Response to Request for Additional Information Related to Creats Actuation Instrumentation License Amendment Request, Attachments 1 - 4

ML022890157
Person / Time
Site:	Ginna
Issue date:	10/07/2002
From:	Mecredy R Rochester Gas & Electric Corp
To:	Clark R Document Control Desk, Office of Nuclear Reactor Regulation
References
Download: ML022890157 (146)
v • d • e

Text

R.E. Ginna Nuclear Power Plant Response to RAI Dated August 28, 2002 Enclosure Inovision Qualification Report 950.366

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Radiation Measurements, LLC May 15, 2001 Rochester Gas and Electric Corporation 89 East Avenue Rochester, NY 14649-0001

Reference:

Purchase Order 4500008671 This is to certify the Qualification Test Report and Data is true and accurate to the best of my knowledge. In addition, it is further certified that the qualification requirements of the above referenced Purchase Order have been fulfilled. The Qualification Test Report, Data and Appendices are intended to substantiate these statements.

David P. Warner Reliability Engineer Zisimos Quiatis Manager, Quality Assurance Qualification Report 950.366 Section 1 Page I of 2

Qualification Report 950.366 Section 1 Page 2 of 2 I

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Qualification Report 950.366 Qualification Report 950.366 Section 2 Page 1 of 2 1.0 Objectives 1.1 This report shall demonstrate that the Model 955A GM Area Monitor System is capable of operation prior to, during and after a Design Basis Event. This object will be accomplished using previously performed qualifications type tests on identical and equivalent equipment specimens.

1.2 This report shall demonstrate that the Model 955A GM Area Monitor System meets the contract specified environmental requirements.

For the 956A-201, previous qualification type tests will be used. In the case of the 897A-21 0 detector, temperature and humidity requirements exceed levels tested in prior qualification" reports for this device. To meet these requirements, type testing will be performed on two of the three detectors to be supplied under the contract.

1.3 This report shall demonstrate that the Model 955A GM Area Monitor System meets the contract specified Electromagnetic Compliance in accordance with EPRI TR-1 02323-RI. This will be accomplished by type testing actual and equivalent equipment specimens.

1.4 To demonstrate that the combined 955A radiation rate dependency and energy dependency are within +/- 20% of actual dose over the nominal rate range of the detector ( 0.01 - 1000 mR/h ) from 80 keV" to 1.5. Determination of low energy response shall be provided using X-ray techniques while upper energy response shall be determined using Cs-1 37 and Co-60. All X-ray and solid source techniques shall be NIST traceable.

1.5 To demonstrate stability of the detectors, ascending and descending plateaus shall be performed on all detectors to be supplied. In addition, repeated fixed voltage count rate tests shall be performed on all detectors.

Qualification Report 950.366 Section 2 Page 2 of 2 This page intentionally blank I

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Qualification Report 950.366 Section 3 Page 1 of 8 S1.0 Customer Requirements

.3 1.1 Seismic The following six pages contain the Operating Basis Event and Safe I

Shut-Down Event seismic response spectra for elevation 289' of the Ginna Nuclear Power Station Control Building.

1 1.2 AC Power Supply I

-20VAC-+/--10%---

1.3 Envir6nmental 1

1.3.1 Control Room 1040 F maximum, 0 PSIG, 60% RH, negligible background radiation.

1 1.3.2 Intake Duct p-101 F to 1221 F, 0 PSIG, 0- 100% RH "1.4 Electromagnetic Interference I

EPRI TR-1 02323-Ri : Guidelines for Electromagnetic Interference Testing in Power Plants i

1.5 Radiation Monitor Range Gamma Radiation from 1.OE-2 mR/h to 1 E3 mR/h over an energy range of 80 keV to 1500 keV

Qualification Report 950.366 Section 3 Page 2 of 8 This page intentionally blank.,

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I Qualification Report 950.366 Section 4 Page 1 of 2 S1.0 Standards The following Specification and Purchase Order apply to this report:

Rochester Gas & Electric Corporation Specification PCR 99- 004, I

EE-171 Revision I, dated 2125100 Rochester Gas & Electric Corporation Purchase Order 4500008671, Revision 4, 1/30/01 The preceding Specification and Purchase Order list the following Guidelines and Standards as requirements:

I American National Standards Institute ANSI N45.2.2,1972: "Packing, Shipping, Receiving, Storage and Handling of Items for Nuclear Power Plants" ANSI N42.3,1969: "ANSI/IEEE Standard Test Procedure for Geiger Muller (GM) Counters" Institute of Electrical and Electronic Engineers IEEE 344 - 1975 : "Recommended Practices for Seismic Qualification of Class 1 E Equipment for Nuclear Power Generating Stations" Additionally the following Regulatory Guide applies:

United States Nuclear Regulatory Commission Regulatory Guide 1.100, Revision 1, August 1977: "Seismic Qualification of Electric Equipment for Nuclear Power Plantso I

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Qualification Report 950.366 Section 4 Page 2 of 2 This page intentionally blank i

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Qualification Report 950.366 Qualification Report 950.366 Section 5 Page 1 of 10 1.0 Identification of Equipment 1.1 Equipment qualified under this report are listed below:

1.1.1 956A-201-Ml Universal Digital Ratemeter-modified 1.1.2 897A-210 Low Range Aluminum Housing GM Detector 1.1.3 948B-1-5 Rack Chassis 1.1.4 S157033A2 Surge Suppressor Assembly Pages 3 through 10 of this section contain the Bills of Material which provide a detailed description of the equipment listed above.

1.2 The following paragraphs detail differences in equipment to be qualified under this report as compared to type tested specimens listed in referenced qualification type tests.

1.2.1 The 956A-201-M1 differs from the 956A-201 specimen qualified under Seismic Test Report 950.353 in that the K1 auxiliary alarm relay is utilized as an additional contact set in the -Ml version. No mass or assembly changes associated with this modification as this relay is also installed in the standard 956A-201 unit as a non functional "spare".

The 956A-201-M1 differs from the 956A-200 specimen qualified under Environmental Test Report 950.360 in that the check source drive voltage is 15 VDC rather than 120 VAC as was used in the model 956A-200. The information in paragraph 1.2.1 also applies in that the K1 relay is not active in the 956A-200 unit. There are no weight or assembly differences between the 956A-201 and 956A 200.

1.2.2 The 897A-210 Detector differs from the 897A-220 specimen qualified under Seismic Test Report 950.353 in that it utilizes a low range rather than mid range GM tube. There is no difference mass or design.

alL.

Qualification Report 950.366 1

Section 5 Page 2 of 10 1.2.3 The S157033A2 Surge Suppressor Assembly consists of sub components of the Model 876A-1 High Range Containment Monitor and the 960PD-100-5 Power Distribution Assembly, a sub assembly of the 960WM-203-5 Wall Mount Enclosure. Seismic Qualification of the Model 876A-1 is detailed in Seismic Test Report 950.352. Qualification of the 960WM-203-5 is detailed in Seismic Test Report 950.338.

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PSO1SOR 300 AN300 QPADEVOOON Inovision Radiatio Product Stru Product No: 956A-201-H1 UDR W/AUXILARY HI ALARM OUTPUT Rev: 001 ECN: 4JR8-96 Drawing Number:

Item No. Product Number DrawingNo.

Siz Description 1 956A-201 RATEMETER DIGITAL AREA MONITOR 2 956A-201-M1HS MODIFICATION SHEET FOR 956A-20 3 200-135 200-135 B

NAME TAG in Measurements, LLC 3/16/01 7.19.03 PAGE 1

icture Quantity ECH 1.000 EA PS 2CR7-97 1.000 EA 1590 1.000 EA 1392 Rev Obs Act 5N Y

1 N

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PSO15OR 300 AN300 Inovision Radiation Measurements, LLC Product Structure 3/16/01 7.21.46 PAGE Product No: 956A-201-5 ASSEMBLY',

DIGITAL RATEMETER Rev: 002 ECH: 10CR40-95 Drawing Numbert Item No.

Product Number 1 956A-100-20 2 942A-100-30 4 956A-201-55 5 956-200-10 6 942-200-60 7 942A-100-24 8 942-100-25 9 5-532 10 5-706 11 5-186 12 5-836 13 200-135 14 5-710 16 92-9124-A 18 50-89 19 30-91-1 20 30-91-2 21 67-83-1P 22 92-9103-A 25 MSB-0072-35 26 MSB-0069 27 36-96-1 28 KSH-6222 29 67-78-2 30 942-100-35A 31 942-100-35B 32 942A-100-35C 33 942-100-35D 34 942-100-35E 35 MSB-0072-31 36 MSB-0072-32 37 SH-2202 38 942-100-28 39 5-953 40 5-678 41 MSH-6228 42 MSB-0072-2 DrawlngNo.

Sizi Description

ASSY, FRONT PANEL

ASSY, REAR PANEL t ASSEMBLY, POWER SUPPLY

ASSEMBLY, MAIN PC 1E C I ASSEMBLY, HIGH VOLTAGE BOARD TOP RAIL RAIL,BOTTOH

SCREW, MACH, PH, 4-40 X.38,

NUT, HEX, 4-40, NY, BO

SCREW, MACH, PH, 4-40 X.31,

WASHER, SPLIT, 4, SS 200-135 B

NAME TAG

WASHER, FLAT, 4,

NY, BO

COUPLER, FEMALE 50-89 B

COAXIAL CABLE Loc: 5" LONG I PIN, COAX i FERRULE INSERT,CONNECTORM,24-20 WIRE CONNECTOR, 4 POSITION, FEMALE

WIRE, HOOK-UP, 22 AWG, YEL/GRN Loc: 5" LONG L WIRE, HV, LEAD WIRE, 22, 10K V Loc: 3" LONG

TERMINAL, LUG,

SOLDER, FEMALE TUBING, 3/16, BLACK 67-78-TAB C

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SLONGWIRE, HOOK-UP, 22 AWG, YEL/BRN Loc: 5" LN I SLEEVE, SPIRAL-WRAP.06"-.5"OD OPTION BOARD SUPPORT MOUNT SCREW,TYPE 25,#4X.44LG,FH,PHIL

SCREW, MACH, RH, 4-40 X.31 TUBING, 1/4, BLACK

WIRE, HOOK-UP, 22 AWG, BLACK Quantity 1.000 1.000 1.000 1.000 1.000 2.000 2.000 4.000 1.000 8.000 8.000 1.000 1.000 1.000 1.000 1.000 1.000 5.000 1.000

.001 EA EA EA EA EA EA EA EA EA EA EA EA EA EA FT EA EA EA EA FT

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ASSEMBLY, Rev: 002 ECHt IOCR40-95 I

Drawing Number:

Item No.

Product Number Drawinglo.

Siý 43 5-193

• w EHD OF REPORT

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PSO150R 300 AN300 Inovision Radiation Measurements, LLC Product Structure 3/16/01 7.18.27 PAGE Product No: 897A-210 Rev: 003 ECNs 4CR3-96 Drawing Number:

DETECTORAREA MON.,GM,ALUMLOW Item No.

Product Number DrawingNo.

Siz Description Quantity ECH 897A-210-SA GEL897A-2XO CAL-GM6 92-7005-9A 92-7005-12A 92-7005-17A 8543-6-26 MB95-10a8 PER PRINT PER PRINT PER DWG D

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MAIN ASSYAL.HOUS.LOW RNG

DETECTOR, DIMENSIONAL OUTLINE 897A GM DET.

CALIBRATION PROC.

CLAMP BUSHING CONNECTOR, FEMALE WALL SUPPORT, DETECTOR MAINTENANCE BULLETIN 1.000

.001

.001 1.000 1.000 1.000 1.000

.001 EA EA EA EA EA EA EA EA PS 2CR7-99 1590 1590 1587 1587 1587 9CR34-98 1590 h** END OF REPORT

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MAIN ASSY,AL.HOUS.LOW RNG Item No. Product Number GT3 TP897A 1 857-210-18 2 857-10-25 3 897A-211-30 4 897A-210-10 5 857-210-20 6 857;1-18 7 857-10-22 8 HSB-0072-2 9 46-77 10 200-135 11 92-7005-20A 12 897-110-28 13 36-3 14 5-837 15 5-288 16 5-280 17 5-838 18 5-853 19 5-1011 21 MSA-0007 22 897A-210-13 23 857-10-7 24 MSJ-4372 27 MSH-6221 28 40-164 29 HSB-0072-16 30 MSB-0072-3 31 MSB-0072-15 32 MSB-0072-4 33 KSB-0069 34 200-122 35 200-53 36 5-712 37 5-852 DrawingNo. Siz Description TRAVELER FOR MECHANICAL ASSYS TEST PROCEDURE 857-210-18 HOUSING PROCESSED COVER PLATE PROCESSED (SA1 CHECK SOURCE MTG.

ASSEMBLY PER DWG B

ASSEMBLY DETECTOR PC BOARD 857-210-20 B TUBE & SHIELD ASSEMBLY LOW HOUSING INSULATOR PAD SCREW,SEEL,PH 6-32 SLOT.50 SS

WIRE, HOOK-UP, 22 AWG, BLACK O-RING, 3.489ID,.07 THK 200-135 B

NAME TAG PER PRINT D

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WIRE, HOOK-UP, 22 AWG, WHT/RED

WIRE, HOOK-UP, 22 AWG, GREEN

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2 2

3 6

5 3

5 8

2 2

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N N

N N

N N

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94as':I NBR.

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I Qualification Report 950.366 Section 5 Page 10 of 10 PAGE

• C.E lATERIAL 3AY CHASSIS REV:

A ECN: !IJR2-92 QUANTITY ECN NITOR 1.000 EA 11JR2-92 4.000 EA 11JR2-92

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PSO1S0R 300 ANSOD Product No: S157033A2 Rev: 001 ECN: 1656 Drawing Numbers S157053A2 QPADEVOOON Inovision Radiation Measurements, LLC Product Structure 3/16/01 7.45.37 PAGE 1

FILTER/SURGE SUPPRESSOR ASS'Y Item No. Product Number 92-9015-A 960SS-200 92-7041-2A 92-7044-A

$157033A21 MSB-0071-1 MSB-0071-2 HSB-0071-3 36-86 19-2 57-112

$157033A-105 5-277 5-304 5-261 5-853 39-48 5-766 14-235 DrawinoNo.

Siz Description FILTER POWER LINE PER BOM BM SURGE SUPPRESSOR 92-7041-2A B 12 POLE BARRIER STRIP WITH FUSE BLOCK,2 POSITION S157033A21 D CHASSIS, PROCESSED

WIRE, HOOK-UP, 18 AWG, WHITE

WIRE, HOOK-UP, 18 GA, BLACK WIRE, HOOK-UP, 18 GA,

RED, TFE

TERM, LUG, CRIMP, 22-16,

1. 6-8

FUSE, 2A 250V, 3AG TERMINAL STRIP, 6 POINT PER PRINT C

SCHEMATIC, SURGE SUPPRESSOR

SCREW, MACH,.FH, 6-32 X.44,

SCREW, MACH, PH, 6-32 X 1.00,

SCREW, MACH, PH, 6-32 X.25,

NUT, HEX, 6-32, SS

STANDOFF, H/F, 6-32 X.38, HEX

WASHER, INT, 6, SS NONE PH FERRITE CUBE Quantity 2.000 2.000 1.000 2.000 1.000

.000

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.000 28.000 4.000 1.000 1.000 4.000 4.000 8.000 16.000 4.000 16.000 2.000 EA EA EA EA EA FT FT FT EA EA EA EA EA EA EA EA EA EA EA ECH 1590 PS 1744 PS 1625 1590 1686 1590 1590 1590 1590 1590 1590 1740 1590 1590 1590 1590 1590 1590 1686 Rev Obs Act 5 14 3

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N I

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N 1 14 I

N I

Y N

1 N N

114 N

14 1 N Y

Y Y

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wie END OF REPORT J

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Quallfication Report 950.366 Qualification Report 950.366 Section 6 Page 1 of 74 1.0 Test Results This section contains the test data required to substantiate that the objectives set forth in Section 2 have been met.

1.1 Seismic Qualification of 955A and S157033A2 Components Appendix I, Qualification Type Test for Digital RMS Components, Report 950.353 details generic testing performed the 956A-201 Ratemeter, 897A-220 Detector and 948B-1 Rack Chassis. Pages 5 through 7 of this section show Ginna Required Response Spectra for SSE conditions plotted -against Tested Response Spectra envelope from Report 950.353.

Appendix II, Seismic Qualification Type Test 950.338 for Containment Atmosphere Monitor,for the Korea Electric Power Company's Kori 1, Kori 2 and Wolsung 1 Units. Report 950.338 details testing performed on the components of the S1 57033A2 Surge Suppressor Assembly. This report is applicable for all but the Line Filter ( p/n 92-9015-A ) sub-component of the S157033A2,

assembly. Pages 8 through 10 of this section show Ginna Required Response Spectra for SSE conditions plotted against the Tested Response Spectra envelope from Report 950.338.

Appendix III, Seismic Qualification Type Test for Analog RMS Components, Report 950.352 detail generic testing performed on the Model 876A-1 HRCM Readout Module. This module contains the Line Filter sub-component (92-9015-A) of the S1 57033A2 assembly. Pages 11 through 13 of this section show Ginna Required Response Spectra for SSE conditions plotted against the Tested Response Spectra envelope from Report 950.352.

1.2 Temperature and Humidity Tests 1.2.1 956A-201-M1 Ratemeter Appendix IV, Environmental Qualification Report for the Victoreen Digital Ratemeter, Report 950.360 details generic testing performed on 956A-200 series ratemeters. This report substantiates a qualified temperature range of -2.86 F to 1250 F at 90% RH ( non condensing ). In addition, Report 950.360 substantiates a qualified AC input power range of 90VAC/5OHz to 127VAC/63Hz for the 956A-200 series ratemeter.

Qualification Report 950.366 Section 6 Page 2 of 74 1.2.2 897A-210 Detector I

The temperature and relative humidity profile that the two specimen detectors were subjected to is shown in Figure 1, page 15 of this section. Both detectors were subjected to three 40-hour cycles of I

this profile. Detector performance was monitored via the analog output of its associated 956 series ratem.eter and logged on a multichannel recorder along with the environmental chamber 3

temperature and humidity. A Cs-137 solid source was placed equidistant between the detectors provided a nominal 2 mR/h rate.

Pages 16 through 28 of this section contain the entire strip chart i

record on the detector temperature and humidity test. No change in count rate (drift) was noted for either of the detectors at any point in the test cycles. These recordings provide substantive evidence that U

the Model 897A-210 detector meets all contractual environmental requirements.

I 1.3 Electromagnetic Compliance EMC testing, in accordance with EPRI Guide TR-1 02323-R1, was performed by an independent testing laboratory. The test specimen was an operating channel of 955A Area Monitor consisting of 75 U

feet of terminated 50-100 composite cable, 897A-21 0 Low Range GM Detector, 956A-201 Digital Ratemeter and the prototype S157033A2 Surge Suppressor. The ratemeter and surge I

suppressor were installed in a model 948B-1 rack chassis. A second non-operational ratemeter was installed in rack chassis to complete the equipment complement.

Pages 29 through 52 contain F-Squared Laboratories Report No.

CLE 033100-01 R1 detailing EMC testing and test results. The equipment, as tested, complied with the requirements of MIL-STD

.461 D,- CS 101, IEC 801-2, IEC 801-3, IEC 801-4, IEC 801-5 and IEC 801-6.

Drawing $157033A-104 defines the 50-100 composite cable shield grounding requirements that must be followed to achieve same level of electromagnetic immunity as tested. This configuration requires that the overall shield be grouinded at both the control room and detector location.

4 I

Qualification Report 950.366 Section 6 Page 3 of 74 1.4 Radiation Rate and Dose Dependency Energy dependency tests were'performed on two of the three 897A-210 detectors to be supplied under the purchase order. Serial numbers 131 and 132 were profiled in both the radial and axial modes using x-ray techniques equivalent to the following energies:

45, 68,100,148 and 180 keV. Solid sources were used for the 662 and 1200 keV. Page 53 through 58 provide the energy response curves as well as the raw data collected for both of the referenced detectors.

Rate dependency for all detectors is provided as part of the standard range calibration procedure CAL-GM1. Pages.59 through 64 contain the factory data sheets as well as raw range data.

1.5 Detector Stability Ascending and descending plateaus for all contractually supplied detectors are provided. A graphical plot of this data is included for each detector's ascending plateau. Additionally, repeated counts were taken for each detector at a fixed high voltage to demonstrate the stability of the selected operating point. Pages 65 through 70 of this section contain the raw plateau data and the graphical representations of this data. Pages 71 through 74 contain the repetitive count tests performed at a fixed high voltage value of 575 VDC. Testing performed utilized the internal operation check source of the detector as the radiation source for both plateau and repetitive count tests.

The GM tube utilized in the 897A-210 detector ( TGM ZP1320 ) has a manufacturer specified maximum slope of 8% over a 100 volt range from 525 to 625 VDC. The determination of % slope is obtained by the formula below:

(OC-C 1) 100 (C2+C1)/2 X (V2 -V 1) X100 Where : V1 and V2 are the plateau end points C0 is the count rate at V1 C2 is the count rate at V2

Qualification Report 950.366 Section 6 Page 4 of 74 The results of testing are summarized in the Table below:

Detector

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For a Digital Rate Meter, Detector and Cable Assembly

---

Manufacturer; T-esting-F-acity:---

Inovision Radiation Measurements. LLC F-Squared Laboratories 6045 Cochran Road 16740 Peters Road Cleveland, OH 44139 Middlefield, OH 44062 The Digital Rate Meter, model 956A-201, Detector 897A-210 and Cable Assembly (consisting of 75 feet of 50-100 composite cable terminated at both ends) were tested to the following Standards and were found to be in compliance with the requirements. A line filter assembly, part number S157033A2, was utilized to achieve the required compliance. The testing commenced on 9/26/00 and was completed on 9/29/00.

Standards:

Military Standard - Requirements for the Control of Electromagnetic Interference Emissions and Susceptibility (MIL-STD-461D and CS 101)

Electromagnetic Compatibility-Part 4: Testing and measurement techniques - Section 2: Electrostatic discharge immunity test, IEC 801-2 Electromagnetic Compatibility-Part 4: Testing and measurement techniques - Section 3: Radiated, radio-frequency, electromagnetic field immunity test, IEC 801-3 Electromagnetic Compatibility-Part 4: Testing and measurement techniques - Section 4: Electrical Fast Transient/burst immunity test, IEC 801-4 I

lectromagnetic Compatibility-Part 4: Testing and measurement techniques - Section 5: Surge Immunity test. IEC 801-5 I

Electromagnetic Compatibility-Part 4: Testing and measurement techniques - Section 6: Conducted Immunity test, IEC 801-6 Evaluation Conducted by:

Tony Masone EMC Manager Report Reviewed by:

- *'doert'Pellizze General Manager EMCIC"2 Rc% I

• uauiicauon ieporn EbU..bb Section 6 Page 29 of 74 EMC TEST REPORT Page I of 23

i.uaulcation Heport 95O7.3E Section 6 Page 30 o0 Client: Inovision Radiation Measurements, LLC Report No.: CLE 033 100-01 RI Model: 956A-201 Date: 12/13/00 Revision Date: 01/03/01 INDEX SectionI GENERAL REPORT

SUMMARY

1.0 ADMINISTRATIVE DATA 1.1 Management of Test Sample 1.2 Abbreviations and Acronyms

2.0 DESCRIPTION

OF TEST CONFIGURATIONS 2.1 Performance Criteria 3.0 LIST OF EUT, ACCESSORIES AND TEST EQUIPMENT 3.1 Equipment Under Test 4.0 MODE OF OPERATION 5.0 METHOD OF MONITORING 6.0 IMMUNITY PASS/FAIL CRITERIA 7.0 REQUIRED MODIFICATIONS 8.0 EMC TEST EQUIPMENT 9.0 ELECTROSTATIC DISCHARGE IMMUNITY TEST PROCEDURE 9.1 Electrostatic Discharge Immunity Test 9.2 Electrostatic Discharge Immunity Test Data Sheet 9.3 Photographs of Electrostatic Discharge Test a

10.0 RADIATED IMMUNITY TEST 10.1 Radiated Immunity Test Data Sheet 10.2 Photograph of Radiated Immunity Test Set-Up 11.0 ELECTRICAL FAST TRANSIENT/BURST IMMUNrTY TEST 11.1 EFT Immunity Test Data Sheet 11.2 Photograph of Electrical Fast Transient/Burst Immunity Test Set-Up 12.0 SURGE IMMUNITY TEST PROCEDURE 12.1 Surge Immunity Test 12.2 Surge Immunity Test Data Sheet 12.3 Photograph of Surge Immunity Test Set-Up 13.0 CONDUCTED IMMUNITY TEST PROCEDURE 13.1 Conducted Immunity Test 13.2 Conducted Immunity Test Data Sheet 13.3 Photograph of Conducted Immunity Test Set-Up 14.0 ELECTROMAGNETIC IMMUNITY CONCLUSION Ertr a'l Rot I Page 2 of 23 I

Client: Inovision Radiation Measurements. LLC Model: 956A-201 GENERAL REPORT

SUMMARY

This electromagnetic emission and immunity testing report was generated by F-Squared Laboratories. The test report is based on testing performed by F-Squared Laboratories personnel according to the measurement procedures described in the test specifications given below and in the -Test-Procedures-section-of-this-reportT.

SECTION TEST RESULTS 9

Electrostatic Discharge Pass 10 Radiated Immunity Pass 11 Electrical Fast Transient Burst Pass 12 Power Surge Immunity Pass 13 Conducted Immunity Pass E.MCOU2 kc% I Section 6 Page 31 of 74 Report No.: CLE 033100-01 RI Date: 12/13/00 Revision Date: 01/03/01 Page 3 of 23

Client: Inovision Radiation Measurements, LLC Model: 956A-201 1.0

'..(UCLmI 1%.CLUVjI I rleJJtu 1,U V.0 Section 6 Page 32 of Report No.: CLE 033100-01 RI Date: 12/13/00 Revision Date: 01/03/01 l

ADMINISTRATIVE DATA 1.1 Management of Test Sample The test sample was inventoried at the F-Squared Facility and returned to Inovision according to the agreement between FTSquared Laboratorids'arid the'clieiit.

1.2 Abbreviations and Acronyms The following abbreviations and acronyms may be used in this document AM BCI CDN EFT EMC EN ESD EUT GRP HCP IEC KHz LISN MHz OATS RF S/N VCP Amplitude Modulation Bulk Current Injection Coupling/Decoupling Network Electrical Fast Transients Electromagnetic Compatibility European Norm Electrostatic Discharge Equipment Under Test Ground Reference Plane Horizontal Coupling Plane International Electrotechnical Commission KiloHertz Line Impedance Stabilization Network MegaHertz Open Area Test Site Radio Frequency Serial Number Vertical Coupling Plane U

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EMC~u2 Rc% I

Client: Inovision Radiation Measurements, LLC Model: 956A-201 1/4?

2.0 DESCRIPTION

OF THE TEST CONFIGURATIONS 2.1 Performance Criteria IC 801-6 A

MIL STD 461D. CS 101 A

Section 6

-Page 33 of 74 Report No.: CLE 033100-01 RI Date: 12/13/00 Revision Oate: 01/03/01 Performance criteria A: The apparatus shall continue to operate as intended both during and after the test. No degradation of performance or loss of function is allowed below a performance level specified by the manufacturer, when the apparatus is used as intended.

Performance criteria B: The apparatus shall continue to operate as intended aftei the test. No degradation of performance or loss of function is allowed below a performance level specified by the manufacturer, when the apparatus is used as intended.

EN1C'iO.1 Rc I

Pg f2 SPECIFICATION PERFORMANCE CRITERIA IEC 801-2 B

IEC 801-3 A

B IEC 801-5 Paz~e 5 of 23

Client: Inovision Radiation Measurements, LLC Model: 956A-201

,4uaifcation Heport'950.366 Section 6 Page 34 of 71 Report No.: CLE 033100-01 R I Date: 12/13/00 Revision Date: 01/03/01 l

3.0 LISTS OF EUT, ACCESSORIES AND TEST EQUIPMENT 3.1 Equipment Under Test (EUT)

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i Device Manufacturer Model #

Serial #

Digital Rate Meter Inovision Radiation 956A-201 Calab I Measurements, LLC

--GM-,trf-aM:

iiitof

.loivfsfn R:diati~rf-89TA-210-....

-131 Detector Measurements, LLC Cable Assembly Inovision Radiation 50-100 N/A Measurements, LLC Line Filter/Surge Inovision Radiation S 157033A2 Prototype Suppressor Assembly Measurements, LLC Rack Chassis Inovision Radiation 948B-1 N/A Measurements, LLC EMC* B'e,,..

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I Section 6 Page 35 of 74 Report No.: CLE 033100-01 RI Date: 12/13/00 Revision Date: 01/03/01 4.0 MODE OF OPERATION The un-was fully operational in phases of the test.

5.0 METHOD OF MONITORING The display of the EUT was visually monitored.

6.0 IMMUNITY PASS/FAIL CRITERIA The unit was monitored and the following criteria was used to define a non-compliance:

1. Rate increase above I mPihr and subsequent alarm (Alarm setpoint 1 mR/hr).

2. Microprocessor failure/lock-up indicated by fail alarm.

3. Loss of setpoints/Alteration of setpoints.

4. Failure to respond to Check Source command.

7.0 REQUIRED MODIFICATIONS The grounds of the signal line were required to be terminated at both ends of the cable.

A ferrite bead, Corcom Filter. and a Surge Suppressor were added to the AC Power lines.

This assembly is identified as the prototype S157033A.2 filter assembly.

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EM'iJ'12 gci I Page 7 of 23 Client: Inovision Radiition Measurements. LLC "Model: 956A-201 I

Client: Inovision Radiation Measurements, LLC Model: 956A-201 8.0 EMC Test Equipment

• Qualification Repott 950.36E Section 6 Page 36 of Report No.: CLE 033 100-01 RI Date: 12/1.3/00 Revision Date: 01103/01 I Equipment Type Manufacturer Model Serial Cal. Due Number Date Shield Room Shielding Resources 3 meter 001 Mar. 2001 AC Power System California Instruments 500 IIX-CTS 52840 Oct. 2001 LISN Fisher Custom Comm 50/250-25-4 9600 Aug. 2001 Antenna I..

EMC-TestSystems 3143 Bicolilog 1229 Nofieqtzired OATS Compliance Labs NA 001 Aug. 2001 PLDCN Fisher Custom Comm 801-M3-16A 97-12 Sept. 2001 Antenna 2 EMC Test Systems 3143 Biconilog 9609-1306 July 2001 ESD generator Haefely Trench PESD 1600 N/A Dec. 2000 Humidity/Temp G Thermo-Hygro Radio Shack 100 N/A Dec. 2000 Surge Generator EM Test VCS 500 21527 Dec. 2000 EFT generator Haefely Trench PEFT Junior 83818.*1 Dec 2000 Sxgnal Generator Giga-tronics 6061A 9618911Ian 2001 Field Probe Chase EMC 20 22441229 Ma.20 EMC1t'2 Rc' I

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II 83818 Dee_ 2fl00 I

9618911 Jan_ 2001

Section 6 Page 37 of 7, Client: Inovision Radiation Measurements, LLC Report No.: CLE 033100-01 RI Model: 956A-201 Date: 12/13/00

"ý' I Revision Date: 01/03/01 9.0 ELECTROSTATIC DISCHARGE IMMUNITY TEST PROCEDURE I

9.1 Electrostatic Discharge Immunity Test (ESD)

The ESD generator and discharge gun was used to conduct the tests outlined below.

The waveform conforms to IEC 801-2. This generator was used to simulated electrostatic discharges to the EUT. The EUT was placed on a non-conductive material 0.5 mm above a horizontal coupling plane (HCP) conforming to the dimensions of EC 801-2. The horizontal coupling plane and.the.vertical -coupling-plane -were -connected to-the -ground reference-place-through -two-470 KOhm resistors. During the test, three different methods were used to determine if the equipment was susceptible to ESD. They consisted of Direct Contact, Air Discharge and Indirect discharge.

The direct contact method was used on all exposed conductive surfaces.

Each point was contacted 10 consecutive times in the positive polarity and 10 consecutive times in the negative polarity with an electrostatic discharge from the ESD Gun. The Indirect discharge method was used on-one point of the horizontal coupling plane (HCP) and to one point on the vertical coupling plane (VCP) located 10 cm from the edge of the EUT on all four sides of the EUT. The Air Discharge method was used on all exposed non-conductive materials. These materials were scanned with the tip of the ESD gun. if the gun discharged at any point, 10 consecutive discharges in both positive and negative polarities were then made to that point.

Page 9 f of 23 ENIC'M2 Rv I

Client: Inovision Radiation Measurements. LLC Model: 956A-201 wuaimcatlon Hepon 950.366 Section 6 Page 38 of 1 Report No.: CLE 033 100-01 RI Date: 12/13/00 Revision Date: 01/03/01 Electrostatic Discharge Immunity Test Data Sheet Test Date:

9/26100 Test Engineer:

Tony Masone Standard:

EEC 801-2 Air Temperature:

170C Performance B

Relative Humidity:

629o Criteria:

Conductive Surfaces EMChT2 Rc% I U

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9.2 Discharge Point Level Method Pass / Fail Vertical Coupling Plane - Right Side

++/-4 kV Contact Pass Vertical Coupling Plane - Left Side

+4 kV Contact Pass Vertical Coupling Plane - Front Side

+/- 4 kV Contact Pass Vertical Coupling Plane - Back Side

+4 kV Contact Pass Horizontal Coupling Plane

+4 kV Contact Pass Conductive Surfaces

+/- 4 kV Contact Pass

Client: Inovision Radiation Measurements, LLC Model: 956A-201 section 6

. Page 33 of 74 Report No.: CLE 033100-01 RI Date: 12/13/00 Revision Oate: 01/03/01

2.0 DESCRIPTION

OF THE TEST CONFIGURATIONS 2.1 Performance Criteria SPECIFICATION PERFORMANCE CRITERIA IEC 801-2 B

IEC 801-3 A

IEC-8S0 15 B-----__

SIEC 80-5B IEC 801-6 A

MIL STD 461D. CS 101 A

Performance criteria A: The apparatus shall continueto operate as intended both during and after the test. No degradation of performance or loss of function is allowed below a performance level specified by the manufacturer, when the apparatus is'used as intended.

Performance criteria B: The apparatus shall continue to operate as intended aftei the test. No degradation of performance or loss of function is allowed below a performance level specified by the manufacturer, when the apparatus is used as intended.

Page 5 of 23 ExlCW2 Pc%- I

Client: Inovision Radiation Measurements, LLC Model: 956A-201 wumanrcauon Heport '950.366 Section 6 Page 34 of 73 Report No.: CLE 033 100-01 RI I Date: 12/13/00 Revision Date: 01/03/01 1

3.0 LISTS OF EUT, ACCESSORIES AND TEST EQUIPMENT 3.1 Equipment Under Test (EUT)

Device Manufacturer Model #

Serial #

Digital Rate Meter Inovision Radiation 956A-201 Calab I Measurements, LLC

-G-M-Area-h~oit~?T...... 6vis i~iR-diato-Ff-....

89TA-.21F...

131.....

Detector Measurements, LLC Cable Assembly Inovision Radiation 50-100 N/A Measurements, LLC Line Filter/Surge Inovision Radiation S157033A2 Prototype Suppressor Assembly Measurements, LLC Rack Chassis Inovision Radiation 948B-1 N/A Measurements, LLC E1,C0.,2 Rc. I U I I

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Section 6 Page 35 of 74 Client: Inovision Radiition Measurements. LLC Report No.: CLE 033100-01 RI "Model: 956A-201 Date: 12/13/00 Revision Date: 01/03/01 I

4.0 MODE OF OPERATION The un5.' was fully operational in phases of the test.

5.0 METHOD OF MONITORING The display of the EUT was visually monitored.

i 6.0 IMMUNITY PASS/FAIL CRITERIA The unit was monitored and the following criteria was used to define a non-compliance:

I

1. Rate increase above 1 mR/hr and subsequent alarm (Alarm setpoint 1 mR/hr).

2. Microprocessor failure/lock-up indicated by fail alarm.

3. Loss of setpoints/Alteration of setpoints.

4. Failure to respond to Check Source command.

7.0 REQUIRED MODIFICATIONS The grounds of the signal line were required to be terminated at both ends of the cable.

S
.A ferrite bead, Corcom Filter, and a Surge Suppressor were added to the AC Power lines.

This assembly is identified as the prototype S157033A2 filter assembly.

Page 7 of 23 fECI))2 Rc%* I

Client: Inovision Radiation Measurements, LLC Model: 956A-201 8.0 EMC Test Equipment Qualification Report 950.36f Section 6 Page 36 of Report No.: CLE 033 100-01 RI I

Date: 12/1/00 Revision Date: 01/03/01 I Equipment Type Manufacturer Model Serial Cal. Due Number Date Shield Room Shielding Resources 3 meter 001 Mar. 2001 AC Power System California Instruments 5001IX-CTS 52840 Oct. 2001 LISN Fisher Custom Comm 50/250-25-4 9600 Aug. 2001 SAntenna I..

EMC-TestSystems -

........ 3143Biconilog"........- -. 1229 ---

iN-fi*6d OATS Compliance Labs NA 001 Aug. 2001 PLDCN Fisher Custom Comm 801-M3-16A 97-12 Sept. 2001 Antenna 2 EMC Test Systems 3143 Biconilog 9609-1306 July 2001 ESD generator Haefely Trench PESD 1600 N/A Dec. 2000 Humidity/Temp G Thermo-Hygro Radio Shack 100 NIA Dec. 2000 Surge Generator EM Test VCS 500 21527 Dec. 2000 EFT generator Haefely Trench PEFT Junior 83818 Dec. 2000 Signal Generator Giga-tronics 6061A 9618911 Jan. 2001 Field Probe Chase EMC 20 2244/29 Mar. 2001 I

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Section 6 Page 37 of 7' l

Client: Inovision Radiation Measurements, LLC Report No.: CLE 033100-01 RI Model: 956A-201 Date: 12/13/00 Revision Date: 01/03/01 i

9.0 ELECTROSTATIC DISCHARGE IMMUNITY TEST PROCEDURE 1

9.1 Electrostatic Discharge Immunity Test (ESD)

'The ESD generator and discharge gun was used to conduct the tests outlined below.

The waveform conforms to-IEC 801-2. This generator was used to simulated electrostatic discharges

-to the EUT. The EUT was placed on a non-conductive material 0.5 mm above a horizontal coupling plane (HCP) conforming to the dirinensions of fEC 80 -2. The horizontal coupling plane

.and.the.v.ertical.coupling-plane -were.connected to -the -ground reference -place-through.two-470 KOhm resistors. During the test, three different methods were used to determine if the equipment was susceptible to ESD. They consisted of Direct Contact, Air Discharge and Indirect discharge.

The direct contact method was used on all exposed conductive surfaces.

Each point was contacted 10 consecutive times in the positive polarity and 10 consecutive times in the negative polarity with an electrostatic discharge from the ESD Gun. The Indirect discharge method was used on one point of the horizontal coupling.plane (HCP) and to one point on the vertical coupling plane (VCP) located 10 cm from the edge of the EUT on all four sides of the EUT. The Air Discharge method was used on all exposed non-conductive materials. These materials were scanned with the tip of the ESD gun. if the gun discharged at any point, 10 consecutive discharges in both positive and negative polarities were then made to that point.

Page 9 of 23 EMT(N'21 Re%* I

Client: Inovision Radiation Measurements., LLC Model: 956A-201

• uarlncatgon Heportf 950.366 Section 6 Page 38 of Report No.: CLE 033100-01 RI I

Date: 12/13/00 Revision Date: 01/03/01 i

9.2 Electrostatic Discharge Immunity Test Data Sheet

• Test Date:

9/26/00 Test Engineer:

Tony Masone Standard:

lEC 801-2 Air Temperature:

170C Performance B

Relative Humidity:

62% a Criteria:

Conductive Surfaces Discharge Point Level Method Pass / Fail Vertical Coupling Plane-Right Side

+/-4 kV Contact Pass Vertical Coupling Plane - Left Side

+4 kV Contact Pass Vertical Coupling Plane - Front Side

+/- 4 kV Contact Pass Vertical Coupling Plane - Back Side

+/-4 kV Contact Pass Horizontal Coupling Plane

+ 4 kV Contact Pass Conductive Surfaces j

.+ 4 kV Contact Pass EMCwI2 Rc% I V

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Section 6 Page 39 of 74 Report No.: CLE 033100-01 RI Date: 12/13/00 Revision Date: 01/03/01 9.3 Photographs of the Electrostatic Discharge Test Set-Up v~im-I E\\I( thj2 Re. I Page II of'23 Client: Inovision Radiation Measurements, LLC Model: 956A-201

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Client: Inovision Radiation Measurements. LLC Model: 956A-201 Section 6 Page 40 of Report No.: CLE 033 100-01 RI Date: 12/13/00 Revision Date: 01/03/01 E

Front View of the EUT during the Electrostatic Discharge Test Page 12 of 23 E'Aý"(1! K,,

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Section 6 Page 41 of 74 SClient: Inovision Radiation Measurements, LLC Report No.: CLE 033 100-01 R1 Model: 956A-201 Date: 12/13/00 h

"Revision Date: 01/03/01 10.0 Radiated Immunity Test The Eq~ipment Under Test (EUT) was placed in a fully anechoic chamber on a non-conductive turntable. A broadband antenna was placed three meters from the EUT and was used to radiate RF energy in both horizontal and vertical polarities at the EUT.

The RF energy consisted of a signal that was stepped at I% increments through the frequency range of 80 MHz to 1000 MHz at a rate slower than the reaction time of the EUT. Th' signal was 80% AM modulated with a I KHz sine wave and had a minimum calibrated 'ield strength of 3.0 volts/meter at the surface of the EUT. The signal was also pulsed modulated at 200 Hz in the frequency range of 895 MHz to 905 MHz. The EUT was exposed to the RF energy on four different surfaces (Front, Back. Left and Right sides).

I The test set up conformed to figure 2 of IEC 801-3.

Page 13 of 23 E%1011I'2 Rc, I

Client: Inovision Radition Measurements, LLC Model: 956A-201 Uualitication Report 950.866 Section 6 Page 42 of '

Report No.: CLE 033100-01 RI Date: 12/13/00 Revision Date: 01/03/01 n

10.1 Radiated Immunity Test Data Sheet ITest Date:

I 926/00 Test EIngineer:

I Tonv Masone Standard:

IEC 801-3 Performance Criteria:

A Side of EUT Exposed to Antenna Frequency Range Minimum Pass/Fail Antenna Polarization Calibrated RF Field Strength Front Horizontal 80 MHz to 1000 MHz 10.0,v/m Pass Right Side Horizontal 80 MHz to 1000 MHz 10.0 v/M Pass Back Horizontal 80 Nff-lz to 1000 MHz 10.0 v/m Pass Left Side Horizontal 80 MfHz to 1000 M-Hz 10.0 v/m Pass Front Vertical 80 MHz to 1000 MHz 10.0 v/m Pass Right Side Vertical 80 Miz to 1000 Hz 10.0 vim Pass Back Vertical 80 MHz to 1000 NI/z 10.0 v/m Pass Left Side Vertical 80 MHz to 1000 MHz I10.0 vin Pass EMCI02 Rex I I

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Section 6 Page 43 of 74 Client: Inovision Radiation Measurements, LLC Model: 956A-201 Report No.: CLE 0.33100-01 RI

-Date: 12/li/00 Revision Date: 01/03/01 10.2 Photograph of the Radiated Immunity Test Set-Up I-.

I Page 15 of 23 F ýi1.,"" -2e Ro

Client: Inovi'ion Radiation Measurements, LLC Model: 956A-201 Qualification Report'950. fl Section 6 Page 44 of Report No.: CLE 033 100-01 RI Date: 12/13/00 Revision Date: 01/03/01 U

11.0 Electrical Fast Transient/Burst Immunity Test The Electrical Fast Transient Burst generator was used to conduct the tests outlined below.

The waveform conforms.to IEC 801-4. This generator was used to simulate RF energy coupled onto power and data cables from switches, relays, motors. and any other device that could produce a voltage "spike".

During the testing, the product was placed on a non-conductive table conforming to the dimensions of IEC 801-4. The set-up conformed to IEC 801-4, figure 7.

The transient energy (as defined in IEC 801-4) was coupled on the cables under test at various levels and polarities as defined by the standard. (Refer to the test page for the details of this test).

During the test, all data cables that may have a practical length greater than 3 meters, and all power mains cables were tested as outlined below.

Data Lines The transient energy was coupled through a capacitive coupling clamp from the EFT generator to the data lines.

AC Mains The transient energy was coupled through the EFT generator coupling/decoupling network to each conductor of the power mains cable with respect to ground.

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Client: Inovision Radiation Measurements, LLC Model: 956A-201 Section 6 Page 45 of 7 Report No.: CLE 033100-01 RI Date: 12/13/00 Revision Date: 01/03/01 11.1 EFT Immunity Test Data Sheet Test Date:

Standard:

Performance Criteria:

9/26100 IEC 801-4 B

Test Engineer:

Air Temperature:

Relative Humidity:

Tony Masone 200C 52%

• DATA LINES

-.Descrintion of-Data-Line [Test -Level- -Polarity--

Test-duration-T.

-Pass/Fail.

3.0 kV

+

1 minute Pass 3.0 kV I minute Pass Page 17 of 23 EMICt(I" kc% I

!Signal Line Signal Line

Client: Inovision Radiation Measurements, LLC Model: 956A-201 ku~iiijcm+/-on rieport 950.5, Section 6 Page 46 of 1 Report No.: CLE 033 100-01 RI I Date: 12/13/00 Revision Date: 01/03/01

[

11.2 Photograph of the Electrical Fast Transient Immunity Test Set-Up aI i

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Section 6 Page 47 of 7, Client: Inovision Radiation Measurements, LLC Report No.: CLE 033100-01 R I Model: 956A-201 Date: 12/13/00 Revision Date: 01/03/01 I

12.0 SURGE IMMUNITY TEST 12.1 Surge Immunity Test I

The test was performed the unit as per IEC 801-5. The surge pulse duration from the combination wave generator was 1.2 x 50 gs voltage into an open circuit as high as 2kV and a 8 x 20 ps current pulse into a short circuit. Each pulse was injected 10 times in each polarity with a minimum of 60 second interval between each pulse. The unit set up was similar to the schematic shown in Figure 8 of EC 801-5.

I AC Mains The AC Mains lines were coupled to the Surge/EFT generators coupling/decoupling network.

Surges were applied to each AC line and protective earth in both common and differential mode injections.

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.12.2 Surge Immunity Test Data Sheet I Test Date:

19/26/00 ITest Engineer:

ITony Masone Standard:

IEC 801-5 Performance Criteria:

B Cable Designation Level Phase Pass/Fail AC Port Testing (kDN) o I

Differential Mode Injiection Tests Line I to Line 2

+3.0 0-360 Pass Line I to Line 2

-3.0 0 - 360 Pass Common Mode Injection Tests Line 1 to Earth

+3.0 0-360 Pass Line I to Earth

-3.0 0-360 Pass Line 2 to Earth

+3.0 0-360 Pass Line 2 to Earth

-3.0 0-360 Pass Page 19 of 23 E\\IC0)o Re, I

Client: Inovision Radiation Measurements, LLC Model: 956A-201 12.3 Photograph of Surge Immunity Test Set-Up E\\I~V,2 Re. I Pave 20 of 23 I

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Section 6 Page 48'ofj Report No.: CLE 033.100-01 Ri I Date: 12/13/00 Revision Date: 01/03/01

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Section 6 Page 49 of 74 Report No.: CLE 033 100-01 RI Date: 12/B/00 Revision Date: 01/03/01 13.0 CONDUCTED IMMUNITY TEST PROCUDURE 13.1 Conducted Immunity Test The Equipment Under Test (EUT) was placed in a fully anechoic chamber 10 cm above a GRP.

A coupling/decoupling network was connected to the EUT.'s power cord and was used to couple RF energy onto all lines of the power to th6 EUT. A bulk current injection (BCI) was used to couple RF energy onto all data, control and I/O lines that may exceed 3 meters in length.

The RF energy consisted of a signal.that was stepped at 1% increments through the frequency range of 150 KHz to 80 MHz at a rate slower than the reaction time of the EUT. The signal was 80% AM modulated with a I KHz sine wave and had a minimum calibrated level of 3.0 Volts.

The test set up conformed to figure 2 of IEC 801-6.

13.2 Conducted Immunity Test Data Sheet Test Date:

9/26/00 Test Engineer:

Tony Masone Standard:

IEC 801-6, MIL-STD 461D, Performance Criteria:

A CS 101 Line Tested Frequency Range Minimum Calibrated RF Pass/Fail Level AC Power lines 150 KHz to 80 M[Hz 6.3 Vrms Pass Signal Line 150 KHz to 80 MH 6.3 Vrms Pass Line Tested Frequency Range Minimum Calibrated RF Pass/Fail Level AC Power lines 30 Hz to 50 kHz 136 dButV Pass Page 21 of 23 Client: Inovision Radiation Measurements, LLC Model: 956A-201 El10102 Re, !

Client: Inovision Radiation Measurements, LLC Model: 956A-201 Section 6 "Paga 50 of Report No.: CLE 033100-01 R I

Date: 12/13/00 Revision Date: 01/03/01 13.3 Photograph of the Conducted Immunity Test Set-Up CI L

.4

-2

-t 

'-

-t

--44 C

I C

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Client: Inovision Radiation Measurements, LLC Model: 956A-201 Section 6 Page 51 of 7 Report No.: CLE 033 100-01 RI Date: 12/13/00 Revision Date: 01/03/01 14.0 ELECTROMAGNETIC IMMUNITY CONCLUSION The Digital Rate Meter, model 956A-201, Detector 897A-210 and Cable Assembly (consisting of 75 feet of 50-100 composite cable terminated at both ends) complied with all of the requirements of the IEC 801-2. IEC-3, IEC 801-4: IEC 801-5. IEC 801-6. and MIL-STD-461D.

CS 101.

Page 23 of 23 EMtC11j2 Rct I

Qualification Report 950.366 Section 6 Page 52 of 74 This page intentionally blank I

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897Asn131grph Energy Response: 897A-210 Serial Number 131 180 662 I-Seriesi Energy In keV Pa I

E (D

C0j..

cvo

~U)

CD

.. n t

20 Oc LE 0 C/

1.2 1

0.8 0

Z(0 0.4 0.2 0

45 68 -

100 148 1200

g-rUm 897A-210-131 or)

LON 06 cD~

0 OC 0 a)~

QCfj Date:

H-f60 H1 00 HVi 5-0 H200

-H250

'9/21/0 HVL 6

1-3.5 17 19.8 22 0

0 nC 2.ýK852 2.851 0.9342 5.735 5.721 3.903 3.902 5.86 5.877 Energy 68 180 662 1200 857 ReadhnC (mRlhr) 14.1 14.2 41 41 225 226 195 195 291 291 Relative Resp 0.91 0.85 0.92 0.98 1

0.99 60 100 1150 V15Fn50 200 250--0 250-O 250 Dflse mRA 5

5 3

3 3

3 3

3 3

Through Side Time (min' 1.5 1.5 1.5 1.5 1.5 1.5

• Di1 st.

300 300 300 300 3500 300O 300 300 300 300

,RITC 1.750E-0 1.750E-0 1.200E-0 1.200E-03 1.1I 60-E-0 :

1.160E-03 1.356E-03 1i.356E-03 1.259E-04 1.259E-0 mR/hr

% Error 3

199.64

-92.94%

3 199.57

-92.88%

3 45.0624

-9.02%

3 44.8416

-8.57%

3266.1346197

-15.46%

265.484945

-14.87%

-7.89%

211.64448

-7.86%

295.1096

-1.39%

i295.96572

-1.68%

LO~ "60

• Q )

() I n-n Cý 897A-210-131 Date:

H60 Hi1100 H200 7H250 9/21100 nC 2.82 2.835 0.9301 0.9409 5.844 5.847 3.856 3.852 6.2.24 E6.221 MnrY 897 Reading kV (mRPhr) 29 60 29 60 46.9 loo 47.4 100 242 150 242 150 186 200 186 200 263 250 263 250 Relative Response I

-t 4I------

I "Time (min) 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 45 0.15

~ 68 1.05 100

'0.89 148 0.89 180 0.84 662 1

1200 0.95

-l Throug°op m

M m

m m

m m

5 3

3 3 3

3 3 3

3 Dist.

(cm) 3OO 300 30O 300 300 300 300 300 300 R/TC-mPriRhr 1.750E-03 197.4 1.750E-03 198.45 1.200OE-03 44.6448 1.2001E-03 45.1632 1.160E-03 271.1928017 1.-160E-03 -271.3320177 1.356E-03 209.14944 1.356E-03 208.93248 1.259E-03 313.44064 1.259E-03 313.28956

,*5 0.15 S......

61]

'1.05 166 o.89 148 0.89 i

180 0.84 S

6*2 1

12()0 0.95

%'6E rro r

-85.31%/

_85.39%

L5.05%

4.95%

ý-1l0.76%

-10.81%

-11.07%

-10.98%

-16.09%

-16.05%

-- Vi T

897Asn132grph (C0 Energy Response: 897A-210 Serial Number 132 in.

4 do) tco CL 0

4-0

CD a ch 68 100 148 180 662 1200 Energy In keV Page 1 1.2 1

0.8 0.6 0.4 0.2

4)

U) c 0

CL I-Seriesi I 0- 4 45 I

897A-210-132 Throi ide M

i I

m 16

~U

=0 E~n

}ut Date:

9/21/00 1

HV L nC 857 Readin]d kV mA Time Dist.

RITC mR/hr

% Error (mR/hr)

(min)

(cm)

H-160 6

4.692 59.1 60 5

1.5 300 1.750E-03 328.44

-82.01%

4.716 59.3 60 5

1.5 300 1.750E-03 330.12

-82.04%

H100 13.5 1.62 90.2 100 3

1.5 300 1.200E-03 77.76 16.00%

1.5903 88.9 100 3

1.5 300 1.200E-03 76.3344 16.46%

H150 17 5.933 287 150 3

1.5 300 1.160E-03 275.3228769 4.24%

5.96 287 150 3

1.5 300 1.160E-03 276.575821 3.77%

H200 19.8 3.863 220 200 3

1.5 300 1.356E-03 209.52912 5.00%

3.84 219 200 3

1.5 300 1.356E-03 208.2816 5.15%

,H250 22 6.435 322 250 3

1.5 300 1.259E-03, 324.0666

-0.64%

6.44 324 250 3

1.5 300 1.259E-03 324.3184

-0.10%

Energy Relative Res )onse 45 0.18 68 1.16 100 1.04 148 1.05 180 1.00 1

1200 0.984375

7 V

mo-"

897A-210-132 Date:* IgWglinni 1-1 1

HVL nC I

U

__I I

857 Reading (mR/hr) kV mA Time (mai)

I 6

1 1.9015 20.5 60 5

1.5 Dist.

(cm)

RITC mRPhr

% Error 1.91 20.5 60 5

1.5 300 1.750E-03 133.7 HM00 13.5 0.7098 32.5 100 3

1.5 300 1.200E-03 34.0704 0.7095 32.5 100 3

1.5 300 1.200E-03 34.056 30 S0-nA 114I 1::;z co r0 0

co 0 0 3.985 3.733 172 172 185 150 150 3

1.5 1.5 300 1.160E-03 184.6468443 300 1.160E-031 184.9252763 t

J3;;

-T

-0.0a-10 3.7354 185 1 200

-3 1.5 300 1.356E-03 202.608096

-8.69%

H250 22 6.378 259 j

250 3

1.5 300 1.259E-03 321.19608

-19.36%

6.344 258 250 3

1.5 300 1.259E-03 319.48384

-19.24%

Co-60 Energy Relative Res onse 45 0.15 68 0.95 100 0.93 148 0.91 180 0.81 662 1

1200 0.964843751-

-84.60%

-84 67%

-4.61%

-4.57%

-6.85%

-6.99%

on') A77n 6

n Through Top H60 H200 19.8 "n lUUI I I 200 3

15R

.nn I -arrr: _n-L);*t(*:

gDllnn

[

l*q 1N*

I m m r*

• I du........

h I Qualification Report 950.366

,Section 6 Page 59 of 74 Rp I, acliation measurements 6045 Cochran Road Cleveland OH 44139 Phone: 440 248-9300 FAX: 440-349-2307 TITLE:

GM Detector Calibration for Area Monitoring Systems www.inovision.com DOCUMENT:

CAL-GM6 REV.

A ATTACHMENT A

897A-XIX DETECTOR DATA SHEET Customer Rochester Gas & Electric F'.O.

4500008671 Project N/A S.0. 0.

157033 W.O.

N/A Detector Model #

897A-210 Serial 131 Tag #

N/A Readout Model #

956A-201.

Serial-#

117 Cal Date 10-Jan-01 6.3 Detector Discriminator N/A volts

( 897 ONLY

)

6.5 Anti-Jam Duty Cycle Verification Pass (Fass/Fail)

Intensity P'osition Pe No..

Count Time Accumulated Gross Net (mR/h)

Of Attenuaters (sec)

Counts TRI SOURCE CALIBRATION INFORMATION (20 ACKGROUND 1.04 3.21 9.56 30.3 91.6 303 971 3107 200 cm 200 cm 250 cm 200 cm 250 cm 200 cm 250 cm 200 cm Z300 cm 6.1.0

& 6 Attn's

& 6 Attn's

& 5 Attn's

& 4 Attn's

& 3 Attn's

& 2 Attn's

& 1 Attn's

& 0 Attn's

& 2 Attn's Check Source 3.00E+02 2.,40E+02 2.40E+02 2.40E+02

1.

..2QE+02'

1. 20E+02 1,,20E+02 1..20E+02 6.OOE+01

Response

8.30E+01 1.. 15E+03 3.29E+03 9.85E+03

1. 50E+04 4.38E+04 J..31E+05 3.66E+05 Anti Jam 89.30 CoUn ts Count Rate

( cpm)

Ci Cs-137) 1.66E+01 2.87E+02 8.23E+02 2.46E+03 7.50E+03 2.19E+04 6.55E+04

1. 83E+05

2. 59E+06 mR/h Conversion Constant 3.98E-03 Dead Time Correction 1.43E-06 onclUcted By O..A., Review By 2x.

Cal Date 01-Mar-01 Date I

225:1MI--6

( cpm )

N /

AF 271 806 2446 7483 21883 65483 1.82983 N /

A

U' WWi A-S-

Qualification Report 950.366

.qrt*'nn A P~n a rA nf 7A Radiation Measurements 6045 Cochran Road*

Cleveland OH 4413904 Phone: 440 248-9300 FAX-440-349-2307 www.inovision.com DETECTOR CURVE FIT PROGRAM -

GM AREA MONITORS 94085701 Rev B Model number is 897A-210 Serial number is 131 DATA FROM CALIBRATION RANGE Field CPM Calc field mR/hr

% Deviation 1.04 271 1.07817 3.66997 3.21 806 3.20911

-0.0276075 9.56 2446 9.76178 2.1107 30.3 7483 30.0818

-0.720002 91.6 21883 89.8434

-1.91764 303 65483 287.377

-5.15603 971 182983 986.203 1.56567 CC1 = 0.00397693 TAU = 1.43242e-006 Root sun) of the squares of the deviation is 7.15236 Backcground CF'M:

17 Date Calibrated:

3/1/01 Calibrated by: Bruce Mahood Customer: Rochester Gas & Electric Sales order number: 157033 Customer tag number:

N/A I

4 w

I

Quakfication Report 950.366 Section 6-Page 61 of 74 ANA-h 6.3 Detector Discriminator N/A 6.5 Anti-Jam Duty Cycle Verification Pass volts ( 897 ONLY )

(Pass/Fail)

Intensity Position & No.

Count Time Accumulated Gross Net (mR/hI)

Of Attenuaters (sec)

Counts Counts Count Rate

( cpm

( cpm )

TRI SOURCE CALIBRATION INFORMATION (20 P

AC IKGROUIDID 1

1.04 3.21 1

9.56 30,.3 I

91.6 I

303) 971 1

3107 200 cm 200 cm 250 cm 200 cm 250 cm 200 cm 250 cm 200 cm 300 cm 6.10

& 6 Attn's

& 6 Attn's

& 5 Attr's

& 4 Attn 's

& 3 Attn's

& 2 Attn's

& 1 Attn's

& 0 Attn's

& 2 Attn's Check Source

3. OOE+02 2.40E+02 2.40E+02 2.40E+02 1.20E+02

1. 20E+02

1. 20E+02

1. 20E+02

6. OOE+01

Response

9.30E+01 1.21E+03 3.60E+03 1.07E+04 1.65E+04 4.79E+04

1. 44E+05 4.01E+05 Anti Jam 81.40 Ci Cs-137) 1..86E+01 3.02E+02

9. OOE+02 2.68E+03 8.25E+03 2.40E+04 7.20E+04 2.01E+05 2.60E+06 mR/h SConversion Constant 3 67E-Dead Time Correction 1.26E-06 Conducted F.

Q.A.. Review By Q Cal Date 0"L-Mar-01 Dat c.

1225. GMI-6 adiation Measurements 6045 Cochran Road Cleveland OH 44139 Phone: 440 248-9300 FAX: 440-349-2307 TITLE:

GM Detector Calibration for Area Monitoring Systems www.inovision.com DOCUMENT:

CAL-GM6 REV.

A ATTACHMENT A 897A-XIX DETECTORN DATA SHEET Customer Rochester Gas & Electric F.O.

0 4500008671 Project N/A S..O.

157033 W..O.

N/A Detector Model #

897A-210 Serial 132 Tag #

N/A Readout Model #

956A-201 Serial 117 Cal Date 10-Jan-01 Ni /

A 284 881 2656 8231 23931 71981 200481 IlI / A

Radiation Measurements Qualification Report 950.366 "Section 6 Page 62 of 74 6045 Cochran Road Cleveland OH 44139 Phone: 440 248-9300 FAX: 440-349-2307 www.inovision.com !

I DETECTOR CURVE FIT PROGRAM -

GM AREA MONITORS 94085701 Rev B Model number is 897A-210 Serial nuniber is 132 DATA FROM CALIBRATION RANGE Field CPM Calc field mR/hr 1.04 284 1.04201 3.21 881 3.23485 9.56 2656 9.77411 30.3 8231 30.5046 91.6 23931 90.4933 303 71981 290.257 971 200481 982.883 CCI = 0.00366773 TAU = 1.2564e-006 Root sum of the squares of the deviation Background CFIM:

19 Date Calibrated:

3/1/01 Calibrated by: Bruce Mahood CusLtomer: Rochester Gas & Electric Sales order number: 157033 Customer tag number: N/A

% Deviation 0.19305 0.774222 2.23966 0.675126

-1.20814

-4.20564 1.22378 is 5.17235 I

I4 I

i i

I

V Qualification Report 950.366 Section 6 Page 63 of 74 L

adiation Measurements TITLE:

0M Do-ector Calibration for Area Monitorinq Systems DOCUMENT:

Custome r Project

)Dc-tecior Readout CAL-GM6 Rochester N/A Model #

Model #

REV.

A 897A-XIX DETECTOR DATA SHEET Gas & Electric P.O.

4 S.O.

157033 W.O.

Of 897A-210 Serial #

100762 956A-201 Serial

1. T 117 6045 Cochran Road Cleveland OH 44139 Phone: 440 248-9300 FAX-440-349-2307 www.inovision.com ATTACHMENT A 4500008671 N/A Taq 4$

N/A Cal. Date 10-Jan-01 6.3 Detector Discriminator N/A volts

( 897 ONLY

)

6.5 Anti-Jam Duty Cycle Verification Fass (F'ass/Fail)

Intensity Position & No.

Count Time Accumulated Gross Net (mR/h)

Of Attenuaters (sec)

Counts Counts Count Rate I

IWACKGROUND 1..04 9.56 30,.3 91.6 303 "971 3107 TRI SOURCE CALIBRATION INFORIMIATION (20

& 6 Attn's

& 6 Attn's

& 5 Attn's

& 4 Attn' s

& 3 Attn's

& 2 Attn's

& 1. Attn 's

& 0 Attn's

& 2 Attn 's Check. Source

3. OOE+02 2.40E+02 2.40E+02 2.. 40E+02

L..20E+02, 1.20E+02 1..20E+02 1.. 20E-+'02 6..OOE+0O

Response

B. -OE+01

1. 15E+03

3. 40E+03 1.01E+04

[..9 56E+04 4.54E+04 1.. 36E+05 3.76E+05 An t:i. Jmn) 43.40

( cpm)

(

Ci Cs-137) 1.62E+0:L

2. 87E+02 8.50E+02 2.53E+03 7.60E+03 2.27E+04 6.180E+04 1.8E3405 2.60E+06 mR/h cprn

)

N /

A 271 834 2509 7784 22684 67984 187984 14 /

A Conversion Constant conducted Dy Cc0.

Da-:te Dead Time Correction I.

O.A.

Review By _

Da t eM 225::G(1,11-6 02--Mar-01 I

200 cm 200 cm 250 cm 200 cm 250 cm 200 cm 250 cm 200 cm 300 cm 6.10

Qualification Section 6 Report 950.366 Page 64 of 74 Radiation Measurements r

DETECTOR CURVE FIT PROGRAM -

GM AREA MONITORS 94085701 Rev B Model number is 897A-210 Serial number is 100762 DATA FROM CALIBRATION RANGE Field CPM Calc field mR/hr 1.04 271 1.04907 3.21 834 3.23103 9.56 2509 9.74278 30.3 7784 30.4491 91.6 22684 90.6205 303 67984 290.356 971 187984 982.757 CCI = 0.00386967 TAU = 1.38204e-006 Root sum of the squares of the deviation Background CFM:

16 Date Calibrated:

3/2/01 Calibrated by: Bruce Mahood Customer: Rochester Gas & Electric Sales order number: 157033 Customer tag number: N/A

"" Deviation 0.872394 0.655042 1.91191

0. 491939

-1.06931

-4.17282 1.2108 is 5.01093 6045 Cochran Roah Cleveland OH 4413904 Phone: 440 248-9300 FAX: 440-349-2307 www.inovislon.com I

i I

IU I

i I

I I

LualiTication Heport 950.366 Section 6 RPage 65 of 74 Plateau Data 897A-210 Serial Number 131 All counts taken with the detector's operational check source activated.

Nominal Check Sou rceponse is 88 mRIh Date.OZ,

/

Ascendina Plateau Desending Plateau time H.V.

counts CPM time H.V.

counts CPM 9:49 375 4.13E+04 2.07E+04 10:26 650 4.50E+04 2.25E+04 9:52 400 4.37E+04 2.19E+04 10:29 625 4.50E+04 2.25E+04 9:55 425 4.42E+04 2.21E+04 10:32 600 4.50E+04 2.25E+04 9:58 450 4.44E+04 2.22E+04 10:36 575 4.46E+04 2.23E+04 10:01 475 4.44E+04 2.22E+04 10:45 550 4.51E+04 2.26E+04 10:05 500 -4.43E+04 2.22E+04 10:48 525 4.47E+04 2.24E+04 10:07 525.4.46E+04 2.23E+04 10:51 500 4.47E+04 2.24E+04 10:10 550 4.46E+04 2.23E+04 10:54 475 4.46E+04 2.23E+04 10:13

-575 4.44E+04 2.22E+04 10:57 450 4.43E+04 2.22E+04 10:16

-600 4.48E+04 2.24E+04 11:01 425 '4.43E+04 2.22E+04 10:18 625 4.50E+04 2.25E+04 11:04 400 4.37E+04 2.19E+04 10:20 650 4.52E+04 2.26E+04 11:07 375 4.15E+04 2.08E+04

(D Co)

O 0 23000 to W.

CL" O)C 0

22000 0c m

N Plateau : 897A-210 sIn 131 100 200 300 400 500 High Voltage 600 Ascending Plateau

-Desending Plateau 700

0.

CL 0 21500 21000 20500 0

m h

Qualification Report 950.366 Section 6 Page 67 of 74 Plateau Data I

897A-210 Serial Number 132 Ascending Plateau Desending Plateau time H.V.

counts CPM time H.V.

counts CPM 13:14 375 4.28E+04 2.14E+04 13:51 650 4.66E+04 2.33E+04 13:17 400 4.51E+04 2.26E+04 13:54 625 4.65E+04 2.33E+04 13:20 425 4.55E+04 2.28E+04 13:56 600 4.61E-04 2.31 E+04 13:23 450 4.56E+04 2.28E+04 13:59 575 4.61E+04 2.31E+04 13:26 475 4.56E+04 2.28E+04 14:01 550 4.62E+04 2.31E+04

.. 13:30 500 4.56E+04.2.28E+04

.14:04

-525 -4.58E+04 2.29E+04 13:33 525 4.58E+04 2.29E+04 14:07 500 4.57E+04 2.29E+04 13:35 550 4.60E+04 2.30E+04 14:10 475 4.55E+04 2.28E+04 13:40 575 4.60E+04 2.30E+04 14:12 450 4.56E+04 2.28E+04 13:43 600 4.64E+04 2.32E+04 14:14

-425 4.52E+04 2.26E+04 13:46 625 4.67E+04 2.34E+04 14:17 400 4.50E+04 2.25E+04 13:49 650 4.65E+04 2.33E+04 14:19 375 4.26E+04 2.13E+04 All counts taken with the detector's operational-check source activated.

Nominal Check Source r se is 84 mR/h P
--

r0d 1 Date Pe...........

v

am ~

il

-m

-m

-i 1-

- m ug.

Plateau: 897A-210 sIn 132 Ascending Plateau

-Desending Plateau 0

100 200 300 400 500 600 700 High Voltage CD'~

C01%

0 a m 0) oc~o

.o

0)

(C)

S(d) 0 24000 23500 23000 ID a 22500 CL 0 C.)

22000 21500 21000

Qualification Section 6 Plateau Data 897A-210 Serial Number 100762 Report 950.366

. Page 69 of 74 All counts taken with the detector's operational check source activated.

Nominal Check Source sonse is 45 mRIh Performedby

/)' " tv

/---

Date

-- AsCenrdirrgPlateau............

Desending Plateau time H.V.

counts CPM time H.V.

counts CPM 12:56 375 0.OOE+O0 0.00E+00 13:48 650 2.34E+04 1.17E+04 12:58 400 2.14E+04.1.07E+04 13:50 625 2.34E+04 1.17E+04 13:02 425 2.28E+04 1.14E+04 13:56 600 2.35E+04 1.18E+04 13:05 450 2.32E+04 1.16E+04 13:59 575 2.33E+04 1.17E+04 13:12 475 2.31E+04 1.16E+04 14:01 550 2.33E+04 1.17E+04 13:16 500 2.32E+04 1.16E+04 14:04 525 2.33E+04 1.17E+04 13:19 525 2.35E+04 1.18E+04 14:06 500 2.31E+04 1.16E+04 13:24 550 2.35E+04 1.18E+04 14:09 475 2.32E+04 1.16E+04 13:37 575 2.35E+04 1.18E+04 14:12 450 2.31E+04 1.16E+04 13:40 600 2.35E+04 1.18E+04 14:15 425 2.27E+04 1.14E+04 13:43 625 2.37E+04 1.19E+04 14:17 400 2.16E+04 1.08E+04 13:46 650 2.37E+04 1.19E+041' 14:20 375 0.OOE+00 0.OOE+00

uE

m -

m -

U Plateau : 897A-21 0- sin 100762 (oD CO, LO

0) 0r-n

~CU CL o

3 CD a U)

S -

-1 1

Ascending Plateau Desending Plateau 0

100 200 300 400 500 600 High Voltage 12000 11800 11600 C:

0 C.

11400 11200 11000 10800 10600 700

Qualification Section 6 Report 950.366 Page 71 of 74 Repeated Count Rate Data 897A-210 Serial Number 131 time counts CPM 9:05 4.45E+04 2.23E+04 9:08 4.43E+04 2.22E+04 9:10 4.42E+04 2.21E+04 9:12 4.43E+04 2.22E+04 9:15 4.45E+04 2.23E+04 9:26 4.44E+04 2.22E+04 9:30 4.44E+04 2.22E+04 9:33 4.46E+04 2.23E+04 9:42 4.44E+04 2.22E+04 9:45 4.45E+04 2.23E+04 All data taken at 575 VDC operating voltage All data taken using detector's operational check source Performed by v--,.L Date l,/

Qualification Section 6 Report 950.366 Page 72 of 74 Repeated Count Rate Data, 897A-210 Serial Number 132 time counts CPM 11:14 4.66E+04 2.33E+04 11:17 4.67E+04 2.34E+04 11:20 4.63E+04 2.32E+04 11:23 4.67E+04 2.34E+04 11:27 4.66E+04 2.33E+04 11:32 4.66E+04 2.33E+04 11:35 4.63E+04 2.32E+04 11:38 4.63E+04 2.32E+04 11:40 4.67E+04 2.34E+04 11:43 4.66E+04 2.33E+04 All data taken at 575 VDC operating voltage All data taken using detector's operational check source Performed bv Date 2 -.9---0/

I"'l I I

I I

I I

I I

I I

I I

I l gF *lm J* v

Qualification Section 6 Report 950.366 Page 73 of 74 Repeated Count Rate Data 897A-210 Serial Number 100762 time counts CPM 10:12 2.31E+04 1.16E+04 10:14 2.33E+04 1.17E+04 10:18 2.31E+04 1.16E+04 10:38 2.33E+04 1.17E+04 11:09 2.31E+Q4 1.16E+04 11:12 2.31E+04 1.16E+04 11:14 2.32E+04 1.16E+04 11:16 2.31E+04 1.16E+04 11:24 2.31E+04 1.I1E+04 11:27 2.31E+04 1.16E+04 All data taken at 575 VDC operating voltage All data taken using detector's operational check source Performed by..

Date________

Performed by i

Date. 31'g-10,(

Qualification Report 950.366 Section 6 Page 74 of 74 This page intentionally blank I

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I

R.E. Ginna Nuclear Power Plant Response to RAI Dated August 28, 2002 Enclosure DA-EE-2001-009 Electrical Factors Analysis for PCR 99-004 (FMEA for CREATS Actuation Instrumentation)

D0960977 Design Analysis Ginna Station PCR 99-004 Electrical Factors Analysis Rochester Gas & Electric Corporation 89 East Avenue Rochester, New York 14649 DA-EE-2001- 009 Revision 2 Effective Date Prepared By:

Design Engineer Reviewed By:

4' 0.

@4)(A.

Reviewer 1/ a.-~

Date Date

Revision Status Sheet Affected Sections All Throughout Throughout Description of Revision Original.

Incorporate design changes, such as isolator addition, fuse addition, wire size changes. Additional technical detail added for single failure analysis, separation, and isolation.

Incorporate design changes for PCR Revision 1.

Revision 2 DA-EE-2001-009 Revision Number 0

1 2

Page 2 of 17

1.0 Purpose 1.1 The purpose of this analysis is to demonstrate that electrical factors associated with the construction of PCR 99-004 meet the requirements for electrical design for Ginna Station and Generic Design Criteria Ref. 3.2. The following sections list the factors that will be analyzed in this document. PCR 99-004 Revision 1 changes are incorporated.

1.1.1 All circuits, existing and new, that are impacted by this design will be analyzed to show appropriate cable properties, including sizing, shielding, grounding, and insulation. (See Section 7.1) 1.1.2 Cable separation and isolation between Class 1E and non-Class 1E equipment will be shown to be appropriate for the related equipment. (See Section 7.2) 1.1.3 Conduit sizes will be shown to be adequate to meet the cable fill requirement specifications. (See Section 7.3) 1.1.4 The selection of relays to be used will be shown to have the proper electrical parameters, including coil voltage rating, contact voltage and current ratings, and adequate amount of contacts. (See Section 7.4) 1.1.5 Switches selected for use will be shown to have appropriate contact configuration and ratings for the applications. (See Section 7.5) 1.1.6 The instrumentation will be shown to have appropriate ratings for input and output parameters, including operating voltage, output contact ratings, and signal outputs.

(See Section 7.6) 1.1.7 Overcurrent protection will be analyzed to show proper fusing and coordination with other protective devices. (See Section 7.7) 1.1.8 Panel loading will be evaluated to demonstrate that no load ratings will be exceeded, and any impact on the loading of upstream supplies is addressed. (See Section 7.8) 1.1.9 The design will be reviewed to ensure that there are no adverse effects from electrical noise on the performance of the equipment, including surge suppression requirements for relay coils. (See Section 7.9) 1.1.10 The control logic for the design will be reviewed to ensure that it fails in the safe position for postulated power failures. (See Section 7.10) 1.1.11 The electrical design will be reviewed to demonstrate that no single failure can cause the loss of both trains of isolation logic or prevent the system from isolating. (See Section 7.11)

Revision 2 DA-EE-2001-009 Page 3 of 17

2.0

'Conclusions I

R4522 C5529 C5545 C5552 AU0235A AU0239 AU0239B 4.3 R4523 C5530 C5551 AU0235 AU0235B AU0239A C3505 C2621 Codes And Standards Revision 2 DA-EE-2001-009 2.1 The design and all electrical components specified in the design of the modification for PCR 99-004 Revision 0 with associated MDCNs, and Revision 1, are adequate and appropriate, consistent with design requirements for the electrical factors described in Section 1.0 of this analysis.

3.0 Design Inputs 3.1 PCR 99-004 Revision 1 and associated attachments, including circuit schedules issued for construction and Bill of Material.

3.2 Generic Design Criteria, Electricalll&C Plant Changes, EWR 10275, Rev. 0.

4.0 Referenced Documents 4.1 Drawings RG&E Drawings:

Drawing

1. Sheet SK21946-0546SHI-1 SK21946-0546SH2-1 SK33013-2784-1 SK33013-1618SH1-2 SK33013-2004-1 SK33013-1860-4 4.2 Circuit Schedules I

Page 4 of 17

4.3.1 Ginna Station Updated Final Safety Analysis Report (UFSAR).

4.3.2 IEEE 141-1986, "Recommended Practice for Electric Power Distribution for Industrial Plants".

4.3.3 IEEE 384-1981, "Standard Criteria for Independence of Class IE Equipment and Circuits".

4.3.4 IEEE 446-1980, "Recommended Practice for Emergency and Standby Power Systems for Industrial and Commercial Applications".

4.3.5 IEEE 946-1985, "IEEE Recommended Practice for the Design of Safety-Related DC Auxiliary Power Systems for Nuclear Power Generating Stations".

4.4 Equipment Information 4.4.1 Vendor Manual, VTD-A4057-4001, Analytical Technology, Inc. vendor literature, publication SS-B 14RC, (1/97), and O&M manuals Series B-14 Monitor System Rev.

R, and UniSens Rev. G.

4.4.2 Vendor Manual, VTD-12677-4101 and VTD-VO 115-4101, Inovision (Victoreen),

Model 956A-201 series Ratemeter and Model 897A series GM Detector.

4.4.3 Cutler-Hammer Quick Selector Catalog 25-000, Type BF and BFD Relays, July 1995.

4.4.4 Square D, Type KA-1, Class 9001 Auxiliary contacts for SE with Type K push-button switches.

4.4.5 Brand-Rex Industrial Wire and Cable, publication PC-8 101.

4.4.6 Buss Fuses, Full-Line Condensed Catalog FLC, January, 1989.

4.4.7 OT2 Switches, Westinghouse Electric Catalog,25-000, March 1977.

4.4.8 WESCO Lamp, information contained in DA-EE-99-047 Attachment 5, DC Load Survey.

4.4.9 Potter & Brumfield, attached data sheet (Attachment 5) from unidentified catalog.

4.4.10 NUS Instruments, Specifications for Analog Isolator Modules, Spec.: Data sheet attached (Attachment 6).

4.5 Correspondence 4.5.1 Letter from James P. Brozek of Bussmann to Joseph E. Pacher, "DC Voltage/AIC Rating of Fuses", dated 12/10/90.

Revision 2 DA-EE-2001-009 Page 5 of 17

4.5.2 Bussmann Correspondence, Steve Shaffer to John Kowal, "AC/DC Fuse Spec", dated 1/3/91.

4.6 Plant Procedures 4.6.1 GC-76.9, Installation and Inspection of Electrical Equipment, Raceway and Electrical Supports.

4.6.2 GC-76.10, Installation, Testing, and Inspection of Wire and Cable.

4.7 Miscellaneous References 4.7.1 National Electric Code, NFPA 70, 1999.

4.7.2 PCR 98-097, Control Room Radiation Monitor Noise Suppression, Rev. 0.

4.7.3 Design Analysis, DA-EE-98-157, Cable Sizing Criteria, Rev. 0.

4.7.4 Ginna Procedure PT-17A, Control Room Radiation R-36, R-37, R-38 and Toxic Gas Monitor Operability Test.

4.7.5 Ginna Alarm Response Procedure AR-E-1 1, Control Room HVAC Isolation.

4.7.6 Design Analysis, DA-EE-99-063, PCR 99-001 Electrical Factors Analysis.

4.7.7 Design Analysis, DA-EE-2001-047, Instrument Bus Electrical System Evaluation.

4.7.8 Topical Design Basis - Electrical Independence, Rev. 0, 6/19/97.

4.7.9 Design Analysis, DA-EE-99-047, 125 VDC System Loads and Voltages, Rev. 1.

5.0 Assumptions None 6.0 Computer Codes 6.1 None 7.0 Analysis 7.1 Cable Properties Cable selection and sizing will be per Ref. 4.7.3, "Cable Sizing Criteria Design Analysis", which specifies the factors and derating amounts to consider in sizing and selecting conductors and routing through trays and conduits. Those factors will be Revision 2 DA-EE-2001-009 Page 6 of 17

adhered to throughout section 7.1.

7.1.1 Power and Control Cables The total power consumption requirements of all components in the new 120 vac circuits are tabulated in DA-EE-2001-047 on the appropriate Twinco Panel tables. breaks out the loading to the portions of the circuits fed by each portion of the circuits shown on drawings SK21946-0546SH1-1 and SK21946-0546SH2-1.

The maximum possible current to any individual portion of the circuit is 1.93 amps.

The cable specified in the circuit schedules for power and control is #12 copper conductor. The new power cable is routed in conduit between the RMS rack and the Aux Benchboard. In accordance with reference 4.7.3 the tables in the National Electric Code shall be utilized for cables this size. In accordance with NEC Table 310 16 the rated ampacity for #12 AWG cable in a 104 degree F ambient is 27.3 amps (30 amps*0.91 temp derating factor). Therefore, the proposed new power cables have adequate ampacity for the expected current requirements.

To accommodate pin connectors on the back of the ratemeter, the control circuit to the output contacts of the ratemeter were changed to #16 awg SIS wire. Per NEC 310-16, the rated ampacity in 104 degree F ambient is 16.4 amps (18 amps *0.91 derating).

This has adequate ampacity (above the 2 amp maximum current) for this circuit.

The existing power cables from the Twinco distribution panels to the RMS racks (Circuit Schedules C2621 and C3505) are #12 and #14 copper respectively. They are routed in tray and conduit, so must be derated by a factor of 0.35 per reference 4.7.3.

C2621 (#12 awg @ 30 amps*0.91 temp derating factor

• 0.35 tray derating) results in an ampacity of 9.55 amps.

C3505 (#14 awg @ 25 amps*0.91 temp derating factor

• 0.35 tray derating) results in an ampacity of 7.96 amps.

Per reference 4.7.7, the existing maximum load on either of these circuits is 5.7 amps, which already includes the above loads, except the isolators were upgraded from SCAIOO to SCA300, resulting in 0.09 additional amps. The additional load of 0.09 amps results in a new total load of 5.8 amps, which is within the ampacity of the existing cables.

Grounding will be performed per procedure GC-76.9. The grounding has been reviewed and is consistent with the vendor recommendations.

All specified cables are rated 600 volts. All power and control circuits are 120 Vac or 125 VDC. Therefore, all cables have an adequate voltage rating for the specified applications.

7.1.2 Detector/Ratemeter Instrumentation and Power Cables Revision 2 DA-EE-2001-009 Page 7 of 17

The cable used to provide power and signal between the ratemeter and the detector is a special cable supplied by the vendor, specifically for this equipment. It has been sized and tested by the vendor for use in this application. Installation ahd connections will be made per vendor instructions and drawings, to be included in the PCR package outputs.

7.1.3 PPCS Cables All PPCS cables will be wired using #16 twisted shielded pair cable (#16TSP),

including connections between isolators and ratemeters. This is adequate for the 4 - 20 mA currents that are carried by these cables from the instrument to the MUX connections. Internal RMS rack wiring requires the use of #22 awg for the pin connectors to P6, the ratemeter analog output connection. The #22 wire will go from the connector approximately three feet to the terminal deck where it transitions to the

1. 16. The #22 wire is appropriate for use for a 4 - 20 ma signal.

Cables to PPCS will have the shields appropriately connected for analog points to ensure no impact on the 4-20 ma signal, consistent with plant computer wiring practices.

7.2 Cable Separation 7.2.1 A review of the design of the electrical systems associated with the proposed design has been performed to demonstrate that compliance with the requirements of IEEE Std 384, "IEEE Standard Criteria for Independence of Class 1E Equipment and Circuits".

A and B train components have been separated into separate compartments in the Auxiliary Benchboard and the RMS racks, so there is physical separation between A and B train redundant components.

7.2.2 Redundant trains of wiring are routed in separate train-specific conduits for the interconnection of all equipment where the cables have to route outside of cabinets.

When cables enter enclosures, such as the Auxiliary Bencbboard or Radiation Monitoring System (RMS) racks, wiring is installed to maintain physical separation between redundant trains of wiring. Where cables are routed through the cabinets to the compartments containing components of the opposite train, the minimum 6" separation is maintained. The "defense-in-depth" design concept that results in the cross-connection of the redundant trains has resulted in a number of cables that are associated with both trains. Separation is maintained up to the points of interconnection between the two logic circuits (relays and terminal blocks). In the RMS racks, the cables have been designated as being associated with the train in which they are logically connected to the isolation initiation relay (if in the R81A circuit, then A train cable). These cables are designated associated to that train and separation from the other train is maintained except at the point of termination at terminal blocks.

7.2.3 In the Auxiliary Benchboard, the cross train logic is encountered where contacts are Revision 2 DA-EE-2001-009 Page 8 of 17

connected in series from R81A to R81B for signals to the individual isolation devices (dampers, fan, MCB annunciator). The connecting cables go directly from an A train device to a B train device, and since they are not train specific at those points, separation cannot be maintained, so the cables are routed together, separate from all other train specific cables. Since the points of connection between the two trains is the relay contacts, isolation can be credited since relay contacts are considered qualified isolators per IEEE 384 section 6.2.2.2).

7.2.4 There is no physical way to separate the wires to these non-train specific points at the contact terminals from the train specific wires to the relay coils. This has been determined to be acceptable per a review of the logic and the Auxiliary Benchboard layout as follows: The wiring in the Auxiliary Benchboard cabinet is for the logic to the isolation relays. A review of that logic wiring demonstrates that any fault in the cabinet that causes failure of a wire will result in an opening of the associated circuit.

Any open circuit will result in the isolation relay to drop out, automatically causing the initiation of the safety function to perform and put the CREATS in isolation. This is true for either a single train failure or a failure that propagates between both trains due to less than optimal separation. There is not a credible failure mode that would result in a condition in which faulted or failed wires in the Auxiliary Benchboard would prevent the safety system from performing its execute function if an actuation signal was present. The only way to prevent the system from performing this function would be for 120 VAC being applied to the logic circuits of both trains within this cabinet, energizing the relays even after the output contacts of the initiating devices (ratemeter or manual pushbutton) have opened. There are only a few wires that are still energized after an initiation signal in a manner that could cause this type of unlikely "hot short" in either logic train, where a wire could be disconnected and contact the relay with 120 VAC. Since the two R81 relays are in separate compartments in the Auxiliary Benchboard, there are no points where such a condition could also cause a second wire of the other train to fail and energize the opposite train's R8 I relay. In addition, failure of any wires in the Auxiliary Benchboard due to inadequate separation between the trains can not propagate back to the ratemeters and cause them to fail in a manner that would prevent the system from performing its safety function.

7.2.5 Wiring for the radiation monitoring cabling, for power to the ratemeters, and for signal wiring between detector and ratemeter, maintains the minimum separation criteria of IEEE 384 between wiring of redundant trains. Outside of enclosures, the cable is inside of conduits that provide the physical separation between trains. There are only A Train or B Train cables in any conduit, and any non-lE circuits are routed with either train in the conduits carrying safety related circuits are train specific associated circuits that are physically separated from or electrically isolated from the opposite train. In the RMS racks, the minimum 6 inches of physical separation is maintained between redundant trains for power and signal wiring.

7.2.6 No new power or control cables are run in cable tray. A Train components are powered from an A Train power supply (IBPDPCBE from INVTCVTA) and B Train components are powered from a B Train power supply (IBPDPCBC from Revision 2 DA-EE-2001-009 Page 9 of 17

hINVTCVTB). Existing cables from IBPDPCBC and IBPDPCBE to RMS racks were not moved, existing separation criteria for these cables remains.

7.2.7 New PPCS circuits will go through an optical isolator to provide isolation from SR to SS systems, but will be installed safety related from the RMS rack to the CREP panels in the Turbine Building. To that point, they will be meet the separation requirements of the Safety Related portion of the design as they will be treated as associated circuits for the train they are associated with. When these circuits reach the CREP panels, they will be terminated on fuses to provide electrical isolation so that the two trains can be run in the same conduit as non-Safety Related cables. The optical isolators are qualified safety related devices, and they are rated to protect the radiation monitors from damage due to fault, short circuit, or open circuit.

The non-safety portion of the circuit downstream of the isolation devices to the MUX equipment share a common conduit. This is acceptable because they are beyond the fuses providing electrical isolation, and there is no requirement for redundancy to the PPCS equipment.

7.3 Conduit Fill Conduit fill will meet the specifications in the National Electric Code Ref. 4.7.1, Chapter 9 Tables 1 and 4. Power and instrument cable diameters and areas are from vendor documentation Ref. 4.4.5. 10/C special cable provided by Inovision has 0.675" o.d. per reference 4.4.1.

Conduit Sizing / Fill Determinations Conduit fill limits are listed in NEC Chapter 9 tables 1 and 4. In attachment 4 the calculated cable fill for each conduit being installed is calculated. Cable diameters were taken from Cabletrak database which lists cables used in the plant and specifications taken from purchase orders and vendor documentation. shows that all conduits are within the fill limits.

7.4 Relays Two additional AC relays (R81A and R81B) will be installed in the control circuits for this modification. These relays require 120 VAC coils. The contacts from these relays will be installed in 125 VDC circuits and 120 VAC circuits, so their contacts need to be appropriately rated.

A review of the control logic demonstrates that the maximum DC load on the relay contacts will be on contact number 1, which supplies control power to MCC K position IF circuit for the control room air handling unit supply fan. This circuit has a maximum DC load of 0.38 amps, consisting of a motor starter, solenoid, and a lamp (Load values taken from Reference 4.7.9). The AC relay contacts will be subjected to a maximum load of a single BF relay coil, with a Revision 2 DA-EE-2001-0 0 9 Page 10 of 17

power requirement of 0.6 amps.

Type BF relays have been selected for this application. The coils are rated for 120 VAC +10%/-15% and the contacts on these relays are rated for 1.1 amps at 125 VDC, and 6 amps at 120 VAC (reference 4.4.3, attachment 2). These rating are acceptable for the specified application.

Existing relay R80B will still have one contact in the 120 VAC circuit. A review of the control logic demonstrates that the maximum load on the relay contacts will now be 1 BF relay which has a power requirement of 72 VA (0.6 Amps) at 120 VAC. R80B is a Potter & Brumfield Type KRP1 IDY relay, with a contact rating of 5 Amps at 120 VAC (attachment 5). This rating is acceptable for the specified application.

7.5 Handswitch Ratings The selected handswitches,, Westinghouse OT2 switches, have contacts rated for 6 amps at 120 VAC, and are rated up to 600 volts. As the table in 7.1 demonstrates, the maximum current on any circuit could be 2.07 amps.

Therefore, these switch contacts are adequate for this application. See Reference 4.4.7.

7.6 Instrumentation Ratings The A17 Power Supply modules being used to power the existing Toxic Gas System instrumentation has an input voltage range from 85 to 270 volts, AC or DC, per Ref. 4.4.1. This system will now be supplied from Instrument Bus power via the RMS racks, at 120 VAC, so the change in power source does not impact the Toxic Gas equipment.

The Radiation Monitoring equipment requires 120 VAC power, +/- 10% (108 132 VAC) per Attachment 1. That is within the regulation range of the Instrument Bus Twinco constant voltage power supplies, which by Tech Spec are required to have an output voltage of 115.6 to 124.4 VAC. Ref. 4.7.7 contains voltage drop calculations for the existing circuits. The voltage drop from the Twinco to the RMS racks is much less than I volt, and the small load being added by this modification will not significantly impact that calculation, so power supply voltage will remain appropriate for the connection of the new ratemeters.

Alarm relay contacts in Model 956A-201 ratemeters are rated 5 A at 120 volts AC, per attachment 1. These contacts will be subjected to a maximum possible load of 1 BF relay, which is 0.6 amps (see 7.4 above). Therefore, these contacts are adequately rated for their expected load.

The ratemeter analog outputs are rated 4-20 ma. Each of the two outputs on each ratemeter will drive a single input on the isolators RY-A and RY-B. Each isolator input channel has an input impedence of 249 ohms. The ratemeters are rated to Revision 2 DA-EE-2001-009 Page 11 of 17

drive 500 ohms maximum load. Therefore, the ratemeters are adequately rated for the analog output devices they are connected to. The isolator outputs are rated to drive 1050 ohms on the 4-20 mA signals. The PPCS output point has a 250 ohm resistor at the MUXATP. The isolator is therefore adequately rated to drive the PPCS point. This is consistent with the existing connections to the PPCS in the MUX Auxiliary Terminal Panel.

7.7 Coordination / Isolation and Fuse Sizing Safety related fuses will provide isolation between the safety related equipment (R-45, R-46, R-10A, R-1 1, R-12, R-29, R-30, RK-78) from non-safety/safety significant equipment (toxic gas, isolators RY-A and RY-B, plus radiation monitors R-10B, R-13, R-14 and associated isolators and relays). The fuse sizing was shown to be appropriately designed in reference 4.7.6, and the new power source does not change any of the analyzed characteristics. The 3 amp fuses used for each circuit and circuit section are adequately smaller than the next upstream protective device, the breakers in IBPDPCBC (15 amp) and IBPDPCBE (20 amp) supplying the new system, so there is coordination between these devices. The 3 amp fuses are also adequately sized to carry the loads as shown on Atttachment 8 (maximum load on any fused section is 1.93 amps, which is less than 80% of fuse size). shows the coordination of protective devices between the fuses, breaker, and conductors.

Isolation of the Safety Significant PPCS from the Safety Related Radiation Monitors, which are connected at the analog output port, will be provided by optical isolation devices rated to protect the radiation monitors from damage due to fault, short circuit, or open circuit. The power supplying the isolators is supplied by the instrument bus circuits described above, and are electrically isolated by fuses. The new fuses used for isolation of power to the PPCS isolation devices (RY-A and RY-B) are also rated 3 amps and will coordinate with the breakers and conductors as described above.

7.8 Panel Loading Panel IBPDPCBC is supplied by 2.0 Kva Twinco voltage regulator MQ-400C, and panel IBPDPCBE is supplied by 2.0 Kva Twinco voltage regulator MQ-400E.

Design analysis DA-EE-2001-047, reference 4.7.7, has detailed equipment rating and loading information, which already incorporates the loading added in Rev. 0 of the PCR. Rev. 1 of the PCR only adds more load due to RY-A and RY-B having 0.09 amps additional. The loading on Atttachment 8 shows the loads of each individual device, where it is supplied from, and the total loading to each fuse. MQ-400C and MQ-400E have maximum allowable loadings of 16.9 amps each. The existing load is 14.31 amps on MQ-400C, with 2.59 amps of margin.

Page 12 of 17 Revision 2 DA-EE-2001-009

There is 11.89 amps on MQ-400E, resulting in 5.01 amps margin. The addition of the new SCA300 isolator with an additional 0.09 amps of load will not exceed these margins.

DA-EE-2001-047 shows a maximum load of 1.72 amps to RMS-3 on breaker IBPDPCBC/ 1, and5.70 amps to RMS-l on IBPDPCBE/1. With the addition of the new style SCA300 isolators, they remain well below the 15 and 20 amp breaker ratings of those positions.

7.9 Electrical Noise Reduction Instrumentation cabling has been provided by the vendor. Per Electrical Specification EE-171, the system has been tested to meet the EMIJ/RFI testing in accordance with EPRI TR-102323-Rl. The equipment will be shipped with a test report demonstrating the equipment with supplied cabling meets that standard.

PCR package outputs reference the vendor documents which provide instructions for configuration and connection of all cables and shields to maintain the configuration used to meet these standards.

PPCS connections for analog signals will also use shielded cable and connections per normal construction practices utilized for PPCS inputs. These measures should adequately address instrumentation noise issues.

To avoid potential disturbances caused by the actuation of isolation signals, Quencharc surge suppressors will be installed across the coils of relays R81A and R81B in the control circuits to dissipate energy from relay coils when the contacts open. The Quencharcs across the contacts installed previously will be removed as the single Quencharc in each logic string on the relay coil will provide the appropriate surge suppression for each circuit. This is consistent with installation on related circuits in PCR 98-097, Ref. 4.7.2.

7.10 Control Circuit Logic The overall control circuitry has been designed to maintain the fail-safe operability of the original Control Room HVAC Isolation system, including inputs from both the toxic gas monitors and the new radiation monitors. In all modes, failure of a component due to loss of power (which typically causes a component to return to its de-energized state) will result in the controlling contacts to open, resulting in de-energization of the controlled device, ultimately resulting in the CR isolation dampers returning to their de-energized position, which is in the isolation mode. Loss of power to any component, or to the total circuit, will result in a CR HVAC isolation being initiated.

7.11 Single Failure Revision 2 DA-EE-2001-009 Page 13 of 17 is a block diagram of the control logic for actuation of a control room isolation. The design incorporates both redundancy and cross-train initiation. In summary, there are two redundant trains of isolation logic, each with a manual and automatic isolation device. Any device (A or B manual or A or B automatic) will initiate a CR isolation in BOTH trains. In this way, for any actuation, if any downstream device fails, the opposite train will still receive an actuation signal. The following sections were taken from the document attached to the Tech Spec Amendment RAI, titled "Conformance to IEEE Std 603 for Modifications Associated with License Amendment Request", dated April 26, 2002.

7.11.1 Single Failure Criterion.

The proposed safety system will perform all required safety functions for a design basis event in the presence of (1) any single detectable failure within the safety systems concurrent with all identifiable but non-detectable failures; (2) all failures caused by the single failure; and (3) all failures and spurious system actions which cause or are caused by the design basis event requiring the safety functions. The guidance of Reg. Guide 1.53 and IEEE Std 379 was used to evaluate the system design for single-failure adherence.

7.11.2 The safety function reviewed under the scope of this modification is the initiation of a Control Room isolation signal. The portion of the system enveloped by this review is from the radiation detectors in the air intake duct through the output contacts on the isolation relays in the Auxiliary Benchboard. It includes the power supplies and all inter-connected non-Safety related components. It will not include the isolation dampers and charcoal filter units controlled by the isolation relays - they are beyond the scope of the modification and their design has not been changed by this modification. Final post-modification functional testing does include testing of these devices to ensure that they perform their safety function and were not impacted by the changes.

7.11.3 The protective action that is a result of the proper operation of this system is to provide initiating isolation signals to the isolation devices from the isolation relays upon detection of radiation levels above the setpoints.

7.11.4 There are two redundant safety groups, A train and B train, that are capable independently of performing that function. Each functioning component in each group has a redundant component in the other train. There are two detectors, two ratemeters, two initiation relays, and two manual isolation pushbuttons, with power provided by two separate power supplies. The redundant relays result in two separate output contacts to each of the isolation devices, each contact capable of providing the signal to the isolation device to go to the isolation position.

7.11.5 The design of the system demonstrates that independence between the two safety groups has been established. For initiation of the signals, there are no shared Revision 2 DA-EE-2001-009 Page 14 of 17

components. Each train is powered by a separate power supply, cables run in separate train-dedicated conduits, each relay will operate irrespective of the state of the other relay, manual isolation pushbuttons will provide isolation signals irrespective of the other button or of the status of the automatic isolation signals.

7.11.6 The design of the logic includes cross-train signal connection so that an initiating event on A train (automatic or manual) will initiate an isolation signal to both relays, and likewise for B train. This was incorporated in the design to provide additional redundancy, so that failure of one relay would not prevent a high alarm from the detector of the other train from initiating an isolation. The points of train cross-connection only add redundancy, and there is no resultant single-failure point caused. The points of cross-connections are limited to the wiring of normally open device output contacts into the actuation circuit of the other train.

There is no manner in which the normally open contacts can fail that will disable the opposite train's actuation logic.

7.11.7 Mounting of all redundant components in the same structures (such as both detectors in the duct, both trains of logic in Auxiliary Benchboard, both trains of conduit sharing conduit supports) has been performed in a manner to preclude a single component failure (mounting bolt, etc.) from causing both trains to fail, including design basis seismic events.

7.11.8 The power supplies to the separate trains are independent, separated, and highly reliable, being fed from completely independent UPS systems. There is no common wiring point from the ratemeter location back to the ultimate supply source. Electrical protection in the form of breakers and current limiting transformers have been analyzed in design analysis DA-EE-2001-047 to be appropriately sized to protect all equipment, further reducing the potential for failure on one train of power propagating to devices on the other train. DA-EE 2001-047 also demonstrates the capability of both power supplies to independently supply power adequate for the operation of all equipment required to perform the safety functions. For further protection, all devices powered by the power supplies are configured so that on a loss of power, the output of the devices goes to the isolation initiation state.

7.11.9 System Portions Analysis (section 6.2 of IEEE 379) 7.11.9.1 Both trains of equipment have outputs that supply a signal to the non-lE Plant Process Computer System (PPCS) and non-lE radiation recorders. These signals are analog outputs from each ratemeter to communicate radiation levels to the PPCS and the recorders, and this is a non-safety related function. A failure in either the PPCS or a recorder is prevented from causing a common failure in both ratemeters by insertion of independent qualified 1E optical isolators in the circuits that connect the ratemeters to PPCS and the recorders. The isolators themselves are isolated from the 1E power supply to them by putting 1E fuses in the supply Revision 2 DA-EE-2001-009 Page 15 of 17

circuit.

7.11.9.2 Both trains of isolation actuation logic have signals from the non-IE toxic gas monitoring system (contacts from the toxic gas system processing modules).

These signals and power to the toxic gas power supplies are all isolated from the safety related portion of the design by qualified fuses.

7.11.9.3 A review of the logic demonstrates that there is no single failure point in the circuitry. Refer to Attachment 7 for a block diagram of the system design. The conclusion is that there is no single failure in the system logic that will cause failure in the channels or actuation circuits that would cause loss of the safety functions.

7.11.9.4 Devices in the isolation logic circuits are configured to fail so that any de energized equipment will fail to the position that provides an isolation actuation signal. Power cannot be maintained incorrectly on the actuator system terminals and cause a loss of safety function because multiple normally open contacts in series provide the actuation signal to the isolation relays, and the isolation relays output contacts likewise are normally open in the control circuits of the associated dampers.

7.11.9.5 SK21946-0546SHI-1 and SK21946-0546SH2-1 diagrams of this design, and the series of normally open contacts is apparent. This series of open contacts, coupled with the cross-train connection of the output contacts to each isolation device, provides assurance that even the mechanical failure of contacts to open upon a loss of power in one relay will not prevent the isolation function from occurring due to the opening of the contact in the other train of isolation initiation.

7.11.9.6 The connection of electrical power supplies is completely independent. The malfunction of a power supply in a manner that results in a high voltage would only impact a single train, again due to the cross connection only being via normally open contacts so that no voltage is being supplied from one train to the other.

7.11.10 All other systems or components that are coupled to these safety systems have been integrated so that they cannot fail in a manner to degrade the safety system.

Maintenance bypass switches are designed and installed in the circuit so that a contact block failure will be detected by the indicating lamp associated with each switch. The bypass functions for each train have been connected with separation from the opposing train, and all components qualified and installed safety related.

7.11.11 SRP Appendix 7.1-C Section 6 contains discussion of scope of review beyond IEEE 603 Single Failure Criterion as it pertains specifically to digital I&C equipment. The concerns with digital equipment in that section are centered around the sharing of data, functions, and process equipment inputs such that a design using shared databases and process equipment has the potential to Revision 2 DA-EE-2001-009 Page 16 of 17

propagate a common-mode failure of redundant equipment. This design feature is not applicable to the radiation monitors that are being installed as part of this modification. The redundant monitors do not share any data or process equipment inputs. The two monitors operate independently, with train-specific inputs from the detectors. The output alarm contacts that provide the protective functions will operate independently of the status or signals associated with the redundant train.

Therefore, the digital nature of these monitors does not lead to the propagation of a common-mode failure of this type. The second concern of digital I&C systems is that software programming errors can defeat the redundancy achieved by the hardware architectural structure. In the application of digital technology for this installation, the software functions are very limited in how they impact the system. The digital functions that are part of the safety functions are 1) the calculation of a dose rate based on input signal from the detector, and 2) the signal to the alarm relay to operate to change output contact states, based on user-set alarm setpoint. These two functions have no other inputs or variables other than the dedicated detector signal for that ratemeter. Both of these functions are completely tested before installation by the manufacturer, at the time of installation by post-modification calibration and functional testing, and at normal operating intervals via Technical Specification required channel checks, channel operability tests, and scheduled calibrations. All of this monitoring and testing throughout the operating range of the unit provides assurance that the software functions utilized to initiate the protective functions are properly programmed and operating for each unit, and that there is not a software programming error that will occur that will prevent the equipment from performing its safety function in a manner to cause both units to fail at the same time.

8.0 Conclusions 8.1 The design shown in PCR 99-004 Revision 1 construction package as defined above meets technical operational requirements. The electrical factors described in section 1 above have been evaluated and have been demonstrated to be adequate and appropriate for installation and operation.

Page 17 of 17 DA-EE-2001-009 Revision 2

Specifications a[Jniver.

Digital Raterneter)

The Victoreen Model 956A-201 Universal Digital Rate meter (UDR),when connected Io a Victoreen Model 897A 2XY Geiger.Muclier (GM) tube detector, comprises a monitoring system which operates over a five decade range. Tbe UDR provides display, control, and annuncia tion functions for the monitoring system. and will display readings in the range of 10" to UP mR/h.

Standard features for the instrument consist of a three digit display of the radiation value and a multi-colored bargraph indicator which covers the entire range of the LTDR. The bargraph will change color in the event of an alarm condi tion (green for normal. amber for warning, and red for high). Front panel alarm indicators and rear panel relay outputs for alarm annunciation are also included. Front panel pushbuttons are provided to apply power, display alarm limit set points, acknowledge alarms, and activate the check source.

Analog outputs of 0 - 10 Vdc (1) and 4 - 20 mA (2) are provided for recording and computer monitoring. The outputs may also be used to drive a remote meter or a local (i.e. near the detector) indicator.

All electronics required to interface with the VICTOREEN 897A series GM detector arc included within the 956A-201 UDR. The electronics consist of a high voltage power supply, low voltage DC power supply and the hardware/

software required for UDR operation. The system also includes an overrange indicator to preclude the possibility of on-scale readings when the radiation field is beyond the range of the detector.

Main Display Bargraph Display (Dynamic Range)

Alarm Indicators Pushbuttons Check Source "Alarm AeL Three digits with backlighted radia tion units display and floating deci mal point. Three digits plus expo nent for data entry/display.

Three segments per decade, 10-2 to 106 mR/h (24 segments), tri-color, indicating channel status.

HIGH, WARN. FAIL, RANGE HIGH. High Alarm lunit WARN, Warn Alarm lunit Activates radioactive Check Source and associated green LED indica tor.

"Momentary Non-Latching pushbutton operation" ATarm acknowledgment: causes alarm indicators to go to a steady on state after acknowledgment Power ONIOFF Alternate action pushbutton for AC power to the unit Relay Outputs (Fals.fe operation) HIlGHAlam - I set. DPDT rated 5 A @ 120 Vac (one set 120 Vac powered for use with optional local alarm)

WARNAlzrm - 2 sets. DPDT rated 5 A Q 120 Vac FAIL AIrm' - 2 sets. DPDT rated 5 A @ 120 VacDC. Contact raung for all relays is 5 A @ 29 VDC HV Output 300 Vdc - 1800 Vdc @ 0.4 mA Check Source PWR +15 Vdc @ 20 mA Kalog Outputs Alarm Ack Input Detector Input Accuracy (electronie)

Dimensions (Hi WxD)

Weight Power Operating &

Storage Temp.

Relative Humidity Compatible Detector Heat Loading Accessories &

A=x. Equipment 41o2I)M (2) (500 ohms Max.) and Oto l0Vdc(lk ohm Min.). logarith mic. May be scaled for any one decade (Min.) to the full range of the unit (Max.)

Optically isolated DC input Digital pulse, up to 2000 feet from tUDR. 50 ohm input impedance

+/-E 1% digit (+/- 1% of the displayed value), exclusive of the detector en ergy response 3.5 in. x 5.6 in. x 13.5 in. (8.9 cm x 14.2 cm x 34.3 cm)

Approximately 3.7 lb. (1.67 kg) 120 Vac +/-10%. 50/60 Hz. 28 watts (240 Vac optional) 32 0Fto 122 0F(0cCto+ 50 C) 0 to 95% non-condensing 897A Series, GM (Geiger Mueller tube)

Approximately 96 BTU/h Please Contact our Systems Sales Attachment

/

Page

/

.of

- ee-.-z.oo 

'.ev

-C-6000 Cochran Road CleMand, Ohio 44139 - 3395 e Phone 216 - 248-9300 a Fax 216 - 248-9301

zpenu r, hdbyip Op e r a un r,

a u L X,.

tal ength I

t-c 15...

• p-'teau Leng~th 100 - 150 Vdc "The Model 897A GM DctW= is designed to operate with the Victorcen Model 956A-201 Universal Digital Rateme ter (UDR) or with other Victoreet readouts. Each detector measuts a five decad rage. ThrEe0 nmasurent ranges are availabic: low, mediuma, and high. Tbe low range avers 10"tvahl 0themediumcovers 10" tolO in01 "h.

and the W*hcove n 0o010 mR/h. The Model 897A detector may also be used with the Victorern Model 960 Digital Radiation Monitoring System equipment or the Victorcen Model 856 Analog ReadoUL 0.1 %V 02%NV 0.3%NV Dead Time (Approxiznute) 897A-210, 897A-211 45 microseconds 897A.220, 897A-221 28 microseconds 897A-230, 5MTA-231 20 microseconds Dimensions Weight Housing Material 897A-210, 897A--2 0,

897A-230 897A-211, 897A-.21, 897A-231 F1Il Gas 897A-21O, 897A-211 897A-220, 897A-221 897A-230, 897A-231 7 l/8x3 inches (18.1 x 7.6cu1) 1 lb. (0.45 kg)

Aluminum, weatherproof Aluminum. weatherproof Stainless Steel, weatherproof Stainless Steel. weatherproof Neon I Argon I Halogen Helium / Neon I Halogen Helium I Neon I Halogen Wall Thickness (bare tube) 897A-210, 897A-211 32-40 mg&c/=

897A-220, 897A-221 80-100 mg/cM2 897A-230, 897A-231 80- 100 mg/cm2 Mounting Wall mount Mating Connectors 897A-2x0:

92-7005-17A, 12 Pin Female 92-7005-12A. Bushing 92-7005-9A. Clamp T97A-2x] (stainless steel):

92-7005-15A. 12 Pin Female 92-7005-12A, Bushing 92-7005-13A. Bushing Required Cable Victoreen PIN 50-100 or equivalent with two coaxial con ductors, two twisted pairs, and overall shield.

External Pressure Limit 30 psig Storage Temperature

-10" to 122] (-23" to W0C)

Operating Temperature -10" to 122F (-23" to 50C)

Relative Humidity g to 95% non-condensing Measurable Radiation 897A-210, 897.-211 B97A-220, 897A-221 897A.230, 897A-231 Detector Element Life Energy Dependence of Reading Detector Accuracy Radiation Detected frzamunaf Input Impedance Output Impedance Output Pulse Polarity Output Signal (S0 ohm)

Low Voltage Power Requirements Maximum Cable Length Electronic Exposure Life Discriminator Level Anti-Jam Level lur 2 tolO10mn* ih 102 to I0' mR/h 10- to 0I mR/h Fxcee.s 1000 hours0.0116 days <br />0.278 hours <br />0.00165 weeks <br />3.805e-4 months <br /> at full-scale

+/-15% from 100 keV to 1.5 MeV

+/-: 20% of actual dose for Cs 137 Gamma rays. X-rays

>100 k-ohms 50 ohms Positive

+5 Vdc square-wave

+15 Vdc (Optional +10 Vdc is jumper selectable)

+15Vdc @ 2OmA 1700 feet Approximately IDs fads Adjustable from 0 to +2 Vdc (nominal value = 0.5 Vdc)

Adjustable from 0 to +3Vdc Anti-Jam Oscillator Freq.

Approximately 50 kHz Analog & Digital Monitor Configuration Divide by 2. square wave out put Optional Monitor configuration Raw pulse output (jumper selectable)

iilrnlihrffp~o uS 1Cjvlid.M044139J'cl3.950Phn 2,.164 -289D o.k iF,*Il'-

-B[t-I:1, Page__

2_.. o S........

erw_ *ft Vdc * *uDDhed by da t'l-Plateau Slope 897A-210, 897A-211 397A-220, 97A-221 S97A.230, 897A-231 UA-c4c; 2-P5 If-,-

IEEN Attachment

/

Page 3

of 3

-EC 2Oo

-Xo Area Radiation Monitor GM Detector Model 955A Jul The system consists of a Model 897A series Geiger Mueller (G-M) Tube Detector with integral preamplifier and the Model 956A-201 Universal Digital Ratcmeter (UDR).

Application Area monitoring is used for the detection of X-Ray or gamma radiation in a selected area. The morutorshould be used in any area location where personnel may be exposed to an adverse amount of radiation. Applications include nuclear reactors, accelerators, hot cells, irradiators and any area where radiation sources are handled. These monitors can be used as single channel monitors or grouped together as a multi-channel area monitoring system.

Specifications (Ion Chamber & Preamplifier)

Victoreen 897A-series GM detectors use a thin walled Geiger-Mueller tube to detect ionizing radiation. Each 897A-scnes detector has a GM tube. a check source, and a preamplifier. The check source is a low-level radioac tive source actuated by a + 15VDC meter movement. The preamplifier provides the pulse conditioning and cable driving capability necessary to dnrve a Victoreen 956A 201 series digital ratcmeter.

All 897A-series detectors arc functionally identical. They differ only in housing material, tube type, and range. The 897A series detectors operate in the voltage range between 500 - 650 Vdc.

Features Range: 5 decade between 10- and IO0 mR/h Energy Response: 15% from 100 keV to LS MeV Life Expectancy: Up to 10 Rads No external power needed at detector location Preamplifier integral with detector Seismic tested with high reliability Readout may be remotely located up to 1700 feet Single cable between readout & detector 8 micro Curie -Cl check source Introduction The Victoreen Model 955A is a single-channel area radia tion monitoring system capable of operaung over the ranges of 1 to mR/h. l0' to 10' mR/h. or 100 to l(s mR/h. depending on the detector selected The system monitors gamma radiation over a 5-decade range and provides indication when the radiation level decreases below a fail threshold. exceeds a warn set point, exceeds a high set point, or exceeds an overrange set point. The overrange feature provides twosignificant benefits. First.

it prevents the system from displaying an on-scale, but inaccurate, reading should the detector become saturated.

Second. it lessens the risk of damaging the detector by disabling it during an overrange condition. Relay outputs are available to activate alarm annunciators.

Analog outputs are available forb trend display on a stip chart recorder or computer. In addition, the monitoring system has an integral check source to verify operational integ ri'y.

GDOO Cochran Road e Clevb1and., Ohio 44139.3395

• Phone 216 - 24"3DD o Fax 216 - 248-9301 19SSAMS

INDUSTRIAL CONTROL RELAYS Fixed Contacts Cat. Nos. BF and BFD WHEN ORDERING SPECIFY

"* catalog number of basic relay.

"* If a coil voltage other than listed is required, select the suffix code from the Coil Voltage Table and substitute it for the last letter in the catalog number.

Example: BF8OV for a 110/60 ac coil.

DESCRIPTION Type BF and BFD relays are compact induStrial control relays ideally suited for machine tool and similar applica tions where size is a factor. Type BF Is ac operated, 300 volts maximum.

and the BFD is dc operated. 250 volts.

Fixed contact relays are available in any combination of NO and NC from two to twelve poles. The NO and NC contacts are electrically isolated and both can be used without regard to polanty.

BF and BFD relays have captive clamp terminals fully accessible from the front. a molded coil with low oper ating temperature. and silver alloy contacts suitable for tow voltage cir cuits. Overlap contacts are available.

All contacts feature the exclusive knife-edge design which provides a "self-wiping' action on every closure.

Type BF Type 8FD ULICSA UR, UL File No. E1 9223 CSA certified, File No. LR39402-6, LR28548-1 0, 11 OPTIONS Code Letter or Price Description Catalog Number Adder FASTON Push-on Terminals -

insert letter " after relay type designation in listed catalog number. Example. BFF20F

$1.50 orBFDF20S.................

F per pole Overlapping contacts-NO contact closes before corresponding NC contact opens -

supplied as NO/NC set(s) In serf letter A after relay type designation in listed catalog number. Example, 1B 8FA22F or BFDAF22S................

A per set Filler Relay -

empty relay case for mounting a timer on a BF mounting strip.

Cat No. BFMS, when other relays cannot be used.O......................

O 18 COIL VOLTAGE TABLE BF Coils BFD Coils Volts Ac Hz - - Suffix Code Volts Dc Suflix Code 12 60 H

6 C

24 60 I

12 D

48 60 J

24 L

110 60 V

48 M

208 60 K

95 a

2401220 6W50 G

130 U

440 60 C

240 T

mrr,.,e r *Pflr J'll/MFJ'M.lflIN'q Pane CO3MPLETE RELAYA 12 12 8

7 5

4 0 4 5 6

7 8

BF120F 84F 75F 6F 4SF 180 156 180.

156.

180 180.

84S 75S 65 57S 43S 10U.

186.

210.

210.

210.

210.

NOTE Relays listed above with equal number of NO and NC contact poles ale specially priced -

1 NO and 1 NC pole are supplied at no additional charge.

Attachment_

CONTINUED NEXT PAGE I-A

vT.N July1995 L-21 I

n rllUFN4QlC)N9 Pane Vf%)Uuuri I %1rU11ruuL1Z ILI

• 1 1

3 0

DFE...84..

14 SBF 3 96 Vo.t BFDA 10 VoS t DC Numer Tye f onac I

Basic Relays _j Basic Reimy 0Fof Tt 2060 120 Dc Co6 Pole$

-NO N*C

-ClIOG Cataog Pc (Form A) i(Form 8)

Number Number 2

0 BF20F

$72.

BFDO2S

$102.

2 1

1 11F

72.

11S 102.

4 2

02F

72.

02S 102.

3 6 3

F30F

84.

BFD30S 114.

2 1

21F

84.

215 114.

1 2

12F 140.

0U 114.

0 C1F 84 S

114.

4 0

BF40F 196.

BFD40S 126.

7 1

31F

13.

31S 126 4

62 2

22F 132.

622S 162.

1 3

53F 132.

13S 1262.

0 4

04F

-1962 0

126.

-6 0

BF60F 108.

BFD60S 138.

5 1

51F ice.

51S 138.

4 2

4.F 108.

42S 138.

6 3

3 33F

96.

315 126.

2 4

24F 108.

24S 138.

0 6

6SF 108.

065 138.

8 0

BFB0F 132.

8FD8B,*

152.

7 1

71F 132.

71S 162.

6 2

62F 132-652S 162.

8 5

3 53F 132.

53S 162.

4 4

44F 158.

44S 138.

0 8

08F 132 CBS 162.

10 0

2FI8OF 156.

2BFD100 186.

8 2

82F 156.

82S 186 7

1 3

73F 156.

7/3S 186.

10 6

4 64lF 132.

64S 162 5

5 55F 132 55S 162 4

6 46F 156 46S 186 2

8 28F 156.

28S 186.

L-21 July 1995

INDUSTRIAL CONTROL RELAYS Fixed Contacts Cat. Nos. BF and BFD CONTACT ARRANGEMENTS FOR BF, BFD RELAYS N O. - Normally Open N.C. = Normally Closed 2 Pols 13 Poles I4 Poles "2

N 0 N.O.I 3 N.O.I 2 N.O. I 1 N.O. 0 N.O. 4 N.0- '

2 N.O.I O.I 0 N.o.

-1 1 IIN r.

NCI ONC. I1 NC. 12N.C. 13NC. 1QN.C.I 1N-C 2N.C.

3NC-I 4NC-6 Poles 3

Poles 6 N.O" 5 N.O. 4 N.O. 3 N.O. 2 Nf0.

8 N.O. 7 N.O. 6 N.O. 5 N.O. 4 N.O. 0 N.O.

o-N.C. INC IN.C 3N.C. 4NC ONC ISNC. 2N.C.{ 3 N-.4N.C.-8 N.C Rear y fll fy11filRear Tl H

T F-Front 77 Front 7700 10Poles 12 Poles 6 N.O.

4N T 12 NN.O.

18 N.O. 71N.O.Z15..O.

.N.£.

4 N.C. 5 N.C.

Rear

771 Center iti TT Front f

fill, 6 N.C IT it.

Lill ff44 Q0NC 4 NC. 5 N.C. 6 N..C. 7 N.C._8 N.G;.

ON ?I

i.

HIrw.

L-22 Attachment Page 3-of July 1I M 11111111°°tt1111111

I 10 Current in.

100 1000 FUSE CURVE APPLIES TO PLOTTING VOLTAGE 0 12 kV BUSS KTK OR KLM TYPE BY, 1'"

DA-EE-2001-009 REV.2 PAGEZOF 2 NO. PCR 99-004 REV.1 ATTACHMENT 3 DATE: 5-2-2002 KS

.1.

.5 10000 N

.1 5

1 10 100 1000 lu0 FUSE CURVE APPLIES TO PLOTTING VOLTAGE'O 12 kV BUSS. KTK OR KLM TYPE BY:

DA-EE-2001-009 REV.2 PAGE 2 OF 2 NO: PCR 99-004 REV. 1 ATTACHMENT 3 DATE: 5-2-2002 20

£

')

Codi',

e.--Fil Soe--

dxt enstaIed Existing conduits with new cables in bold C5529 I YA" C5529 1-2-12 0.138 0..552" 0.814" C5530 1-2-12 0.138 C5543 1-2-12 0.138 C5544 1-2-12 0.138 C5529.1 1 1/2" C5529 1-2-12 0.138 0.552" 0.814" C5530 1-2-12 0.138 C5543 1-2-12 0.138 C5544 1-2-12 0.138 C5539 1 /"

C5539 1-2-12 0.138 0.414" 0.814" C5545 1-2-12 0.138 C5546 1-2-12 0.138 C5539_1 1 1/2" C5539 1-2-12 0.138 0.414" 0.814" C5545 1-2-12 0.138 C5546 1-2-12 0.138 New Conduits and Cables C5551 2"

C5551 1-4-12 0.185 0.621" 1.342" AU0235A 1-2TSP-16 0.078 R4522 10/C special 0.358 C5552 2"

C5552 1-4-12 0.185 0.621" 1.342" AU0239A 1-2TSP-16 0.078 R4523 10/C special 0.358 R4522 I V2" R4522 10/C special 0.358 0.436" 1.079" AU0235A 1-2TSP-16 0.078 R4522.1 1 1/2" R4522 10/C special 0.358 0.436" 1.079" AUO235A 1-2TSP-16 0.078 R4522-2 1 /A" R4522 10/C special 0.358 0.358 1.079 R4523 1 1/2" R4523 10/C special 0.358 0.436 1.079" AU0239A 1-2TSP-16 0.078 R4523_1 1 '"

R4523 10/C special 0.358 0.436 1.079" AU0239A 1-2TSP-16 0.078 R4523_2 1 Y21" R4523 10/C special 0.358 0.358 1.079 AU0235A 1 1/2" A0235A 1-2TSP-16 0.078 0.078 1.079 AU0239 I 1/2" A0239A 1-2TSP-16 0.078 0.078 1.079 DA-EE-2001-009 Rev.KZ 0-Ah 4

1

p. I of I

Putter &BrumfieldO Relays "Siemens Electromechanical Components KRPA KRI KA Features

• Industry standard octal-type teimination for Quick installation

• Contact arrangements from 1 form A ISPST - NO) to 3 Form C (3PDT)

• Indicator lamp and push-to-test options available on certain models

• The KRPA seris is the autoimated manufactured version of the KRP series

• Hermetically sealed option available with KR UL recognized for Class I Din 2 Hazardous locations. Groups A. B. C. 0 Contact Data @ 25'C Arrangements: See Ordering Information Table Materials: Silver or siveh-cadmium oxide. with or without gold flashing Eapected Life: 10 million operations min. mechanical. 100,000 operations minn rated loads KA, KRR, KRPA ULCSA Contact Ratings @ 256C (Except KR)

- Cod#

Arnaagem~aVlt contact Rating Y&L

1. 2. 3 Poles 5A @ 120VAC (Silver) 3A @ 240VAC 111OHP 0 120VAC 1/6HP C 24OVAC G&N

1. 2. 3 Poles 10A @ 240VAC (Silver-Cad 1/2 HP 0 240VAC Oxide)

I1/3HP 0 120VAC KRP KRPA Factory Ratings

"" C de IArm.ell "Contac"t Retina'.

Y&L

1. 2. 3 Poles SA 0 28VDC. 120VAC. 80% PF G&N

1. 2.3 Poles 10A 0 2OVDC. 120VAC. 80% PF 6A 0 250VAC KA UL Contact Ratings

.r..Cods.,

Cotat. Ratings y

KAI 5A 0 120VAC. 3A @ 240VAC.

1/10 HP @ 120VAC. 1/6 HP O 240VAC G

KA2 10A @ 120VAC. 6A @ 240VAC 1/6 HP 0 120VAC. 1W3 HP 0 240VAC Il.sted b, CSA foa SAO 120VAC 90% Pr 2LiUtd Wy C.A lam MAO 120VAC 110% K~

Initial Dielectric Strength Between Open Contact-g 500V rms Between All Element: 1.500V rms NIPaw S9 KRPA, KRP ICA KR-E Ordering hnfr*lmun INV* on P1g4 10

~ -eE~e2~

-?s KRPA, KRP, KA, KR series 5 to 10 Amp General Purpose Relay 9d File E29244, E22575, E81558 (KR Hermetic) 6 File LR15734 Coil Data @ 25*C omlna Poer M-lmmm Po T

KRP AC 2VA Open Models - 5VA Enclosed Models - 4VA KRPA DC 12W Open Models - 4W Enclosed Models - 3W KA AC 2VA Open Models - 4VA DC 125mW per movable arm Open Models - 4W Duty CVcle: Continuous Initial Insulation Resistance: KRR KRPA - 1000 Megohms. nfun KA - 100 Megohms, man Coll Data M 25C l.." :.

CRastu.

(aoe

"]. cJVaminalCoulI F__T_______

C-uirret~tA)'

6 32 188 12 120 100 DC 24 472 51 COils 48 1.800 e

266 110 10 000 *-11 5

220 Use 11OV fowv wth 100000 W*

WRsior i.sewres 6

6 335 AC 12

-24 168 Colls 24 8s 84 20 2.250 175 240 9.110 575 Operate Data @ 250C Musit-Operate Voltage:

DQ: 75% or less of nominal voltage AC: 85% or less of noinmal voltage Operate Time (Excluding Bourice)-.

15 milliseconds typical a nominal voltage Release Time (Excluding Bounce):

10 milliseconds typical 0 nominal voltage Environmental Data Temperature Range:

Open Models: AC: -45C to *70*C DCQ -45*C to 4851C Enclosed Models: AC: -45*C to &55"C DQ: -45"C to 470=C Mechanical Data Open Models: Solder terminals Enclosed Models: Octal-type plug

Enclosures:

Transparent polycarbonate texcept KR)

Hermetically sealed metal case available with KR only Weight KA. 17 oz (48 2g) approximately KRPA. KRP: 3 0 z CB5g) approximately k'I'

NUS Instruments SPECIFICATIONS FOR ANALOG ISOLATOR MODULES The analog isolator module, model number as hsted below. Is a solid state signal conditioning and isolation module with one to eight Inputs which provides from one to eight outputs electricaly isolated from the inputs.

lI utnts use the same basic circuils jor isolation and signal conditioning. All mufti-channel FCA units use the same Isolator PC board. The SCA and FIA use PC boards unique to their applications. The FIA has separate DC power supplles for each channel and therefore has electrical separation between the outputs.

MODELS AVAILABLE Model Channels Model Channels Model Channels Model Channels Model Channels SCA100 1

FCA300 SCA101 1

FLA350 SCA102 1

OCA300 SCA103 1

TNPTPr CODE RANGE 4.3.2 4.3.2 1

FCA500 FIA500 OCA500 4.3.2 4.3,2 1

ECAS00 FCAS00 OCA600

'KD' Irr f1tTID"r ANDl POWER RANGE CODES IMPEDANCE CODE RANGE xx 8 4 1

FCAe00 FRA800 oCAe00 4,3.2 4.3.2 1

POWER SOURCE IMPEDANCE CODE RANGE 7.2 Not Loaded 00 0 to 100 mVdc 100M ohms 01 0 to 51 mVdc looM ohms 02 0 to 1 Vdc 100M ohms 03 0 to 5 Vdc 100M ohms 04 1 to 5 Vdc 5.2M ohms 05 o to 10 Vdc 400k ohms 06 4 to 20 mAdc 249 ohms--2o0l 10 to 50 mAdc 100 ohms 08 o to 1 mAdc 50 ohms 09 o to 20 mAdc 249 ohms 11 0 to 50 mAdc 100 ohms 12 50 to 10 mAdc 100 ohms 13 Variable IM ohms 14 0 to 8 Vdc 428k ohms

-10 to I0 Vdc 3.7M ohms Not

-2 to 15 Vdc 2.4M ohms 5 to 1 Vdc 100M ohms 3.6 to 11.6 Vdol77k ohms 2 to 10 Vdc 427k ohms 1.)

-2 to 2 Vdc 3.5M ohms

-20 to 20 mAdc 249 ohms 2.)

N/A 1 to 2 Vdc 3.2M ohms 0 to 4 Vdc 100m ohms 3.)

10 to 32.4 mAdc200 ohms Not Loaded 0 to 100 mVdc 32.9 ohms 0 to 51 mVdc 17.3 ohms 0 to 1 Vdc 299 ohms 0 to 5 Vdc 825 ohms I to 5 Vdc 825 ohms 0 to 10 Vdc Ik ohms 4 to 20 mAdc 1050 ohms' 10 to 50 mAdc 660 ohms*

0 to 180 mVdc 59.3 ohms 0 to 20 IAdc 1050 ohms' 0 to 50 mAdc 660 ohms' 1 to 5 Vdc 249 ohms 10 to 44.29 mAdc660 ohms 00 Not Loaded 08 85-132Vac/125Vdc These are not output impedances but the output drive capabilities of the current output modules.

Some combinations may require alternate specification, consult NUS before ordering.

Other input and output ranges may be available or can be engineered.

Alternate terminal arrangements and multiple output models are also available.

This list is complete as of 05/98.

9WVRONMENTAL' Ambient Temp.:

Relative Humidty:

Pressure:

35 to 122F (2 to 50"C) (Normal Operation - all specifications apply) 35 to 135"F (2 to 57"C) (No damage-Abnormal Operation for 200 hours0.00231 days <br />0.0556 hours <br />3.306878e-4 weeks <br />7.61e-5 months <br />, may operate outside performance specifications)

-40 to 1851F (-40 to 85*C) (Storage) 0 to 95% non-condensing (Operating) 0 to 99% non-condensing (Storage)

Atmospheric *10 psig Radiation Umits:

10 Red TID gamma over forty years Isolation:

3000 Vdc and 1000 Vac (RMS) from Input to output.

(Each Input is isolated from every other to these values) 1000 Vdc and 1000 Vac (RMS) from Input to case Attachment -

Page.

o 2-00 01 02 03 04 05 06 07 08 09 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 zz xx il ý, - C 1.0o 1 -ooA j --

N" 2-

Fault Withstand.

Surge Withstand:

Electrical Class:

480 Vac or 140 Vdc at 20 amps on any port. all ports provide isolatlion from any cot on FRA versions. Same specification except output ports Isolated from power port to 132 Vac only on all other versions.

No damage when the waveform of IEEE.472-1974 Is applied In common or tIansverse mode to any port.

Plant protection, qualified to IEEE 323-1974/1983 and IEEE 344-1975/1987.

POWER.SUPPLY Power NORMAL OPERATION PEAK AND INRUSH 1Ch Series 100. 500 3W,7VA 5W, 18 VA (maximum)

S4 Ch Series 300,350.500, 00 8W, 18VA 12W, 50 VA (ma~amulm) 8Ch Series 600 15 W.36 VA 24 W, 75 VA (maximum)

Supply Voltage:

51to132 Vac.47to63HZor 1l1tol70Vdc. Harmonicsof power lrie frequency. tothe 21st harmonic, comprising up to 60% of the total voltage, present on the power supply port, have no effect on the module output Temperature Effects: Less than 0.025% of output full scale change for a 1"C change In temperture.

Time Response:

Less than 5 msec from application of a step change at the Input to a change in the output (resistive load) of 63% of the final value. (Filters bypassed or not In the circulL)

Accuracy.

eO.10 of output full scale, repeatable to 0.05%.

Linearity.

0.05% of output full scale Freq. Response:

DC to 20 Hz (120 Hz for ac inputs) or as specifled (5 kHz maximum)

Senes 100 Version: (Encapsulated, surface mount, single channel model)

Size:

7.5w x 6.0"h x 2.6'd Weight Approximately 6.8 lbs Series 300 Version: (Encapsulated, surface mount. multi-channel model)

Size:

7.5w x 8.0'h x 2.6"d Weight:

Approximately 9.4 lbs Series 350 Version: (Encapsulated, surface mount. multi-channel independent output model)

Size:

8.5*w x 9.0'h x 2.6"d Weight:

Approximately 11.5 lbs Series 500 Version: (Shelf or rack mount, single or multl-charnei model)

Size:

2.78'w x 7.00"h x 13.75"d + 0.75' front clearance Weight Approximately 4.8 Ibs Series 600 Version: (19' rack mount. multi-channel model)

Size:

17.0w x 1.72"h x 1325'd Weight Approximately 9 Ibs Series 800 Version: (Shelf or rack mount. single or multi-channel model)

Size:

3.37w x 9.50"h x 15.25'd + 125' front clearance Weight Approximately 5.3 lbs 800:. Yellow power LED ard 0.080" pin style test jacks 801: Red power LED and banana style test jacks FOR ADDITIONAL INFORMATION CONTACT:

NUS INSTRUMENTS, INC.

440 WEST BROADWAY IDAHO FALLS, ID 83402 PHONE (208) 529-1000 ALL SPECIFICATIONS ARE SUBJECT TO CHANGE WITHOUT PRIOR NOTICE.

bf'-jf&- 20-Loot¶'0

'Lev 2-.

.-ttachment_

G Page 2_-

of.

2:

CR RADIATION INTAKE MONITORING INSTRUMENTATION (PROPOSED)

_EXISTING CR INTAKE DUCT SENSOR "B" SENSOR PPCS INDICATION "A7 MANUAL ISOLATION

" B" PPCS INDICATIOI "B" MANUAL ISOLATION 1/4

1 TRAIN 1E PC 1/4 ISOLATION AND CHARCOAL FILTER DAMPER & FANS V.*_,4

t. :_' e.5

TRAIN B (Twinco C)

IBPDPCBC/1 1 (C3505) This circuit also feeds CREPB instrumentation.

Safety Related:

R-30 40 VA R-46 40VA Non Safety (FURMS5):

RK-79 50 VA RY-B 18VA IBPDPCBD/05 (C2665) (Twinco D)

R-15 40VA R-16 40VA R-17 40VA R-18 4OVA R-19 4OVA R-20A 40VA R-20B 40VA K850-R15 17VA K850-R16 17VA K850-R17 17VA K850-R18 17VA K850-R19 17VA K850-R120B 17VA

§OyVA 68yA 339 NA 0.67 amps 0.57.amps 2.83:, mps TRAIN A (Twinco E)

IBPDPCBE/01 (C2621) This circuit also feeds CREPA instrumentation.

Safety Related:

R-29 z

R-45 80 VA 0 VA I0 VA 0.67.amps Safety Related: (FURMS4):

R-10A 40VA R-11 40VA R-12 40VA K850-R1OA 17VA K850-R1I 17VA K850-R12 17VA RK-78 50VA 221.0 VA 1.84 amps Non Safety (FURMS3):

R-10B 40VA R-13 40VA R-14 40VA K850-R1OB 17VA K850-R13 17VA K850-R14 17VA RY-10A 7.14VA RY-1I 7.14VA RY-12 7.14VA RY-10B 7.14VA

.RY-13 7.14VA RY-14 7.14VA RY-A 18VA 231.84 VA "OA, -eC- -zC,0,o-00 oo'LV*.

2..

Attachment

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Pagemp.Ls t

1.93 amps S:\\teams\\nog nes\\electrical\\swift\\pcr 99-004 CR Radiation Monitor\\PCR Revision 1\\RMS fuse loads.wpd 4/19/02

R.E. Ginna Nuclear Power Plant Response to RAI Dated August 28, 2002 Enclosure RG&E Procurement Specification EE-171

D0819526-Control Room Radiation Monitor Specification Ginna Station P CR 99-004 Rochicstcr Gas and Elcctric Corporation 89'East Avcnuc Rochcster, NY 14649)

EE-171 Initial Rcvisioii I Fcbruary 25. 2000 FEB Y-8 200

ý-r 3COIMS MANAGBhIEN.I.

Prcparcd by:

Revicwvcd by:

Approved by:

Assigned Engincer A If ii'dc Rcvicwcr Datc:

2 26 Y Date:

-l Datc:

ý2/2S /00t.

Maj cr, I K (t Electric

/l'1 page 1 o r 7

't 1.o 1.0

-Sc0p-e 1.1 This specification dcfincs the performance rcquirements, associated testing and documentation for two duct mounted control room* air intakc radiation monitors.

1.2 The monitors will be used to continuously monitor radiation levels in a 42 inch diamcter control room air intake duct. They will be used to inform the control room when a predetermined limit is cxcccd'cd. They will provide an isolation signal to the control room dampers and a signal to initiate the control room air filtration system. The piant process computer system (PPCS) will receive an analog input from each monitor. A recorder will receive a voltage input from each monitor.

1.3 They arc safety related and shall be supplied in accordance with the requirements of IOCFR50, Appendix B.

1.4 They shall be supplied new (not used or rebuilt).

2.0 Referenced Codes and Standards 2.1 ANSI N45.2.2 (1972). "Packing. Shipping, Receiving, Storage and Handling of Items for Nuclear Power Plants." [ANSI/ASME NQA-2 (1989), "Quality Assurance Requirements for Nuclear Facility Applications:, Incorporates the technical requirements of ANSI N45.2.2],

2.2 ANSI/ANS-HPSSC-6.8.l (1981), "Location and Design Criteria for Area Radiation Monitoring Systems for Light Water Nuclear Reactors" 2.3 ANSI N42.3 (1969), "American National Standard and IEEE Standard Test Procedure for Geigcr-Mullcr (G/M) Counters" 2.4 Updated Final Safety Analysis Report (UFSAR) for R. E. Ginna Nuclear Power Plant 2.5 RG&E drawing 33013-0721, Control Building Ventilation Duet New Outside Supply 2.6 RG&E Design Analysis DA-EE-99-063, PCR 99-001 Electrical Factors Analysis I 2.7 EPRI TR-192323-RI, Guidelines for Electromagnetic Interference Testing in Power Plants, 1997 I 2.8 EPRI TR-1 02348, Guideline on Licensing Digital Upgrades, 1993 EE-171 Page 2 of 7 Revision I EE-171 Page 2 of 7 Revision I

3.0 Design Requircments 3.1 The powcr requirements for each monitor shall have a minimum allowable voltage range of 120 Vac +/-1 0%..The maximum allowable operating voltage rangc and system power requircments (Watts and Volt Amps) shall be provided with the monitors.

3.2 Environmental 3.2 I The ratemcter will be installed in RMS2 in the Control Room. Por Table 3.11.1 of reference 2.4, the normal ambient conditions in the Control Room are less than 1040F. 0 psig. 60% humidity, radiation is negligible.

3.2.2 The detectors will be mounted in the Control Room intake air duct which draws outside air and is located in the Turbine Building. Per Section 2.3.2.2 orrefercnce 2.4, the ambicnt conditions in the air duct are 21F to 91"F, 0 psig 100% humidity.

To provide additional margin, the detectors should operate over a range of -10"F to 122'F.

I 3.2.3 The monitor shall meet the requirements of EPRI TR-l03232-RI and TR-102348.

The testing shall verify that the monitors remain functional with an 8 dB margin I

over the generic emission measurement surveys in the guideline. (Per reference I

2.7.)

3.3 Monitoring Range 3.3.1 In accordance with Section 4.3 and Table 2 of reference 2.2, the required radiation rate range expected during routine monitoring will be 1.OE-2 to 1.0E3+3 mR/hr.

3.4 Indications and Alarms 3.4.1 Each channel shall have a panel mounted ratemeter with audible and visual alarms which will activate at a predetermined exposure rate.

EE-171 Pagc3of 7 Revision I EE-171 Page 3 of 7 Revision I

3.4.2 All contact output logic shall be fail-safe and shall actuate on a loss of power.

Per Section 7.4 of reference 2.6. the high alarm contact outputs of each monitor will interface with Westinghouse BF relays which have 120 Vac coils and have a power requirements of 12 Voll Amps.

Each monitor shall have one double pole double throw (DPDT) high alarm output.

two DPDT warning outputs, two DPDT fail outputs. The fail outputs will be activated upon the following conditions: no counts, loss of power. a hardwarc failure, or detector anti-jam occurs.

The DPDT relay output contacts shall be rated for 5'amps P! 120,Vac or 5 amps

@ 29 Vdc.

In addition, each monitor shall have one 0- 10 Vdc output and one 4-20 mA output that will drive a 250 ohm resistor.

3.5 Detector 3.5.1 Shall be a selftqcuenched halogen G/M counter.

3.5.2 A plot of each detector plateau (count rate versus voltage) shall be supplied. Thc detector operating temperature limits shall be supplied. The affect of the entire temperature operating range on the detector accuracy shall he provided.

I 3.5.3 The range ofthe detector energy dependence ofrcading shall be 80 kcV to 1.5 McV. Thc documentation shall includc the dctcctor accuracy over this range.

3.5.4 Repeated count-rate measurements of a source at a fixed voltage should be made to determine if the counter has become stabilized. To test fbr hysteresis. the plateau voltage shall be traversed in an ascending and then a descending direction with a total elapsed time of less than one hour.

3.5.5 The photosensitivity shall be tested by measuring the background counting rate first with the counter operating in the dark and then with the counter exposed to a stated illumination. The results shall be included in the test report.

EE-171 Page4of 7 Revision 1 EE-171 Page 4 of 7/

Revision I

3.6 Power Supply Voltages 3.6.1 The high voltage power supply must be capable of delivering the maximum current demand and must do so without overloading or loss of regulation. The regulation against line and load variations should be one percent or better. The ripvle should be less than 100 millivolts. (Per reference 2.3.)

3.7 Primary Calibration 3.7.1 This calibration shall be performed with a procedure that uses sources or instruments or both that arc traceable to the National Institute of Standards and Technology (NIST).

3.7.2 The calibration shall include the response to Xc-133, Cs-137 and the ratio of Xe 133 to Cs-137. Cobalt 60 shall be used as the gamma-ray sources in tests ofcount rate versus exposure rate and current versus exposure rate. Strontium 90 can be used for radial sensitivity measurements. The response shall be within.-t20% of the actual exposure rate present at the dctec.tor location.

3.8 Functional Test 3.8.1 The monitor verification of operability shall utilize a check source mechanism that contains a Cs-137 radiological source of sufficient strength for a detector response that is greater than 5 mR/hr.

4.0 Materials 4.1 The detector housings shall be aluminum, weather proof.

4.2 Each detector shall be provided with 1700 feet of shielded cable and connectors.

The cable and connectors shall provide the maximum resistance to electromagnetic interference (EMI).

5.0 Fabrication 5.1 The detectors shall be supplied with hardware suitable for mounting in a 42 inch steel pipe (API 5L, GR. B, 0.375" wall). Referencc 2.5 5.2 The ratemcters shall be supplied with hardware that will allow them to be slid into and out of a 19 inch rack.

EE-171 PageS of 7 Revision I EE-171 Page 5 of 7 Revision I

-4 4...

6.0 Optional Equipment 6.1 A G/M adapter for usc in our Inovision (Victorccn) Model 848-8 field calibrator shall be supplicd. This will be used during secondary calibrations.

6.2 Two non-saFety related ratcmctcrý shall bc supplied with a 0-10 volt input for use in a simulator.

'7.0 Quality Verification Requirements 7.1 RG&E will review the test procedures and the documcntation. RG&E will provide a source survei~lancc of the primary calibration and the functional testing of the monitors.

8.0 Documentation 8.1 The documentation shall providc thc accuracy and drift of the ratcmetcrs (including high alami setpoint) and the detectors., It shall include what cffect changes in pressure, temperature and power supply aging over a 30 month period has on the ratemeters. high alarm setpoint and detectors. It shall include any random effects that may bias the monitor's output.

S.2 The ratemeter fimlware documentation shall include revisions. functional descriptions and any supporting test data.

8.3 The documentation shall include system interconnection drawings with details for installing connectors and terminating, inspecting and testing cables. If applicable, include recommended cable separation and/or routing restrictions.

8.4 A report shall document the requirements of this specification and include the results of the primary calibration and the functional tests.

8.5 The ascending and descending detector plateau curves shall be supplied.

8.6

'fhe high voltage power supply specifications shall be supplied.

8.7 The recommended periodic maintenance including but not limited to calibration practices and frequencies shall be supplied.

8.8 A Certificate of Compliance to this specification shall be supplied.

8.9 For each item, four copies of vendor manuals and drawings shall be supplied.

EE-171 Pagc6of 7 Revision I EE-171 Page 6 of 7 Revision I

S.

Four copies of vendor rccommendcd spare parts list shall bc supplied.

Markinzs and Identification Each ratcnicter. dcteccor. calibration source and standard gcomctry shall include the manufacturer's namc, a serial number.

EE-1 71 Page 7of 7 Revision I S.10 9.0 9.1 EE-171 Page 7 of 7 Revision I

R.E. Ginna Nuclear Power Plant Response to RAI Dated August 28, 2002 Enclosure Certificate of Conformance (C of C)

Purchase Orders for Inovision Equipment

f

p LUw .:-

Radiation Measurements 6045 Cochran Road Cleveland OH 44139 Phone: 440 248-9300 FAX: 440-349-2307 www.inovision.com www.surveymeters.com Date: May 3, 2001 Rochester Gas and Electric Ginna Station Ontario, NY 14519 Customer P.O.:4500008671 Inovision S.O.: 157033 ITEM NUMBER 00010 Ia lb Ic Id 00040 00050 PART NUMBER S157033A 897A-21 0 S157033A1 956A-201-Ml 9481B-1 897A-210 956A-201-Ml DESCRIPTION Assy, Air Intake Radiation Monitor Consisting of:

S/N GM Detector 131, 132 Mounting Hardware N/A Ratemeter 104643, 104644 UDR Mounting HW N/A GM Detector Ratemeter 100762 104645 QTY Lot 2

2 2

2 (1 rack assy)

I 1

CERTIFICATE OF CONFORMANCE It is hereby certified that all articles herewith in the quantities as referenced by your purchase order were manufactured in accordance with the requirements of the purchase order and utilizing previously approved Quality Assurance Manual Version 003, dated 10/9/00, and specifications and drawings applicable to that order. These items are qualified for Class 1E Safty Related applications I.A.W. IEEE 344-1975 per Inovision Test Report 950.366 and appendices 950.353, 353, 338, and 360.

Sincerely, Inovision RMD "rQ iatis QA Manager Formerly Victoreen and Keithley Radiation Measurements