2-8 100%

(1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawings.

(2) Identification of Class IE equipment and equipment location shall be under the change control of the system responsible for designin!J tha t equ ipmen t.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 1001. humidities.

t) TABLE 3-1 A) hq Class 1E: Equipment Subject to Severe Environments Figure numbers of enveloping environmental transients or maximum values (3)

Description Cell Numbe Temp. Pressure Humidity W Rad. Chemical thnnber System 56 56SGB098A SGS Primary PPS Instrument SGB241 2-7 2-8 100%

Rack, Channel A, Loop 2 l 56SGB0988 SGS Primary PPS Instrtsnent SGB242 2-7 2-8 100%

Rack, Channel B, Loop 2 56SGB098C SGS Primary PPS Instrtsnent SGB243 2-7 2-8 100%

Rack, Channel C Loop 2 56SGB099A SGS Primary PPS Instrument SGB241 2-7 2-8 100% R5 y Rack, Channel A, Loop 3 56SGB0993 SGS Primary PPS Instrument SGB242 2-7 2-8 100%

Rack, Channel B Loop 3 56SGB099C SGS Primary PPS Instrument SGB243 2-7 2-8 100% l Rack, Channel C, Loop 3 !

l 56SGB094A SGS Secondary PPS Instrument SGB241 2-7 2-8 100%

Rack, Channel A, Loop 1 56SGB0948 SGS Secondary, PPS Instrument SGB242 2-7 2-8 100% l Rack, Channel B, Loop 1 ,

l 56SGB094C SGS Secondary PPS Instrument SGB243 2-7 2-8 100%

Rack, Channel C. Loop 1

~

(1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawings.

(2) Identification of Class 1E equipment and equipment location shall be under the change control of the system l responsible for designing that equipment.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 100% humidities.

TABLE 3-Class IE: Equipment Subject'to Severe Environments Figure numbers of enveloping environmental transients or maximum values (3)

Description Cell Numbe Temp. Pressure ilumidi_ty(4) Rad. Chemical Naher System 56 56SGB095A SGS Secondary PPS Instrument _SGB241 2-7 2-8 100%

Rack, Channel A, Loop 2 56SGB095B SGS Secondary PPS Instrument SGB242 2-7 2-8 100%

Rack, Channel B, Loop 2 56SGB095C SGS Secondary PPS Instrument SGB243 2-7 2-8 100%

Rack, Channel C, Loop 2 56SGB096A SGS Secondary PPS Instrument SGB241 2-7 2-8 100%

T' Rack, Channel A, Loop 3 k$

7 56SGB096B SGS Secondary PPS Instrument SGB242 2-7 2-8 100%

Rack, Channel B, Loop 3 56SGB096C SGS Secondary PPS Instrument SGB243 2-7 2-8 100% R5 Rack, Channel C, Loop 3 56INB111AP IHTS Primary PPS Panel SGB207 2-7 2-8 100%

Channel A 56INB111BP IHTS Primary PPS Panel SGB208 2-7 2-8 100%

Channel B 561NB111CP IHTS Primary PPS Panel SGB209 2-7 2-8 100%

Channel C

- = . . _ _

(1) location of cell numbers within each building may be readily determined from the General Arrangement Drawings.

(2) Identification of Class lE equipment and equipment location shall be under the chanqe control of the system responsible for designing that equipment.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 100% humidities.

p. (%

0s Class IE:

1^8'e >v).

Equipment Subject to Severe Environments t>

Figure numbers of enveloping environmental transicnts or maximum values (3) ,

Description Cell flumbebI} Temp. Pressure Humidity Rad. Chemical Number System 56 56IflB111AS IHTS Secondary PPS Panel SGB207 2-7 2-8 100%

Channel A 1 56IflB111BS IHTS Secondary PPS Panel SGB208 2-7 2-8 100%

Channel B 56IfiB111CS IHTS Secondary PPS Panel SGB209 2-7 2-8 100%

Channel C 56SGPSH108AS Superheater Inlet SWRPRS Vent SGB244 2-7 2-8 100%

y 56SGPSil108BS Line Pressure Sensors, Loop 1, SGB244 2-7 2-8 100%

y 56SGPSH108CS Channels A, B, C SGB244 2-7 2-8 100% R5 56SGPSH208AS Superheater Inlet SWRPRS SGB245 2-7 2-8 100%

56SGPSil208BS Vent Line Pressure Sensors, SGB245 2-7 2-8 100%

56SGPSH208CS Loop 2, Channels A, B, C SGB245 2-7 2-8 100%

56SGPSil308AS Superheater Inlet SWRPRS SGB246 2-7 2-8 100%

56SGPSH308BS Vent Line Pressure Sensors, SGB246 2-7 2-8 100%

56SGPSH308CS Loop 3, Channels A, B, C SGB246 2-7 2-8 100%

56SGPSH109AS West Evaporator SWRPRS SGB224 2-7 2-8 100%

56SGPSH109BS Vent Line Pressure Sensors, SGB224 2-7 2-8 100%

56SGPSH109CS Loop 1, Channels A, B, C SGB224 2-7 2-8 100%

(1) location of cell numbers within each building may be readily determined from the General Arrangement Orawings.

(2) Identification of Class 1E equipment and equipment location shall be under the chanqe control of the system responsible for designing that equipment.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 100% humidities.

TABLE 3 Class IE: Equipment Subject to Severe Environments Figure numbers of enveloping environmental transients or maximum valuest3)

Number Description CellNumbeP Temp. Pressure iumidityN) Rad. Chemical System 56 56SGPSH209AS West Evaporator SWRPRS SGB225 2-7 2-8 100%

56SGPSH209BS Vent Line Pressure Sensors, SGB225 2-7 2-8 100%

56SGPSH209CS Loop 2, Channels A, B, C SGB225 2-7 2-8 100%

! 56SGPSH309AS West Evaporator SWRPRS SGB226 2-7 2-8 100%

56SGPSH309BS Vent Line Pressure Sensors, SGB226 2-7 2-8 100%

56SGPSH309CS Loop 3, Channels A, B, C SGB226 2-7 2-8 100%

56SGPSH110AS East Evaporators Sk'RPRS SGB224 2-7 2-8 100%

56SGPSH110BS Vent Line Pressure Sensors, SGB224 2-7 2-8 100%

Loop 1, Channels A, B, C SGB224 2-7 2-8 100% R5

{ 56SGPSH110CS 5 56SGPSH210AS East Evaporators SWRPRS SGB225 2-7 2-8 100%

56SGPSH210BS Vent Line Pressure Sensors, SGB225 2-7 2-8 100%

56SGPSH210CS Loop 2, Channels A, B, C SGB225 2-7 2-8 100%

56SGPSH310AS East Evaporators SWP. PRS SGB226 2-7 2-8 100%

56SGPSH310BS Vent Line Pressure Sensors, SGB226 2-7 2-8 100%

56SGPSH310CS Loop 3, Channels A, B, C SGB226 2-7 2-8 100%

56SGTE151A, B, C Cell Temp. and Moisture Sensors, SGB241 2-7 2-8 100%

56SGME151A, B, C Steam Drum Cell Loop 1, SGB241 2-7 2-8 100%

Channels A, B, C SGB241 2-7 2-8 100%

, (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawings.

(2) Identification of Class IE equipment and equipment location shall be under the chanqe cnntrol of the system responsible for designing that equipment.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 100% humidities.

f O N d Class IE:

TABLE 3]) ,

Equipment Subject to Severe Environments J

Figure numbers of enveloping environmental transients or maximum values (3)

Description CellNumbeb Temp. Pressure Humidity ) Ikad. Chemical Numbe r System 56 56SGTE251A, B, C Cell Temperature and Moisture SG8242 2-7 2-8 100%

56SGME251A, B, C Sensors, Steam Drum Cell, Loop 2, SGB242 2-7 2-8 100%

Channels A, B, C SGB242 2-7 2-8 100%

56SGTE351A, B, C Cell Temperature and Moisture SGB243 2-7 2-8 100%

56SGME351A, B, C Sensors, Steam Drum Cell, Loop 3, SGB243 2-7 2-8 100%

Channels A, E, C SGB243 2-7 2-8 100%

56SGTE152A, B, C Cell Temperature and Moisture SGB221 2-7 2-8 100%

56SGME152A, B, C Sensors, Recirc. Pump Cell, SGB221 2-7 2-8 100%

i Y' Loop 1, Channels A, B, C SGB221 2-7 2-8 100%

M R5 56SGTE252A, B, C Cell Temperature and Maisture SGB222 2-7 2-8 100%

56SGME252A, B, C Sensors, Recirc. Pump Cell, SGB222 2-7 2-8 100%

Loop 2, Channels A, B, C SGB222 2-7 2-8 100%

56SGTE352A, B, C Cell Temperature and Moisture SGB223 2-7 2-8 100%

56SGME352A, B, C Sensors, Recirc. Pump Cell, SGB223 2-7 2-8 100%

Loop 3, Channels A, B, C SGB223 2-7 2-8 100%

56SGTE153A, B, C Cell Temperature and Moisture SGB224 2-7 2-8 100%

56SGME153A, B, C Sensors, Steam Generator Cell, SGB224 2-7 2-8 100%

Loop 1, Channels A, B, C SGB224 2-7 2-8 100%

i (1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawings.

(2) Identification of Class 1E equipment and equipment location shall be under the change control of the system responsible for designing that equipment.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 100% humidities.

s TABLE 3b) q p)

(

Class IE: Equipment Subject'to Severe Environments Figure numbers of. enveloping environmental transie'nts or maximum values (3)

~

Description CellNumbeh} Temp. Pressure Humidity Rad. Chemical Number

! System 56 56SGTE253A, B, C Cell Temperature and Moisture SGB225 2-7 2-8 100%

56SGME253A, B, C Sensors, Steam Generator Cell, SGB225 2-7 2-8 100%

Loop 2, Channels A, B, C SGB225 2-7 2-8 100%

56SGTE353A, B, C Cell Temperature and Moisture SGB226 2-7 2-8 100%

56SGME353A, B, C Sensors, Steam Generator Cell, SGB226 2-7 2-8 100%

Loop 3, Channels A, B, C SGB226 2-7 2-8 100%

56SGTE154A, B, C Cell Temperature and Moisture SGB207 2-7 2-8 100%

56SGME154A, B, C Sensors, Na Dump Tank Cell, SGB207 2-7 2-8 100% RS

<r Loop 1, Channels A, B, C SGB207

'M* 56SGTE254A, B, C Cell Temperature and Moisture SGB208 2-7 2-8 100%

56SGME254A, B, C Sensors, Na Dump Tank Cell, SGB208 2-7 2-8 100%

j Loop 2, Channels A, B, C 56SGTE354A, B, C Cell Temperature and Moisture SGB209 2-7 2-8 100%

56SGME354A, B, C Sensors, Na Dump Tank Cell, SGB209 2-7 2-8 100%

Loop 3, Channels A, B, C SGB209 2-7 2-8 100%

56HRTE145 PACC Return Water Temperature SGB241 2-7 2-8 100%

56HRFT144 Sensor and Flow Transmitter, SGB241 2-7 2-8 100%

Loop 1

+

(1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawings.

(2) Identification of Class lE equipment and equipment location shall be under the change control of the system responsible for designing that equipment.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 100% humidities.

p) [3 d Class IE:

TABLE 3U Equipment Subject'to Severe Environments

()

Figure numbers of. enveloping environmental transients or maximum valuesl3)

Description CellNumbeb) Temp. Pressure Humidity Rad. Chemical Number System 56 56HRTE245 PACC Return Water Temperature SGB242 2-7 2-8 100%

56flRFT244 Sensor and Flow Transmitter, SGB242 2-7 2-8 100%

Loop 2 R5 4

56HRTE345 PACC Return Water Temperature SGB243 2-7 2-8 100%

56llRFT344 Sensor and Flow Transmitter, SGB243 2-7 2-8 100%

i Loop 3

i' n

a j

i (1) location of cell numbers within each building may be readily determined from the General Arrangement Drawings.

(2) Identification of Class lE equipment and equipment location shall be under the chanqe control of the system responsible for designing that equipment.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 100% humidities, t

, ,n (v' ) TABLE 3-(,,) (v' )

v '.

Class 1E: Equipment Subject to Severe Environments Figure numbers of enveloping environmental transients or maximum values (3)

Description CellNumbeP Temp. Pressure Humidity N) Rad. Chemical thenbe r System 82 110LD 1 302006 82CGilV154A Containment Iso. Valve Operator 102A 2-1 2-2 2-3 2-4 R5 32CGPV501B Containment Iso. Valve Operator 105S 2-1 2-2 2-3 2-4 82CGPV351B Containment Iso. Valve Operator 105S 2-1 2-2 2-3 2-4 82CGliV153B Containment Iso. Valve Operator 173 2-1 2-2 2-3 2-4 82RPilV137A Containment Iso. Valve Operator 173 2-1 2-2 2-3 2-4

, 82RPilV13M Containment Iso. Valve Operator 173 2-1 2-2 2-3 2-4

$ 82APilV001 Containment Iso. Valve Operator 173 2-1 2-2 2-3 2-4 R5 (1) location of cell numbers within each building may be readily determined from the General Arrangement Drawings.

(2) Identification of Class 1E equipment and equipment location shall be under the change control of the system responsible for designing that equipment.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 1007, humidities.

D2

(],,/ TABLE V ), J Class IE: Equipment Subject to Severe Environments Figure numbers of enveloping environmental transients or maximum valuesT3)

Description CellNumbeb Temp. Pressure Humidity N) Rad. Chemical Number System 96 R6 96PMB001A Head Access Area hnitors ,

151 2-1 2-2 100% 2-3 2-4 E6PMB001B Head Access Area Monitors 151 2-1 2-2 100% 2-3 2-4 96PMB001C Head Access Area Monitors 151 2-1 2-2 100% 2-3 2-4 96PMB002A RCB Exhaust Monitors 161A 2-1 2-2 100% 2-3 2-4 R5 96PMB0028 RCB Exhaust Monitors 161A 2-1 2-2 100% 2-3 2-4 96PMB002C RCB Exhaust Monitors 161A 2-1 2-2 100% 2-3 2-4 h96 PPB 043 RCB High Range Annulus Monitor 169A (5) (5) (5) (5) (5) 96 PPB 044 169A (5) (5) (5) (5) (5) R6 96 PPB 045 169A (5) (5) (5) (5) (5)

(1) Location of cell numbers within each building may be readily determined from the General Arrangement Drawings.

(2) Identification of Class 1E equipment and equipment location shall be under the change control of the system responsible for designing that equipment.

(3) Components which will be qualified to vibration environments will be indicated on this table at a later date.

(4) Condensation will occur on equipment under test at 100% humidities.

(5) TMBDB equipment refer to WARD-D-0156 for Environmental Conditions. R6

4. QUALIFICATION PROCEDURES 4.1 CRBRP Class lE Equipment (Ov) The design basis accident environment is significantly different from the normal environment in selected cells affected strongly by accidents. Conse-quently, Class lE equipment located in these cells must be aged and qualified to the severe accident environments per paragraph 4.2.2. Other Class lE equipment which is not subjected to severe accident environments must be R6 evaluated for aging effects and qualified by any one or an appropriate combination of the several ways of meeting the requirements of IEEE 323, such as type testing, (Sections 4.2.1,4.2.2) operating experience (Section 4.2.3) or analysis (Section 4.2.4). If, due to practicality or cost considerations, a piece of Class lE equipment cannot be qualified using any one or an appro-priate combination of procedures specified in Section 4.2, then the RM or AE cognizant engineer shall propose procedures and obtain Project Office approval for testing the equipment as single components or as completed assemblies that are at least as severe as the requirements of IEEE 323-1974. The results of the qualification procedure are to be recorded per IEEE 323-1974 (see Appen-dix A for an illustration of format).

The cognizant engineer preparing an Equipment Specification for any piece of Class 1E equipment will determine whether it is to be qualified according to paragraph 4.2.1, 4.2.2, 4.2.3 or 4.2.4. Each piece of Class lE equipment must be qualified for operation during that portion of the applicable trans-ients during which it must perform its safety function. The cognizant engineer must specify the choices, if any, which are being passed to the N vendor. In each instance the cognizant engineer must specify the require-ments for qualification. He must determine the time interval during which the particular Class lE equipment must perform its safety function. IEEE 323 requires that 10% be added to this time interval for margin. If (for example), the equipment appears in Table 3-1 and will be qualified by type test, the cognizant engineer must specify this type test in accordance with the procedures of paragraph 4.2.1, Where equipment is qualified by type testing, the item being qualified must be either identical to the plant R6 hardware or all differences existing must be identified and justification provided that the differences do not affect the qualification validity.

He must also specify that the records of these tests be prepared in such form as to meet the auditable documentation requirements of IEEE 323-1974.

An illustration of acceptable documentation is given in Appendix A.

4.2 Specific Procedures 4.2.1 QUALIFICATION PROCEDURES FOR CLASS lE EQUIPMENT NOT SUBJECTED TO SEVERE ACCIDENT ENVIRONMENTS Class lE equipment in this category is not subject to severe accident environment qualification. This equipment will be qualified to the temp-erature, humidity, voltage and frequency conditions defined in Figure 4-1 by operating experience (4.2.3) analysis (4.2.4) or the type test described in this paragraph. When size or other practical requirements limit type tests, this part of the qualification may be completed by a combination of

, c 4-1 i ._. _ __

partial type test with extrapolation or analysis. If the equipment is a large rotating machine, it may be qualified by a combination of analysis, h motorette testing and type testing. Where testing is required the motorettes R6 will be thermally aged and subjected to the appropriate accident environments as shown in Figura 4-1. Equipment subjected to this type test shall have first passed all other E-Spec acceptance tests.

The type tests shall be performed in numerical order to meet the require-monts of IEEE 323 paragraph 6.3.2. Also, any item being type tested shall undergo the complete set of tests described below.

1. Pre-Operational Tests: Visual examination, dieletric and insulation resistance tests followed by interconnection to function as a complete working system. Dummy input signals and loads shall be provided as required to perform simulated system operation. Electrical inter-ference tests shall be performed as defined in equipment specification.

2. Functional Tests: Verify that the equipment performs its safety function; e.g. : Inject test signals and detarmine that logic compu-tation is correct; relay operates; bistable operates and set-points are correct.

3. Aging: The aging effects on Class lE equipment in non-severe environ-ments shall be evaluated and the results are to be documented as part of the Equipment Qualification Data Package. Equipment and components may be excluded from the simulated aging requirements of Section 4.2.2.1, based on documented demonstration of no significant degradation of R6

\ pertinent properties during its projected installed service life (ir, j the specific Class lE equipment) assuming scheduled maintenance sur-veillance and inspection is properly performed. If such demonstration cannot be made, then aging of the equipment or component is required.

4. Burn-In Test (Determination and evaluation of infant mortality): After completion of the initial system tests, the system shall be energized for a minimum of 100 hours0.00116 days 0.0278 hours 1.653439e-4 weeks 3.805e-5 months at nominal voltage under room temperature conditions to assist in the detection and elimination of components subject to early failure. The operation of the system shall be checked during the burn-in test as outlined below, and by complete operational test performed at the completion of the test.

Periodically, during the burn-in tests, functional performance of the equipment shall be verified. The time between periodic tests shall no't exceed 25 hours2.893519e-4 days 0.00694 hours 4.133598e-5 weeks 9.5125e-6 months . Any malfunction observed during this test shall be cause to interrupt the test, evaluate the cause of failure, and repair the mal function. If the malfunction is repairable, the repair may be performed and the test continued. Any repaired component should be re-inserted into the system at the next periodic check. The test time shall be extended beyond 100 hours0.00116 days 0.0278 hours 1.653439e-4 weeks 3.805e-5 months as required to insure, at the comple-tion of the test, that all components initially installed have been energized for at least 100 hours0.00116 days 0.0278 hours 1.653439e-4 weeks 3.805e-5 months , and all components replaced as a result of malfunction have been energized for at least 50 hours5.787037e-4 days 0.0139 hours 8.267196e-5 weeks 1.9025e-5 months . No requirement for design modification is anticipated in this phase of the qualification.

O However, if the need should occur, the modification will be in accordance with IEEE-Std. 323-1974, Section 6.8.

4-2

i

5. Operational Tests: Verify that the equipment meets the electrical requirements of its performance specifications, including static and dynamic calibration.

6. If required, a pressure test will be performed in accordance with Section 3.5.

7. Environmental Tests: Environmental testing shall be performed for temperature, humidity, and non-severe sodium aerosols environments as R6 specified below.

Temperature / Humidity - Environmental testing shall be performed according to Figure 4-1. Equipment shall be mounted in a manner and a position that simulates its expected installation when in actual use unless an analysis can be performed and justified to show that the equipment's performance would not be altered by other means of mounting. The equipment, with all electrical loads and inputs properly simulated, shall be placed in an environmental test chamber capable of providing concurrently the conditions defined by ;

the curves. Complete instrumentation shall be used to permit con-4 tinuous monitoring of the environmental conditions. The equipment shall be energized throughout each test cycle as indicated by the figure. Input / output simulation shall be used to provide the cap-ability to test the equipment for proper operation during and after the test cycles. The test chamber conditions shall be stabilized l q for a minimum of two hours prior to the start of any test cycle.

The tolerances on the steady state test chamber conditions are to 1 (V be added to the temperature and relative humidity ranges with appro-priate sign to be sure that the specified ranges are accomplished by the test. Functional tests (Test 2) shall be performed at the beginning of the test and at the end of each cycle. Eight hours (maximum) between cycles is recommended for testing, repair and to establish the new test chamber conditions for cycles 1 through 4.

The test chamber conditions shall be established in 1.5 hours5.787037e-5 days 0.00139 hours 8.267196e-6 weeks 1.9025e-6 months maximum except for t.he last cycle as defined below. After cycle 4 is completed, including the functional test the equipment is to cool slowly to room temperature and humidity.

Non-Severe Sodium Aerosols - Environmental testing shall be per-formed to simulate the non-severe sodium aerosol environment des-cribed in paragraph 3.1. The equipment, with all electrical loads and inputs properly simulated, shall be placed in an environ-mental test chamber capable of conservatively simulating the non-severe aerosol enviornment while exposed to the maximum equipment temperature specified in Table 3.1 plus 15"F margin and humidity R6 condition in agreement with Table 4-1. Testing with any one or a combination of the Na compounds described in paragraph 3.1 is accept-able provided that the test performer can analytically support that the other sodium compounds which could be present as described in paragraph 3.1 will not result in a more severe environment. The suspended sodium aerosol concentration shall be simulated by the injection of sodium aerosol until the specified peak 4-3

c concentration is reached. After this time injection of sodium

( aerosol suspended concentrations shall be terminated and the 1 equipment must be operated for the time period for which the equipment must operate while exposed to this environment. Func-i tional tests shall be performed at the beginning and conclusion R6 of this test.

8. Seismic Tests: After completion of the applicable portion of the above tests,with ance the Class lE equipment IEEE Standard 344 shall 1975 be seismicalland WARD-D-0037.y qualified Performance shall be in accord-monitored during the seismic qualification and the functional tests performed to demonstrate that the equipment can perform its safety function.

9. At the conclusion of each test series, any malfunctioning components shall be examined to determine the cause of malfunction by a complete failure analysis. Replacement of the component with one having suitable characteristics or redesign of the assembly shall be pursued if shown to be necessary by the failure analysis.

10. The test report shall contain the technical information required to satisfy IEEE Std. 323-1974.

11. In the evaluation of the qualification test results, any sample equip-ment is considered to have failed when the equipment' does not perform the Class lE functions required by the equipment specifications.

O 4-4

O O 4.2.2 CLASS 1E EQUIPMENT SUBJECTED TO SEVERE ACCIDENT ENVIRONMENTS Class 1E equipment which is subjected to severe accident environments during the time interval in which it must perform its safety function, will be qualified per paragraph 4.2.3, 4.2,4 or by type test as described in the following paragraphs, or a combination of those methods to the environments defined in Table 3-2. When size or other practical requirements limit type tests, this part of the qualification may be completed by a combination of partial type tests with extrapolation or analysis.

If the equipment is a large rotating machine, it may be qualified by a combination of analysis, motorette testing and type testing. The procedure will meet the requirements of IEEE 117-1974 for random wound coils or IEEE 275-1966 for form wound coils, and will conform to the requirements of IEEE 323-1974 and IEEE 334-1974, and will meet the applicable requirements of Regulatory Guide 1.40. The motorettes will be thermally aged, irradiated and subjected to the appropriate accident environments as shown in Figure 4-2.

'n*

,V Qualification requirements for valve operators, in addition to those defined in this document, are defined in Regulatory Guide 1.73 and IEEE 382-1972. P Equipment subjected to this type test shall have first passed Equipment Specification acceptance tests. The type tests shall be performed in numerical order to meet the requirements of IEEE 323-1974, paragraph 6.3.2.

Also, any item being type tested shall undergo the complete set of tests described below:

Type Test Procedures are as follows:

1. Pre-operational Tests: Visual examination, dielectric and insulation resistance tests followed by interconnection to function as a complete working system. Dummy input signals and loads shall be provided as required to perform simulated system operation. Electrical interference tests shall be performed, where applicable, according to the equipment specification.

2. Functional Tests: Verify that the equipment performs its safety function; e.g. : Inject test signals and determine that logic computation is correct; relay operates, bistable operates and set-points are correct.

3. Thermal Aging: Operate the equipment (or motorette representing motor windings) at elevated temperature for at least 100 hours0.00116 days 0.0278 hours 1.653439e-4 weeks 3.805e-5 months as shown in Figures 4-2 and 4-3 and explained in paragraph 4.2.2.1.

n v 4. If required, a pressure test will be performed in accordance with Section 3.5.

4-5

5. Operational Tests: Verify that the equipment still meets the electrical f,s requirementswhichever specification sp(ecifiedisinmost Figure 4-1 or thoseincluding conservative), specifiedstatic in its and performance h dynamic calibration (if applicable).

6. Seismic and Radiation Tests: Class 1E equipment shall be seismically qualified in accordance with IEEE Standard 344-1975 and WARD-D-0037.

The Equipment Specification shall specify the seismic frequencies and accelerations plus the IEEE 323-1974 margins for acceleration.

If the specific equipment is subjected to vibration due to fluid turbulence or machine unbalance, this information is to be provided and a vibration test included with the seismic and radiation tests providing the equipment cannot be shown by analysis or operating experience to be un-affected by the vibration.

Perfomance shall be monitored during these tests and the functional tests performed to denonstrate that the equipment can perform its safety function. The radiation dose shall be applied at this point in the test sequence unless it can be shown that a more severe test results from a different sequence.

The dose shall be the sum of normal exposure for 30 years (from Table 2-1) plus the dose resulting from the DBE (from Table 3-2) plus 10% of the DBE dose (per the dotted curve). The details of seismic and radiation tests shall be included in the Equipment Specification for the specific Class

,m 1E equipment.

I \

V 7. Margin Transient: The Class IE equipment will be mounted in a tenperature controlled test chamber and subjected to a transient to the peak accident tenperature plus the IEEE 323-1974 temperature margin of 15 F. The accident temperature will be the maximum temperature to which the equipment is exposed (according to Table 3-2) during the time interval in which it must perform its safety function. This information shall be supplied in the Equpment Specification for specific Class IE equipment.

8. DBE Transient: Maximum temperature, pressure, humidity, and chemical values as applicable (Table 3-2) will be taken from the appropriate

. portion of the (dotted curve) parameter transients (Figures 2-1 to 2-111. ._ _

The Class IE equipment shall be exposed to that portion of the accident transient (from Table 3-2) during which the equipment must perform its safety function for a time of 110% of this interval (the IEEE 323-1974 timemargin).

9. At the conclusion of each test series, any malfunctioning components shall be examined to determine the cause of malfunction by a complete failure analysis. Replacement of the component with one having suitable characteristics or redesign of the assembly shall be pursued if shown necessary by the failure analysis.

j O

(j

10. The test report shall contain the technical information required to satisfy IEEE Std. 323-1974.

4-6 i __ _ . _ .

im

\ 11. Post Accident Aging: Some Class 1E equipment will be required to operate (V for a significant time interval following the termination of the accident.

Figure 4-2 shows that the Class 1E equipment will next be exposed to this aging condition for a minimum of 100 hours0.00116 days 0.0278 hours 1.653439e-4 weeks 3.805e-5 months at a temperature to be determined from Figure 4-3. The temperature and time for pcst accident aging are to be specified in the Equipment Specification if this function is required.

12. In the evaluation of the qualification test results, any sample equipment is considered to have failed when the equipment does not perform the Class 1E functions required by the Equipment Specifications.

4.2.2.1 Simulated Aging This sub-section applies to Class 1E equipnent subjected to severe accident environments.

The CRBRP Project aging method assumes that the assemblies of components which make up each piece of equipment will be, in effect, many different insulation systems. Each of these systems will have some aging characteristics (dependent upon its insulation material) which will range from the "non-aging" characteristics of some ceramics to the characteristics of electrolytes in capacitors which double their aging rate for 6.9 F increase in temperature.

When testing an assembly, the increase in temperature to double the aging g rate will be taken from the insulator in the assembly which requires the T largest temperature increase to double its aging rate. If insulators are

d involved in one assembly that have very different aging characteristics, it may be necessary to remove some components, " age" them separately, and then reassemble.

The aging simulation for mechanical stress, electrical stress and cyclic operations will be conducted and evaluated as follows. An arbitrary normal life for the module or assembly will first be assumed. (typically 30 years or as otherwise specified in the equipment specification. The module or assembly will be aged to this assumed normal life. If an assembly contains one or more items that are clearly in the category of replaceable elements (such as some electrolytic capacitors), the projected qualified life of these items is to be determined and they are to be listed as replaceable elements and their replacement schedule is to be specified in the EQDP. If the module l or sub-assembly successfully completes the aging procedure and the following environmental tests without failure, the projected qualified life will be the assumed nonnal life. If the module or sub-assembly f611s the simulated aging or the following environmental tests, attempts may be made to achieve a redesign which can pass the tests. If it is impractical to change the design, new " aging" tests may be run for a shorter " aging" interval and, if the following environmental tests are completed satisfactorily, the projected qualified life of the sub-assembly will be determined by the maximum " aging"

! interval achieved. Equipment modification, if required, will be in accordance l with IEEE Std. 323-1974, Section 6.8. If this procedure proves to be impractical, the equipment may be aged by a combination of analysis, test, T and available data concerning aging rates for specific types of insulating

[(,)s material.

4-7

m a 4.2.3 Operating Experiance A very large amount of equipment qualified to earlier criteria is presently operating successfully in nuclear plants.

Another experience source is that of equipment features such as insulation systems, lubricants, bearings and so forth, previously qualified for applica-tion in PWR designs and BWR designs, but now designed into CRBRP equipment.

The CRBRP Project plans to use this experience where available and applicable.

Operating experience will apply to Class IE equipment located throughout CRBRP buildings. Qualification by operating experience shall meet the requirements of IEEE 323-1974, paragraph 6.4.

4.2.4 Analysis Analysis can also be employed as the primary method or to supplement other methods as appropriate. In particular seismic analyses of large rotating apparatus will be employed. Analysis can apply to Class IE equipment located throughout CRBRP buildings. Qualification by analysis shall consist of a mathematical or logical demonstration that Class 1E equipment can meet or exceed its safety requirements under worst case conditions. An analytical N approach to qualification may be used when extensive operational experience and/or manufacturer test data, which is applicable to CRBRP DBE's or accident environment, exists for the same or similar equipment. Analysis may also be used to establish the aging characteristics of some types of Class 1E equipment whose components can be classified into groups such as ceramics, copper, pve insulation, varnish or rubber (for example) whose aging characteristics are known from large quantities of research and development data. Qualification by analysis shall meet the requirements of IEEE 323-1974, paragraph 6.5.

4.3 Qualified Life .

The CRBRP Project will determine a projected qualified life based on the results of the qualification procedures described throughout this report.

The maintenance and refurbishing procedures employed, as well as many other factors, affect the useful life of the equipment under consideration. The projected qualified life validity will, therefore, also depend on these procedures. To enhance this validity, the CRBRP Project will also assure that its manuals, and operating and maintenance instructions are current, definitive and accurate.

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FIGURE 4-2 -

QUALIFICATION ENVELOPE FOR EQUIPMENT LOCATED IN SEVEflE ACCIDENT ENVIRONMENTS (SEE fj0TES ON Tile NEXT PAGE)

! RADIATION (1) AND/0R SEISMIC 1

. V AEROSD L TG SIMULATE Na FIRE >

ViliERE APPROFRIATE

+ *- : M- : : P8 AIR STE M ST EN 1 0 f. Er I il0T G AS 110T G AS j l PER TABLE 3-2 PER TA3LE 3-2 rJ 7-- p j ) I i

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SIMULATED FOR 1 I SIMULATED NORMAL EXTRA l ACC, DENT I I SIMULATED POST ACCIDENT AGlf]G MARGIN g COND!TIONS g AGING l
(2)
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! MINIMUM TIME
O QUALIFICATION NOTES V (See Figure 4-2)
The following notes supplement the test sequence information shown in Figure 4-2.
1. The simulated normal aging time-temperature profile may optionally be modified according to the curve by Figure 4-3 which is a plot of the equation.
1/P = 2x P
= simulated aging period (hours)
X = number of Y F steps that the aging temperature is above normal ambient for the test item Y = Change in temperature required to double the aging rate for the materials in the assembly which requires the largest temperature change to halve its life. (See Table - pg. 4-13)
L = required test item life (hours)
Simulated normal aging time shall not be less than 100 hours0.00116 days 0.0278 hours 1.653439e-4 weeks 3.805e-5 months . Equipment s shall be continually energized during the aging test unless it can be T shown that aging in the deenergized state is more severe. Simulated s post accident aging may also be optionally modified according to Figure 4-3.
2. Required by IEEE Std. 323-1974, page 16. The peak temperature dwell time shall be one minute minimum.
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1 4-11
104-~
fig URE 4-3 AGE ACCELERATION VS TEMPERATURE 103 IE d.
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.a OE 9 102=
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5 _!
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f!OTES:
1. EACH SENTS .Y fEMPERATURE STEP NOR-F ABOVE THE AVERAGE REPRE-FOR THE En 101- -
MAL AMBIENT (See Pg. 4 ULPMENT11, note 1.)
BEING AGED.
~
9 2. EQUIPMENT SHALL BE ENERGlZED
~[ DURING AGE SIMULATION.
~
3.THE MINIMUM AGING TIME SHALL BE 100 HOURS FOR ANY TEMPERATURE.
O . . . . . . . . . m .
1 2 3 4 5 6 7 8 9 10 11 12 13 TEMPERATilRE STEP 9 ( X )
Table of "Y" Valves for Typical Materials of Class IE Assemblies ,
TEMPERATURE INCREASE TO HALVEg0MPONENT ,
SOURCE DESCRIPTION LIFE ( F)
MILHDBK 217A Vinyl-Nylon Wire 11.1 Type 1 Silicone Wire 28.4 FEP Wire Type K 13.7 McGrath, T. J. Resistors 12.8 Aging of Class 1E Modules, Paper IEEE Capacitors 6.9 Nuclear Power System Symposium Transistors 25.0 O Dec.12, 1974 T. W. Dakin, E.H. Henry, Polyester Amide Wire 28.0 and G. A. Mullen " Life Enamel, Kraft Paper Testing of Electronic Layer Insulation Power Transfonners, Part Power Transformers II, IEEE Transactions on Electrical Insulation, Vol . El-3, No.1, Feb.1963 i
AIEE Std.1 (now IEEE-273)
Standard Handbook for l Electrical Engineers, ninth Edition, McGraw Hill Book Co.
Section 4-382, 385 (6) Transformers 12.6 to 18 l
Class A Insulation 21 .6 1(a3
4-13 l
t
. Attachment I to:
ECP-L10-109, Rev. 1 Page 7 of 8 New Table and Page Table 4-1 Environmental Test for Equipment Not Subjected to Severe Accident Environments Maximum Values from Humidity Values
Table 3-1 Plus a Corresponding to
Margin of 150F Test Temperatures Test Temperature OF % Relative Humidity i
55 95 60 95 65 95 70 95 75 95 80 95 .
85 85 90 72 95 62 1 00 53 105 46 110 39 115 35 120 30 125 26 130 23 135 19 140 18 145 15 1 50 13 155 12 160 11 165 10 170 9 175 8 180 7 185 6 1 90 6 195 5 200 5 205 4 210 4 215 4 220 3 225 3 230 3 235 3 240 2 245 2 2 50 2 255 2 260 2 265 2 270 2
Values taken from B&R Letter BLOOOO7 "CRBRP - Environmental Envelope Temperature / Humidity Conditions for Class IE Equipment Subjected to Non-Severe Environments" dated 1/21/80.
l 1
a 4-14
5. DOCUMENTATION OF QUALIFICATION The overall documentation plan will consist of this generic interpretation parent document and a series of supplements, or " Equipment Qualification Data Packages. " One date package supplement will be submitted for each piece of Class 1E equipment or system as applicable upon successful qualifi-cation of the candidate equipment. This package provides the "Auditable Link" required by IEEE Std. 323-1974.
The preferred Equipment Qualification Data Package fonnat is illustrated in Appendix A.
i Any fonnat which meets the requirements of IEEE 323-1974 is acceptable.
x k
5-1
ACRONYMS ABHX Air Blast Heat Exchanger A/C Air Conditioning AFW Auxiliary Feedwater AFWS Auxiliary Feedwater System CAPS Cell Atmosphere Processing System ,
CB Control Building CIC Compensated Ion Chamber CIS Containment Isolation System CRBRP Clinch River Breeder Reactor Plant DBE Design Basis Event DGB Diesel Generator Building EVST Ex-Vessel Storage Tank FHC Fuel Handling cell HAA Head Access Area
HVAC Heating Ventilating and Air Conditioning IEEE The Institute of Electrical and Electronics Engineers, Inc.
IHTS Intermediate Heat Transport System PACC Protected Air Cooled Condenser PAM Post Accident Monitoring PPS Plant Protection System PHTS Primary Heat Transport System PWST Protected Water Storage Tank RMS Radioactive Argon Processing System RCB Reactor Containment Building RSB Reactor Service Building RSS Reactor Shutdown System
_ _ . _ _ , .,___,y . ,.-, , ---_-. ._ r ,
i .
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t
}
l ACRONYMS f SGB Steam Generator Building
! SGAHRS Steam Generator Auxiliary Heat Removal System SSE Safe Shutdown Earthquake SSST Site Suitability Source Term .
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l f
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f
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O
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V LIST OF REFERENCES (1) IEEE Std. 117-1974," Systems of Insulation Materials for Random-Wound A/C Electric Machinery, Std. Test Procedure for Evaluation Of".
(2) IEEE Std. 275-1966 (R-1972)," Systems of Insulation Materials for A/C Electric Machinery Employing Form Wound Pre-Insulated Stator Coils, Test Procedure for Evaluation Of".
(3) IEEE Std. 323-1974, "IEEE Standard for Qualifying Class 1E Equipment for Nuclear Power Generating Stations", February 28, 1974.
(4) IEEE Std. 323A-1975, " Supplement to the Foreward of IEEE Std. 323-1974".
(5) IEEE Std. 334-1974, " Standard for Type Tests of Continuous Duty Class IE Motors for Nuclear Power Generating Stations".
(6) IEEE Std. 344-1975, "IEEE Recommended Practices for Seismic Qualification of Class 1E Equipment for Nuclear Power Generating Stations".
(7) IEEE Std. 382-1972, " Trial Use Guide for the Type Test of Class 1 Electric Valve Operators fur Nuclear Power Generating Stations",
April 10, 1973.
(8) IEEE Std. 383-1974, " Standard for Type Test of Class IE Electric Cables, Field Splices and Connections for Nuclear Power Generating Stations".
(9) Regulatory Guide 1.89, " Qualification of Class 1E Equipment for Nuclear Power Plants", November, 1974.
(10) Regulatory Guide 1.73, " Qualification Tests of Electric Valve Operators Installed Inside the Containment of Nuclear Power Plants", (1/74).
(11) Regulatory Guide 1.40, " Qualification Tests of Continuous-Duty Motors Installed Inside the Containment of Water-Cooled Nuclear Power Plants",
(3/16/73).
(12) Best, Brotts, McLean, and Lampart, " Determination and Application of Aging Mechanisms Data in Accelerated Testing of Selected Semi-Conductors, Capacitors, and Resistors, ' National Symposium on Reliability and Quality Control 1965'",p. 293-302.
(13) Reynolds, Fredrick H., " Thermally Accelerated Aging of Semi-Conductor Components", IEEE Proc. Vol. 62 No. 2, Feb. 1974 (14) Wakefield Engineering Inc., " Guideline on Component Burn-In Technology".
A (15) Rabinowica, E., "McEntire R., and Sireklar B., " Technique for Accelerated Life Testing", ASME Transactions, August, 1970.
(V)
(16) Steck and Zimmer, Sandia Labs and New Mexico University, " Estimation of Acceleration and Aging Functions",1972.
(17) Wiksten, D. et.al., Jet Propulsion Lab. " Accelerated Life Testing of Spacecraft Subsystems", November,1972.
4, 1
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1 APPENDIX A i
i
! SAMPLE i
1' 5 EQUIPMENT QUALIFICATION DATA PACKAGE 4
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A-1
t CRBRP PROJECT
' Oak Ridge, Tennessee EQUIPMENT QUALIFICATION DATA PACKAGE COVER SHEET This cover sheet shows the revision status of the other sheets of the qualification data package. It is revised when any other sheet of the package is revised.
PAGE REVISION APPROVALS O
l 1
l I
EQUIPMENT ISSUED LAST REVISION PAGE OF PAGES i - - ___
EQUIPMENT QUALIFICATION DATA PACKAGE FORMAT The " Equipment Qualification Data Package (EQDP's) is intended as an 4
outline for the documentation of methods utilized to qualify safety related electrical equipment in a systematic and auditable fonn. The package is organized in five parts: (1)EquipmentIdentification; (2) Performance Specifications; (3) Qualification by Test; (4) Qual-ification by Experience; and (5) Qualification by Analysis. Parts 1 and 2 are required for each qualified safety class component (or conponent with attached safety class auxiliary devices). In addi-l tion, Parts 3, 4 and 5 should be completed as applicable.
l s
..-__----.--_..---.----..-.m.._.-- .---.__-~--.-,-----._---,..--___,----,.--_.--m----..--- - - , - -
4 EQUIPMENT QUALIFICATION DATA PACKAGE (PART 1 - IDENTIFICATION) i EQUIPMENT BEING QUALIFIED 2
Name:
1 e
i Manufacturer's Identification Number:
II l
l Design Specification Number:
Rev.
i \
Unusual Design Features of the Equipment (if any):
I i
l l If this equipment was qualified by type test and failures during the type test resulted in design changes, describe the failure analysis and the changes and provide the new manufacturer's Identification Num-ber below:
l
1 EQUIPMENT QUALIFICATION DATA PACKAGE (PART 2 - SPECIFICATIONS) 1.0 PERFORMANCE SPECIFICATIONS 1.1 Electrical Requirements 1.1.1 Voltage 1.1.2 Frequency 1.1.3 Load 1.1.4 Electromagnetic Interference 1.1.5 Other 1.2 Installation Requirements 1.3 Auxiliary Devices (l)
O 1.4 Preventative Maintenance Schedule 1.5 Design Life (2) 1.6 Operating Cycles (3) 1.7 PerformanceRequirements(4) i i 1.7.1 Normal 1.7.2 Abnormal 1.7.3 Containment Test 1.7.4 DBE 1.7.5 Post DBE O PAGE OF
\
.J 1.8 Environmental Conditions (5) 1.8.1 Temperature 1.8.2 Pressure 1.8.3 Humidity 1.8.4 Radiation 1.8.5 Chemical 1.8.6 Seismic 1.9 Projection Qualified Life (6) 1.10 Remarks 1.11 Part 1 Notes (1). List auxiliary devices required for proper operation of the qualified equipment and reference Qualification data sheet for auxiliary devices if qualified separately.
(2) Main equipment; if required auxiliary devices design life is different, so state.
(3) Expected number of operational cycles including testing during design life.
(4) Accuracy, duration of requirement, etc. , DBE is the Design Basis Event.
(5) Conditions and duration of each. Reference to standard curve may be used. Do not include margins.
(6) May be determined after qualification by test or analyses.
O PAGE OF
1 EQUIPMENT QUALIFICATION DATA PACKAGE (PART 3 - QUALIFICATION BY TESTS) 2.0 TEST PLAN 2.1 Equipment Description 2.2 Number Tested 2.3 Mounting 2.4 Connections 2.5 Aging Simulation Procedure 2.6 Simulated Environmental Conditions (I) 2.6.1 Temperature 2.6.2 Pressure 2.6.3 Humidi ty l
l j 2.6.4 Radiation l
2.6.5 Chemical 2.6.6 Seismic PAGE OF
.- - -- - _ . = .
I 2.7 Measured Variables Not 2.7.1 Category I - Environment Required Required )
2.7.1.1 Temperature
2.7.1.2 Pressure 2.7.1.3 Moisture Content
2.7.1.4 Gas Composition 2.7.1.5 Vibration 2.7.1.6 Time 2.7.2 Category II - Input Electrical Characteristics l 2.7.2.1 Voltage 2.7.2.2 Current
! 2.7.2.3 Frequency 2.7.2.4 Power 2.7.2.5 Other
! 2.7.3 Category III - Fluid Characteristics
2.7.3.1 Chemical Camposition 2.7.3.2 Flow Rate 2.7.3.3 Spray 2.7.3.4 Temperature 2.7.4 Category IV - Radiological Features 2.7.4.1 Energy Type 2.7.4.2 Energy Level 2.7.4.3 Dose Rate 2.7.4.4 Integrated Dose r
l l
PAGE OF l
1 - _ - - , _ . . - - - - - _ . . . - . _ , _ _ _ _ _ _ . _ _ . - _ _ _ , _ . _ _ _ _ _ _ . ___. __
1 2.7.5 Category V - Electrical Characteristics 2.7.5.1 Insulation Resistance 2.7.5.2 Output Voltage 2.7.5.3 Output Current 2.7.5.4 Output Power 2.7.5.5 Response Time 2.7.5.6 Frequency Characteristics 2.7.5.7 Simulated Load 2.7.6 Category VI - Mechanical Characteristics 2.7.6.1 Thrus t 2.7.6.2 Torque 2.7.6.3 Time 2.7.6.4 Load Profile 2.7.7 Category VII - Auxiliary Equipnent (List Function and Required Measurements) 2.7.7.1 2.7.7.2 l
2.7.7.3 2.7.7.4 l
l l
PAGE OF
1 i
2.8 Test Sequence Preferred (2) l 2.8.1 Inspection of Test Item 2.8.2 Operation (Normal Condition) 2.8.3 Operation (Perfonnance Specifications Extremes, Section 1) 2.8.4 Simulated A91ng(3) i 2.8.5 Vibration (4)
2.8.6 Operation (Simulated DBE Conditions)(3) 2.8.7 Operation (Simulated Post DBE Conditions)(3) 2.8.8 Disassembly and Inspection 2.9 Test Sequence Actual (l)
Step Justification 2.9.1 2.9.2 2.9.3 2.9.4 ,
2.9.5
2.9.6 2.9.7 l
2.9.8 l
2.10 Type Test Data 2.10.1 Objective l
2.10.2 Equipment Tested 2.10.3 Features Demonstrated by the Test 2.10.4 Description of the Test Facility l
L
! 2.10.5 Test Procedures l
__ _ - . . _ _ ____ _ _.. _. . - . _ . - - - - . _ . . - - _ .-_ PAGE ____ 07. _ .
I
)
) :
2.10.6 Test Data and Accuracy 2.10.7 Summary, Conclusions and Recommendations 2.10.8 Supporting Data (APPROVAL) (DATE) 2.11 Part 2 Notes (1) Reference to Standard Curve may be used. Margins per IEEE-323-1974 have been added.
(2) Paragraph 2.8 shows the preferred test secuence. Show actual sequence and justify in Section 2.9 (3) Aging and radiation may be combined. If combined, DBE and post DBE conditions need not include radiation.
(4) Simulated Seismic and other Nomal vibration seen in service O
PAGE OF suts
3 O EQUIPMENT QUALIFICATION DATA PACKAGE (PART 4 - QUALIFICATION BY EXPERIENCE) 3.0 OPERATING EXPERIENCE DATA 3.1 Interface cr Boundary Conditions 3.2 Qualification Features Demonstrated 3.3 Comparison of Experience and Specifications I
3.4 Summary and Source of Experience l
3.5 Qualification Basis O (APPROVAL) (DATE) l l PAGE OF l
i L5LD)
. 5
. l E00IPMEhiT QUALIFICATION DATA PACVAGE (PART 5 - QUALIFICATION BY ANhlYSIS)
~
. 4. 0 ANALYSIS .
'. 4.1 Interface er Boundary Conditions 4.2 Specific Features Analyzed
/
4.3 Assumptions and Mcdels -
1 I
I i
l -
l 4.4 Analytical Methods and Ccraputer Programs 4.5 Summary Co PAGE OF
. )

ML20050J052

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