Unit 1 Reactor Containment Bldg Integrated Leak Rate Test Type A,B & C Surveillance Test,Mar 1981.

ML20004E072
Person / Time
Site:	North Anna
Issue date:	03/31/1981
From:	Cartwright W, Stall J VIRGINIA POWER (VIRGINIA ELECTRIC & POWER CO.)
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ML20004E068	List: ML20004E067 ML20004E072
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NUDOCS 8106110104
Download: ML20004E072 (45)
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I REACTOR CONTAINMENT BUILDING INTEGRATED LEAK RATE TEST TYPE A, B, AND C SURVEILLANCE TEST VIRGINIA ELECTRIC AND POWER COMPANY NORTH ANNA POWER STATION UNIT NO. 1 I MARCH 1981 PREPARED BY: APPROVED BY:

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% L LVl J. A. STALL, ENGINEER W. R.CARTWRIGid, CHAIRMAN NUCLEAR OPERATIONS STATION NUCLEAR SAFETY l AND MAINTENANCE OPERATING COMMITTEE l

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TABLE OF CONTENTS Page_

Section ii REFERENCES. . . . . . . . . . . . . . . . . . . . . .

1-1 PURPOSE . . . . . . . . . . . . . . . . . . . . . . .

2-1

SUMMARY

3-1 TYPE A TEST . . . . . . . . . . . . . . . . . . . . .

. . . . . . . . . . . . . . 3-2 GENERAL TEST DESCRIPTION.

3-2 Prerequisites. . . . . . . . . . . . . . . . . . . 3-2 Equipment and Instrumentation. . . . . . . . . . .

I Data Acquisition System. . . . .

Data Resolution System . . . . .

3-3 3-3 3-4 TEST ANALYSIS . . . . . . . . . . . . . . . . . . . .

3-5 TEST RESULTS. . . . . . . . . . . . . . . . . . . . .

I OILRT Results. . . . . . . . . . . . . . . . . . .

Verification Test Results. . . . . . . . . . . . .

3-5 3-6 Type B and C Penetration Leakage To Be 3-6 I Added to Containment Calculated Leakage. . . . . .

Appendices 3A

SUMMARY

OF PRETEST AND POST-TEST CALIBRATION 3A-1 CHECKS ON RTT S AND DEW CELLS . . . . . . . . . .

. . . . . . . . . . 3B-1 3B SITE METEOROLOGY DURING CILRT 3C-1 3C INSTRUMENTATION TABLE . . . . . . . . . . . . . .

3D-1 3D INSTRUMENTATION LOCATIONS . . . . . . . . . . . .

3E-1 3E CONTAINMENT INPUT VARIABLES . . . . . . . . . . .

. . . . . . . . 3F-1 3F LEAK RATE DATA - ABSOLUTE METHOD.

, . . . . . . . . . . . 3G-1 3G CONTAINMENT MASS VS. TIME 3e-1 3N tEAx RATE vS TIME . . . . . . . . . . . . . . . .

g 4A-1 4A 1979 AND 1981 TYPE B DATA

SUMMARY

. . . . . . . 4B-1 4B 1979 AND 1981 TYPE C DATA

SUMMARY

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REFERENCES 1 10CFR50 Appendix J, Primary Reactor Containment Leakage Testing For Water Cooled Power Reactors, April 1976 I 2 ANS N274, Containment System Leakage Testing Requirements, Draft 3, July 1979 3 1-PT-61.1, Reactor Containment Building Integrated Leak Rate Test, February 25, 1981 I

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I I SECTION 1 PURPOSE I The purpose of this report is to present a description and analysis of the Surveillance Types A, B, and C Containment Leak Rate Tests (CILRT) results conducted on the Virginia Electric and Power Company's North Anna Power Station, Unit No. 1.

I This report is submitted as required by 10CFR50, Appendix J, paragraph V.B. (Reference 1).

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SECTION 2

SUMMARY

2.1 TYPE A TEST The North Anna Unit 1 Containment Integrated Leak Rate Test (CILRT) was performed from March 9-11, 1981. The following is I a summary of activities prior to and during the performance of the test.

Pressurization for the Type A test was initiated at approximately 0400 hours0.00463 days <br />0.111 hours <br />6.613757e-4 weeks <br />1.522e-4 months <br /> on March 9, 1981, after satisfactory completion of all test prerequisites, including walkdown of the interior and exterior of the containment building. After several problems I related to removal of H bus for maintenance were encountered and resolved (see Section 3), containment pressurization to 58.3 psia was achieved at approximately 1630 hours0.0189 days <br />0.453 hours <br />0.0027 weeks <br />6.20215e-4 months <br /> March 9, 1981.

At 0200 hours0.00231 days <br />0.0556 hours <br />3.306878e-4 weeks <br />7.61e-5 months <br /> on March 10, 1981, containment temperature stabili-zation criteria were met and the 24 hour2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> leak rate test was I officially started. After approximately 2.5 hours5.787037e-5 days <br />0.00139 hours <br />8.267196e-6 weeks <br />1.9025e-6 months <br /> of data collec-tion, the overall leak rate had dropped to 0.66 La and continued to decrease until the twenty-fourth hour at which time it was less than 0.17 La.

At 0400 hours0.00463 days <br />0.111 hours <br />6.613757e-4 weeks <br />1.522e-4 months <br /> on March 11, 1981, the mass pumpback verification test commenced. At 0515 hours0.00596 days <br />0.143 hours <br />8.515212e-4 weeks <br />1.959575e-4 months <br /> approximately 394 lbm of air had I been pumped into the containment via the service air line. The computer calculated mass increase was within the acceptable limit and the test was secured. At approximately 0900 containment depressurization was initiated.

2.2 LOCAL LEAK RATE TESTS (TYPES B AND C)

The local leak rate testing of containment isolation valves and primary containment penetrations was conducted as required by station procedures. The penetrations tested and their associated leak rates are listed in Section 4 of this report.

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SECTION 3 TYPE A TEST

~I 3.1 EDITED LOG OF EVENTS March 9, 1981 After all procedure initial conditions had been satisfied, the North Anna Unit Number 1 Containment Integrated Leak Rate I Test (CILRT) 1-PT-61.1 began at approximately 0400 hours0.00463 days <br />0.111 hours <br />6.613757e-4 weeks <br />1.522e-4 months <br />.

Containment pressurization was accomplished with approximately 10,000 SCFM tf oil free air. Containment atmosphere was centrolled with containment recirculation air fans operating I with chilled water.

At 0905 hours0.0105 days <br />0.251 hours <br />0.0015 weeks <br />3.443525e-4 months <br /> pressurization of the containment was halted I when H bus was deenergized for maintenance. When H bus was deenergized, power to rad monitors RMS 159, 160, and 162 was lost. This caused the monitors to alarm, which led to I closure of MOV-HV102 and MOV-HV100A. These valves are located in the purge and exhaust line which was the line that was used for pressurization. Containment pressure at this time was 38 psia.

Containment pressurization was reinitiated at 1224 hours0.0142 days <br />0.34 hours <br />0.00202 weeks <br />4.65732e-4 months <br />.

I Pressurization continued until 1630 hours0.0189 days <br />0.453 hours <br />0.0027 weeks <br />6.20215e-4 months <br />, at which time all compressors were secured. The pressure at this time was 58.3 psia.

At 1724 containment recirculation air fan 1-HV-F-1A tripped 8 due to deenergizing H bus once again. An approved jumper was prepared to power 1-HV-F-1A from the J bus. At 2032 hours0.0235 days <br />0.564 hours <br />0.00336 weeks <br />7.73176e-4 months <br /> all I three (3) containment recirculation air fans were once again operable.

At 2215 hours0.0256 days <br />0.615 hours <br />0.00366 weeks <br />8.428075e-4 months <br />, 1-HV-F-lA once again tripped, this time due to I an overload on the feeder breaker used in the temporary jumper written to power 1-HV-F-1A from the J bus.

'E At this time it was decided to perform the type A test with 5 only two (2) operable containment recirculation air fans.

March 10, 1981 Containment temperature stabilization criteria were met at 0200 hours0.00231 days <br />0.0556 hours <br />3.306878e-4 weeks <br />7.61e-5 months <br /> on March 10, 1981.

After approximately 2.5 hours5.787037e-5 days <br />0.00139 hours <br />8.267196e-6 weeks <br />1.9025e-6 months <br /> of data collection, the overall leak rate had dropped to 0.66 La and continued to decrease until the twenty-fourth hour, at which time it was less than I .17 La.

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March 11, 1981 At 0400 hours0.00463 days <br />0.111 hours <br />6.613757e-4 weeks <br />1.522e-4 months <br /> on March 11 the mass pumpback verification test .

commenced. At 0515 hours0.00596 days <br />0.143 hours <br />8.515212e-4 weeks <br />1.959575e-4 months <br />, approximately 394 lbm of air had  !

been pumped into the containment via the service air line. The I computer calculated mass increase was within the acceptable limit and the test was secured. At approximately 0900 hours0.0104 days <br />0.25 hours <br />0.00149 weeks <br />3.4245e-4 months <br /> containment depressurization was started.

3.2 GENERAL TEST DESCRIPTION 3.2.1 Prerequisites In accordance with the North Anna Unit No. 1 CILRT l-PT-61.1, t , the following is a partial listing of prerequisites that are completed and documented prior to containment pressurization.

1. General inspection of the accessible interior and I exterior surfaces of the containment structure was performed.

I 2. All equipment and instrumentation that could be da.maged or destroyed by test pressure was removed or vented.

3. All instrumentation used for this test was calibrated.

4. Valve line-ups, as required, were completed including closure of the containment isolation valves.

5. Componen* cooling and chilled water systems were operable.

6. Plant computers w3re operational and programmed for the CILRT.

7. Instrument location verification tests were completed (see Appendix 3D).

8. The Official Log of Events book was established and available prior to initiation of the CILRT.

3.2.2 Equipment and Instrumentation Pressul-ization of the containment was achieved by utilization I of approximately 10,000 SCFM of oil free compressed air. Air was piped through two (2) aftercoolers in parallel and a refrig-erated air dryer. The dryer was sized to deliver air at approxi-I mately 100 psig with a 40* dew point. Instrumentation and valving were installed to maintain proper monitoring and control during pressurization.

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During the test, the variables necessary to quantify containment leakage were continually monitored using instrumentation which consisted of multiple resistance temperature detectors (RTD'S),

Foxboro dew cells, and two absolute pressure quartz manometers 5 (see Appendix 3C).

A gas totalizer in the service air system was used during the mass pumpback verification test. All test instrumentation I except for the gas totaliser is input into the plant computer for data acquisition and averaging.

3.2.3 Data Acquisition System The North Anna Unit 1 CILRT utilized a Westinghouse Prodac P250 to scan, log, and average, and analyze data received from the I. containment instrumentation.

I The p250 analog scan package reads all analog inputs in a pre-established manner, converts these readings into engineering units, and then stores these values for use by the plant engineers.

For the CILRT, the P250 plant computer monitored the following instrumentation:

Tyge Scan Rate (Sec.)

18 RTD's 20 5 Dew Cells 20 2 Quartz Manometers 2 Instantaneous values of the CILRT instruments were recorded every 5 minutes during the test period using the P250 digital I trend function on the operatcr's console.

A 10 minute time average of the 25 readings, calculated by the I p250 Average and Integrate (A&I) package, was used as input in the plant computer CILRT programs.

I The plant computer CILRT program consists of ILRTDATA, which runs ev_ry 10 minutes, collects A&I data for all the instrumentation, performs sensor validity checks, and calculates weighted average dew point temperature, vapor pressure, weighted average contain-I ment temperature, and containment air mass.

3.2.4 Data Resolution System After the appropriate data has been acquired and averaged utilizing the plant computer system, the results are manually input to a remote computer system for leak rate calculations.

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I 3.2.4.1 Absolute Method Mass Point Analysis The absolute method of mass point analysis consists of calculating I air masses within the containment structure over a period of time from pressure, temperature, and dew point observations during the CILRT. The air masses are computed using the ideal gas law as follows:

M= (P-Pv) V (144) (Eq. 1)

RT where:

M = air mass, lb P = total pressure, psia Pv = average vapor pressure, psia I R = 53.35 ft lbf/lbm *R (for air)

T = average containment temperature, 'R V = containment free volume, ft3 The leakage rate is then determined by plotting the air mass as a function of time, using a least-squares fit to determine the slope, A (dm/dt) . The leak rate is expressed as a percentage of air mass lost in 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> or:

Leak Rate = A/B (-2400) (Eq. 2) where:

A = slope of least squares fit curve I B = y-intercept I The sign convention is such that an outward leak is positive and the units are in percent / day. The air mass is computed separately and the result is correlated as a function of time by means of a Icest-squares fit of the form:

I m = At + B (Eq. 3) l I The slope A and the y intercept B are then used in Equation 2 to determine the leak rate.

A 95 percent confidence interval is calculated using a student's T distribution.

The sum of leakage rate and the 95 percent confidence interval is I the t'CL. Therefore, the leak rate is less than the UCL with a probability of 95 percent.

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I 3.3 TEST ANALYSIS The data obtained from the data acquisition system for the period from 0200 hours0.00231 days <br />0.0556 hours <br />3.306878e-4 weeks <br />7.61e-5 months <br /> March 10, 1981 to 0200 hours0.00231 days <br />0.0556 hours <br />3.306878e-4 weeks <br />7.61e-5 months <br /> March 11, 1981, were I utilized for the test analysis. The interval between approximately 1630 hours0.0189 days <br />0.453 hours <br />0.0027 weeks <br />6.20215e-4 months <br /> March 9, 1981 to 0200 hours0.00231 days <br />0.0556 hours <br />3.306878e-4 weeks <br />7.61e-5 months <br /> March 10, 1981 represents the containment stabilization period.

The leakage rate analysis is performed by Virginia Electric and Power Company's (VEPCO) CILRT program. The input data for the VEPCO CILRT program are shown in Appendix 3E.

The absolute method mass point analysis was used to calculate the containment building leakage rate. The results (Appendix 3F) show I the UCL to be 0.01656 percent / day, which is within the acceptable limit of 0.07/ day (0.075 less t1:e Type C penalty for valves on systems not vented to the contai. ment) .

W' The following appendixes summarize ti.3 plots provided by this report:

I Appendix Description _

3G Containment air mass vs. time 3H Containment leakage rate vs. time The leakage rate test calculations were verified by the mass pump back method. Approximately 4813 ft3 was inserted during approxi-mately 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> of elapsed time. The computer calculated-air mass I was within 0.25 La of the metered value (refer to Section 3.4.2).

3.4 TEST RESULTS 3.4.1 CILRT Results - Mass Point Method

1. Leakage rate calculated, Lam .0126 percent / day

2. 95% upper confidence interval .00394 percent / day I 3. UCL, Lam leakage rate with 95%

confidence interval (1 + 2) .0165 percent / day f~) 4. Correction for types B and C h leakage .005 percent / day

5. Total reportable type A leak I rate .0215 percent / day

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3.4.2 Verification Test Results

1. Metered mass of air inserted 393.75 lbm  !

2. Difference between initial computer air mass and final computer air mass 274.10 lbm

3. 0.25 I 2 verification limit 138.69 lbm I 4. Difference between computer air mass difference and metered air (1-2) 119.65 lbm Therefore, the calculated CILRT air mass increase agreed with the mass pump back verification instrumentation within 0.25 La in accordance with 10CFR50, Appendix J.

3.4.3 Types B and C Penetration Leakage To Be Added to the Containment Calculated Leakage Penetration Leakage Penetration Leakage No. (SCFH) No. (SCFH) 1 0 56A 0 2 0 56B 0 4 0 56D 0 5 0 57A 0 I 7 0.1 60 0 8 0 61 0 62 I 9 10 11 0

0 0

63 64 0

0 0

12 0 70 1.2 I 13 14 15 0

0 1.5 71 79 80 1.3 1.19 0

I 16 17 18 0

0 0

91 82 83 0.04 3.6 0.5 19 0 84 0.03 lI 22 24 25 0

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85 86 97A 0

0.5 0

26 0.6 97C 0 1I 27 28 0 105A 105B 0

0 f 4.0 m 39 0 105C 0.26 40 0.25 113 0 l

E 41 0 114 0.85 l 46 0 32 0 SSB 0 34 0.6 l

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I Penetration leakage No. (SCFH) 100 0 lilD 0 108 0 Total Type C leakage to be added 15.52 SCFH Total Type B leakage to be added 0 SCFH Total Types B and C leakage to be 15.52 SCFH added 0.005 percent / day i NOTE: The above penetrations were in a non-vented valve lineup for the CILRT.

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I APPENDIX 3A SUMMIRY OF PRETEST AND POST-TEST CALIBRATION CHECKS ON RTD'S AND DEW CELLS

1. Test No. 1 (Pre-Test)

a. The temperature difference between each RTD computer point and a calibrated digital thermometer inserted I into a beaker of ice water and a beaker of approxi-mately 100-110* F water was less than 1* F.

NOTE: Acceptance Criteria The temperature difference between each RTD and a cali-I brated reference thermometer was less than or equal to 1 F.

b. The weighted average dew point temperature as deter-I mined by a calibrated psychrometer agreed with the weighted average dew point temperature as determined by the dew cells within 5 F.

NOTE: Acceptance Criteria The weighted average dew point temperature by the I psychrometer is within + 5 F of the weighted dew point average temperature by dew cells.

2. Test No. 2 (Post-Test)

a. The temperature difference between each readily acces-iI sible RTD (computer point) and a calibrated digital thermometer inserted into a beaker of ambient water was less than 1* F.

NOTE: Acceptance Criteria l The temperature difference between each RTD checked

'g and a calibrated reference thermometer was less than

!5 cr equal to 1 F.

lg b. The weighted average dew point temperature as determined E by a ca11brated psychrometer agreed with the average dew point temperature as determined by the dew cells within 5* F.

NOTE: Acceptance Crite?:ia The weighted average dew point temperature by the psychro-

'I meter is within + 5' F of the weighted dew point average temperature by TIE. dew cells.

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APPENDIX 3B SITE METEOROLOGY DURING THE CILRT I BAROMETRIC WIND SPEED TIME TEMP *F PRESSURE (MPH) WIND DIRECTION 0000 33 30.25 3 270*

0100 32 30.24 3 270 I 0200 0300 3400 30 31 30 30.24 30.23 30.23 3

3 4

270*

270*

270*

0500 32 30.23 270 I

4 0600 32 30.23 6 270*

0700 38 30.24 2 320*

0800 45 30.22 7 270*

I 0900 1000 1100 48 48 49 30.22 30.21 30.20 5

5 9

260 260*

250' 1200 49 30.17 8 280*

I 1300 50 30.16 8 320*

1400 50 30.16 12 270*

1500 48 30.17 19 300 I 1600 1700 1800 48 44 41 30.18 30.19 30.17 13 5

4 310*.

270*

260*

l 1900 38 30.18 13 270*

l 2000 37 30.18 8 270 2100 37 30.18 5 180 l 2200 35 30.18 2 120 2300 33 30.16 6 120*

l 2400 32 30.14 6 270*

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APPENDIX 3C ,

INSTRUMENTATION TABLE The following instrumentation was calibrated, and functionally tested, no greater than 6 months prior to performance of the CILRT in accordance with 10CFR50, Appendix J, and Field Cali-I bration Procedures using instrumentation traceable to the National Bureau of Standards.

Instrument Range Accuracy TE-LM-100-3 0-200*F + 0.5*F I TE-LM-100-4 TE-LM-100-5 TE-U1-100-6 0-200*F 0-200*F 0-20G*F I 0.5*F T 0.5*F T 0.5*F T 0.5*F I TE-LM-100-7 TE-LM-100-8 TE-LM-100-9 0-200*F 0-200*F 0-200 F T 0.5*F T 0.5*F TE-LM-100-10 0-200*F T 0.5 F I TE-LM-100-ll 0-200 F T 0.5 F TE-LM-100-12 0-200 F T 0.5 F TE-LM-100-13 0-200*F I 0.5 F I TE-LM-100-14 TE-LM-100-15 TL-2-100-16 0-200*F 0-200 F 0-200 F T 0.5*F I 0.5 F T 0.5 F TE-LM-100-17 0-200*F T 0.5 F I TE-LM-100-18 TE-LM-10 0-19 0-200 F 0-200 F T 0.5 F T 0.5 F TE-LM-100-20 0-200*F T 0.5 F I MT-LM-100-1 MT-LM-100-2 MT-LM-10 0-4 32-110*F 32-110*F 32-110*F I 1 to 2 F I 1 to 2 F T 1 to 2 F MT-LM-100-5 32-110*F ~ 1 to 2*F I MT-U1-100-6 PI-LM-102 32-110*F 0-100 psia r 1 to 2*F T 0.01%

PI-LM-107 0-100 psia T 0.01%

I FIT-LM-100-1 FIT-LM-100-2 0-100 0-100 scfm scfm T 2% of range

[ 2% of range I

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APPEtiDIX 3D INSTRUMENTATION LOCATION ,

I M N l TE-8 TE-7 MT-1

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! TE-12 TE-13 TE-11 TE-19 TE-4

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6(3/ TE-18 TE-20 TE-14 I

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INSTRUMENTATION LOCATION I

-TE-4 MT-2 TE-15 TE-3 TE-8 TE-16 I

MT-5 TE-5 TE-18 TE-13 3 ,

N i \

TE-14 3

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TE-20 TE-ll TT-1 I u-7 m 'o \

MT-1 e\ \ TE-6 l MTP-3 TE-19 TE-17

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APPENDIX 3E VEPCO NORTH ANNA POWER STATION UNIT 1 INTEGRATED LEAK RATE TEST FROM 0206 HOURS ON 3/10/81 TO 0208 HOURS ON'3/11/81 68 DATA SETS ARE IN ABS PRESSURE DEWPOINT VAPOR PRESSURE TEMP TIME PSIA 'F PSIA 'F 0.0 57.944 54.25 0.2081 530.06 0.0350 57.939 54.39 0.2092 530.03 0.700 57.934 54.22 0.2079 529.98 I 1.050 1.417 1.767 57.929 57.927 57.923 54.26 54.38 54.33 0.2082 0.2091 0.2088 529.96 529.92 529.89 57.920 54.24 I 2.117 2.483 2.833 57.916 57.913 54.32 54.41 0.2081 0.2087 0.2094 529.84 529.80 529.78 3.200 57.910 54.41 0.2094 529.75 I 3.550 3.900 4.250 57.906 57.904 57.901 54.56 54.43 54.45 0.2105 0.2095 0.2097 529.72 529.72 529.66

'g 4.600 57.899 54.49 0.2100 529.68

'E 4.967 57.896 54.38 0.2091 529.',4 5.483 57.892 54.50 0.2101 529.61 5.833 57.890 54.56 0.2105 529.61 I 6.183 6.533 6.883 57.888 57.887 57.886 54.53 54.59 94.69 0.2103 0.2107 0.2115 529.60 529.55 529.56 I 7.233 7.583 7.917 57.885 57.885 57.887 a4.60 54.59 54.72 0.2108 0.2107 0.2117 529.55 529.55 529.59 8.267 37.889 54.71 0.2117 529.57 I 8.617 8.983 9.333 57.890 57.891 57.891 54.59 54.71 54.68 0.2107 0.2117 0.2114 529.60 529.58 529.60 I 9.683 10.017 10.393 57.893 57.894 57.894 54.72 54.85 54.78 0.2117 0.2128 0.2122 529.61 529.61 529.63 10.733 I 11.083 11.417 57.895 57.895 57.895 54.65 54.81 54.72 0.2112 0.2124 0.2117 529.65 529.64 529.67 11.767 57.895 54.87 0.2129 529.65 I 12.117 12.483 12.833 57.895 57.895

'7.895 54.81 54.83 54.83 0.2124 0.2126 0.2126 529.67 529.66 529.68 I 13.183 13.533 14.050 57.895 57.895 57.895 54.90 55.00 55.00 0.2131 0.2139 0.2139 529.66 529.67 529.66 14.400 57.895 54.99 0.2138 329.69 14.767 57.895 54.98 0.2138 529.66 I 3E-1

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I ABS PRESSURE DEWPOINT VAPOR PRESSURE TEMP TIME PSIA *F PSIA 'F 15.117 57.895 54.87 0.2129 529.67 I 15.467 15.817 16.167 57.895 57.894 57.893 54.84 55.04 54.76 v.2127 0.2142 0.2121 529.64 529.62 529.60 16.517 57.891 529.63 I

54.84 0.2127 16.867 57.889 54.96 0.2136 529.59 17.217 57.886 54.89 0.2131 529.54 17.567 57.884 54.91 0.2132 529.54 I 17.93's 18.26) 18.633 57.882 57.880 57.878 54.91 55.07 55.04 0.2132 0.2145 0.2142 529.55 529.52 529.49 0.2145 I 19.150 19.517 19.867 57.876 57.875 57.873 55.07 55.26 55.18 0.2159 0.2153 529.45 529.45 529.46 20.217 57.871 55'.15 0.2151 529.44 I 20.567 20.917 11.267 57.868 57.866 57.864 54.90 54.93 54.87 0.2131 0.2134 0.2129 529.38 529.35 529.31 I Pl.617

~1.967 22.317 57.862 57.860 57.859 55.10 54.91 55.04 0.2147 0.2132 0.2142 529.31 529.29 529.31 22.667 57.857 55.03 0.2141 529.28 I 23.033 23.383 23.933 57.855

$7.853 57.850 55.03 55.10 54.95 0.2141 0.2147 0.2135 529.28 529.25 529.19 24.100 57.249 55.07 0.2145 529.20 I

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APPENDIX 3F VEPCO NORTH ANNA POWER STATION UNIT 1 I INTEGRATED LEAK RATE TEST FROM 0206 HOURS ON 3/10/81 TO 0208 HOURS ON 3/11/81 68 DATA SETS ARE CURRENTLY IN I Time

..... ABSOLUTE TEST METHOD, MASS POINT ANALYSIS......

Mass Leakage Conf Ucl Hours Lbm Pct / day Pct / day Pet / day 0.0 536557.17 0.0 0.0 0.0 0.350 536531.16 0.0 0.0 0.0 I 0.700 1.050 1.417 536547.34 536518.28 536531.69 0.062849 0.128421 0.080343 1.113669 0.305207 0.161978 1.176519 0.433627 0.242322 1.767 0.061525 0.160372 I 2.117 2.483 536528.43 536557.53 536555.19 0.008921

-0.011408 0.098847 0.101336 0.077354 0.110257 0.065946 2.833 536541.17 -0.008249 0.058153 0.049904 I 3.200 3.550 3.900 536543.66 536526.16 536516.83

-0.007888 0.002676 0.013165 0.045199 0.038735 0.034518 0.037311 0.041412 0.047683 I 4.250 4.600 4.967 536548.28 536506.57 536527.01 0.006055 0.016375 0.016255 0.030236 0.028778 0.024709 0.036290 0.045153 0.040963 5.483 536511.66 0.020051 0.021692 0.041743 5.833 536488.76 0.027893 0.021050 0.048943 I 6.183 536482.45 0.034162 0.019985. 0.054147 6.533 536519.52 0.030745 0.018218 0.048963 I 6.883 7.233 7.583 536492.92 536500.20 536500.91 0.032563 0.032327 0.031678 0.016451 0.014823 0.013453 0.049013 0.047150 0.045131 7.917 536469.68 0.035021 0.012907 0.047928 I 8.267 8.617 8.983 536509.26 536496.77 536517.73 0.032429 0.031529 0.028350 0.012219 0.011278 0.011074 0.044648 0.042808 0.039424 I 9.333 9.683 10.017 536499.62 536505.23 536505.18 0.027368 0.025879 0.024519 0.010309 0.009728 0.009198 0.037677 0.035607 0.033717 10.393 536489.96 0.024448 0.008578 0.033026 I 10.733 11.083 11.417 536488.33 536486.97 536463.05 0.024374 0.024274 0.025643 0.008020 0.007516 0.007246 0.032394 0.031790 0.032889 f 11.767 12.117 12.483 536472.52 536456.58 536415.27 0.026077 0.027258 0.027650 0.006838 0.006538 0.006246 0.032915 0.033855 0.033896 536445.02 0.028937 0.006101 0.035038 I

12.833 13.183 536460.22 0.029159 0.005784 0.034943 13.533 536442.87 0.030067 0.005590 0.035658 14.050 536452.99 0.030234 0.005304 0.035538 I 14.400 14.767 15.117 536423.33 536454.44 536452.26 0.031576 0.031321 0.031091 0.005270 0.005020 0.004787 0.036846 0.036341 0.035878 0.029562 0.004896 0.034458 I 15.467 15.817 16.167 536484.81 536481.31 536512.48 0.028275 0.025994 0.004906 0.005384 0.033181 0.031377 0.030903 16.517 536457.74 0.025744 0.005159 I 3F-1

I I

E I Time Hours Mass Lbm Leakage Pct / day Conf Pct / day Ucl Pct / day 16.067 536470.99 0.025039 0.005008 0.030048 17.217 536498.79 0.023511 0.005119 0.028630 17.567 536478.74 0.022692 0.005004 0.027696 I 17.933 18.267 18.633 536450.01 536450.21 536464.17 0.02.7723 0.022698 0.022264 0.004805 0.004619 0.004471 0.027528 0.027317 0.026736 I 19.150 19.517 19.867 536483.92 536460.78 536437.87 0.021302 0.020968 0.021173 0.004439 0.004289 0.004138 0.025740 0.025257 0.025311 20.217 536441.71 0.021231 0.003990 I

0.025221 20.567 536492.73 0.020127 0.004052 0.024179 20.917 536502.35 0.018896 0.004160 0.023056 21.267 536528.62 0.017220 0.004457 0.021677 I 21.617 21.967 22.317 536493.34 536508.78 536469.78 0.016377 0.015295 0.015013 0.004417 0.004450 0.004320 0.020794 0.019745 0.019332 I 22.667 23.033 23.383 536482.30 536463.69 536470.40 0.014511 0.014357 0.014085 0.004223 0.004096 0.003983 0.018734 0.018453 0.018067 23.933 536514.18 0.013078 0.004026 0.017104 24.100 536486.03 0.012612 0.003943 0.016555 I Initial Estimated Mass - 536526.23 Final Estimated Mass - 536458.29 I

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I .

SECTION 4 LOCAL LEAK RATE TESTS (TYPES B AND C)

Local .'eak rate tests were performed by pressurizing with air the

'I penetra< ions listed in the following tables and either measuring leakage across containment isolation valves (Type C) or across resilient seals (Type B).

The total Types B and C leakage documented was verified to be in accordance with station procedures. The following pages list the penetrations tested and their documented leakage.

I I -

I I

IC I

I .

I .

I I ~

I 4-1

I APPENDIX 4A 1979 TYPE B DATA

SUMMARY

Equipment Leakage Penetration Tested (scf/m) Remarks Fuel Transfer Tube Blind Flange 0 Equipment Hatch and 0-Ring Escape Lock 0 Personnel Air Lock 0 and Escape Door Electrical Penetration '

No.

l-A Cannister 0 1-A O-Ring 0 1-B Cannister 0 1-B O-Ring 0 1-C Blind Flange 0 1-C O-Ring 0.033 1-D Blind Flange 0.007 1-D O-Ring 0.011 1-E Cannister 0 I l-E 2-A 2-B O-Ring Blind Flange 0

0 0

2-C 0 2-D 0 2-E O 3-A 0 3-B 0 3-C 0 3-D 0 3-E I

O 4-A Blind Flange 0 4-B 0 4-0 0 I 4-D 4-E 5-A 0

0 0

5-B 0 5-C 0 ,

5-D 0 5-E O I 6-A 6-B 6-C Blind Flange 0.022 0

0 6-D 0 6-E 0 4A-1 l

I Equipment Leakage  ;

Penetration Tested (scf/m) Remarks 1 7-A o i 7-B Blind Flange 0 7-C 0 I 7-D 7-E 8-A 0

O o

I 8-B 8-C 8-D 0

0 0

8-E Blind Flange 0 9-A 0 9-B 0.036 9-C 0 I 9-D 9-E 10-A 0

O 0.043 10-B I

0 10-C 0.025 10-D 0 10-E O ll-A Blind Flange 0 ll-B Blind Flange 0 ll-C Blind Flange 0 ll-D Blind Flange 0 ll-E Blind Flange 0 12-A 0 12-B 0 l

12-C 0 12-D 0 12-E O 13-A 0 13-B 0 13-C 0 13-D Elind Flange 0 I 13-E 14-A 14-B O

0 0

I 14-C 14-D 14-E Blind Flange Blind Flange 0.018 0

0.015 15-A 0.029 15-B 0 l 15-C Blind Flange 0 15-D 0

.I l

15 -E 16-A 16-B O

0 0

16-C 0 16-D 0 16-E Blind Flange 0 l

4A-2

Equipment Leakage I P,enetration Tested (scf/m) Remarks 17-A 0 17-B 0 17-C 0 17-D 0 17-E O 18-A 0 18-B 0.018 18-C Blind Flange 0 18-D 0 18-E 0 19-A 0 19-B Blind Flange 0 19-C Blind Flange 0 19-D 0 19-E Blind Flange 0 20-A 0 20-B 0 20-C 0 20-D 0 20-E Blind Flange 0 21-A 0.020 21-B 0 21-C 0 21-D 0 21-E O 22-A 0.018 22-B 0 22-C 0 22-D 0.025 22-E O 23-A Blind Flange 0.011 23-B Blind Flange 0 23-C 0 23-D 0 23-E O l 24-A Cannister 0.007 24-A O-Ring 0

,I 24-B Cannister 0 l 24-B O-Ring 0 24-C Cannister 0 24-C 0-Ring 0 l 24-D Cannister 0.018 l

24-D O-Ring 0.014 24-E Cannister 0.014 24-E O-Ring 0.007 4A-3

I 1981 TYPE B DATA

SUMMARY

Equipment Leakage Penetration Tested (scf/m) Remarks Fuel Transfer Tube Blind Flange 0 Equipment Hatch and 0-Ring Escape Lock 0 Personnel Air Lock 0 and Escape Door Electrical Penetration No.

1-A Cannister 0.021 1-A O-Ring 0.038 1-B Cannister 0 1-B O-Ring 0.016 1-C Blind Flange N/A I l-C 0-Ring 0.027 1-D Blind Flange 0.028 .

1-D O-Ring N/A 1-E Cannister 1-E O-Ring 0 2-A Blind Flange 0 2-B 0 2-C 0 2-D 0 l

2-E O 3-A 0 3-B 0 3-C 0 3-D 0 I 3-E 4-A 4-B O

0 0

4-C 0 4-D 0 4-E O 5-A 0 t

l I 5-B 5-C 5-D 0

0 0

5-E O 6-A 0.036 6-B 0.038 6-C Blind Flange 0 6-D 0 i

I 4A-4

I Equipment Leakage Penetration Tested (scf/m) Remarks 6-E o 7-A o i 7-B Blind Flange 0 7-C o 7-D o 7-E 0.027 8-A o 8-B 0 8-C 0 8-D 0 8-E Blind Flange 0.027 9-A 0 I 9-B 9-C 9-D 0.041 0.050 0.012 I 9-E 10-A 10-B O

0.050 0

10-C 0.021 I 10-D 10-E ll-A Blind Flange 0

O 0

ll-B Blind Flange 0.034 ll-C Blind Flange 0 ll-D Blind Flange 0 ll-E Blind Flange 0.025 I 12-A 12-B 12-C 0.018 0

0 I 12-D 12-E 13-A 0

0 0

13-B 0 13-C 0 13-D Blind Flange 0 14-A 0 I 14-B 14-C 14-D 0.047 0.036 0.027 14-E I 15-A 15-B 0.036 0

0.047 15-C Blind Flange 0 15-D 0.047 15-E 0.048 16-A 0.054 I 16-B 16-C 16-D 0.045 0.038 0

16-E Bliid Flange 0.021 4A-5

I I Penetration Equipment Tested Leakage (scf/m) Remarks 17-A 0.010 17-B 0 17-C 0

,g 17-D 0.045 g 17-E 0.036 18-A 0.012 18-B 0 I 18-C 18-D 18-E Blind Flange 0.027 0.036 O

I 19-A 0.039 19-B Blind Flange 0 19-C Blind Flange 0 19-D 0.027 I 19-E 20-A 20-B Blind Flange 0.027 0

0 20-C I 20-D 20-E Blind Flange 0

0 0

21-A 0.023 I 21-B 21-C 21-D

, 0.030 0.050 0.050 I 21-E 22-A 22-B 0.009 0

0 22-C 0 22-D 0 22-E O 23-A Blind Flange 0.043 I 23-B 23-C 23-D Blind Flange 0 0.028 0.036 I 23-E 0.036 l 24-A Cannister 0 24-A O-Ring 0.011 24-B Cannister 0.022 24-B O-Ring 0.022 24-C Cannister 0.043 24-C 0-Ring 0.036 I 24-D Cannister 0.052 24-D O-Ring 0.041 24-E Cannister 0 24-E O-Ring 0.043 FB#1 0 4A-6 1 .. - - - . . .. . . . . _ _ _ _ - _ - . . _ .

APPENDIX 4B TYPE C TESTING SUMMABY 1979 Pre Repair Post Repair Leakage Leakage Penetration No. Valves Tested SCFil SCFil Remarks 1 Component Cooling from TV-CC-103B 0 NA RilR IIeat Exhanger 2 Component Cooling to RIIR l-CC-193 0 NA IIcat Exchanger 4 Component Cooling to 1-CC-198 -

0.11 .03 RilR IIeat Exchanger 5 Component Cooling from TV-CC-103A .07 .02 RIIR IIeat Exchanger 7 Iligh IIead Safety Injection 1-Sl-79 MOV 1867C 5.0 2.21 1-Sl-77 MOV 1867D a

y 8 Component Cooling from TV-CC-101A 0.16 0.04 H RCP Thermal Barrier TV-CC-101B 9 Air Recirculation 1-CC-572 89 0 Cooling Water 10 Air Recirculation 1-CC-559 89 0 Cooling Water 11 Air Rccirculation 1-CC-546 89 0 Cooling Water 12 Air Recirculation TV-CC-100B 0 NA Cooling Water TV-CC-105B 13 Air Recirculation TV-CC-100C 0 NA Cooling Water TV-CC-105C 14 Air Recirculation Cooling TV-CC-100A 0 NA Water Inside Containment TV-CC-105A 15 Charging 1-CII-3 2 2 0.35 0.136 MOV-1289A

m M M M m m M M M M M m M .

m Pre Repair Post Repair

, . Leakage Leakage i

Penetration No. Valves Tested SCFH SCPH Remarks 16 Component Cooling to 1-CC-154 0.15 0.04 RCP's Shroud Cooling Coils TV-CC-104C 17 Component Cooling to 1-CC-119 0.08 0.01 RCP's Shroud Cooling Coils TV-CC-104B 18 Component Cooling to 1-CC-84 3.4 1.5 RCP's Shroud Cooling Coils TV-CC-104A 4

19 Seal Water from MOV-1380 0 NA RCP's 1-CH-402 MOV-1381 20 SI Accumulater Makeup 1-SI-110 0 NA 1-SI-58

, u 22 High Ilead SI l-SI-185 0 NA y MOV-1836 w

24 RIIR To RWST l-RH-36 0 NA l-RH-37 25 Component Coolina from TV-CC-102E 0.08 0.02 RCP's & Saroud Cooling Coils TV-CC-102F 26 Component Cooling from TV-CC-102A 0 NA RCP's & Saroud Cooling Coils TV-CC-102B 27 Component Cooling from TV-CC-102C 0 NA RCP's & Saroud Cooling Coils TV-CC-102D i'

28 RC Letdown RV 1203, IICV-1200A 9.0 9.0 HCV-1200B, IICV-1200C liCV-ll4 2, TV-120 4 31 Component Atm. Cleanup 1-IIC-14 0.25 0.25 1-ilC-31 1-IIC-12

Pre Repair Post Repair Leakage Leakage

. Penetration No. Valves Test'd SCFil SCFH Remarks 33 Primary Drains TV-DG-100A 0 NA

, Transfer Pump Discharge TV-DG-100B 38 Sump Pump Discharge TV-DA-100A 0.95 0.37 TV-DA-100B 39 SG Blowdown TV-BD-100A 89 0 TV-BD-100B i

40 SG Blowdown TV-BD-100E O NA TV-BU-100F 41 SG Blowdown TV-BD-100C 0.36 0.56 TV-BD-100D 42 Service Air 1-SA-58 0 NA i

a 1-SA-57 to E 43 Air Monitor Sample TV-RM-100D 0.04 0.01 4

TV-RM-100A 44 Air Monitor Sample TV-RM-100B 0 NA TV-RM-100C 1

45 PG Water 1-RC-149 789 0.03 j TV-I$19A 46 Loop Fill 1-Cll-3 3 0 200 0.41 4 FCV-ll60 47 Instrument Air TV-IA-102A 4.6 2.03 1-IA-55 48 Priamary Vent Header TV-VG-100A 0.06 0.02 1

TV-VG-100B 50 Nitrogen to Waste Gas HCV-1936 0.85 0.33 i Charcoal Filters TV-SI-101

m m M M m M M M M M M M M M M Pro Repair Post Repair Leakage Leakage Penetration No. Valves Tested SCFil SCFII Remarks 53 Nitrogen to PRT l-SI-106 0.35 0.14 TV-SI-100 54 Primary Vent Pot Vent 1-DA-39 0 NA 1-DA-41 55 PRT Gas Space Sample TV-SS-104A 0 NA Vent TV-SS-104B

.55B Containment Leakage TV-LM-100E 0.10 0.03 Monitoring TV-LM-100F 56 Primary Coolant Cold TV-SS-102A 0 NA Leg Sample TV-SS-102B 4

56B Primary Coolant TV-SS-106A 0 NA l u Ilot Leg Sample TV-SS-106B

?

A 56C PZR Liquid Space TV-SS-100A 0 NA Sample TV-SS-100B 56D SG Blowdown Sample TV-SS-112A 0.02 0.01 TV-SS-ll2B 57 Containment Leakage TV-LM-100G 0 NA Monitoring TV-LM-100A 57B PZR Vapor Space TV-SS-101B 0 NA Sample TV-SS-101A l

60 Low IIead SI Discharge 1-SI-207 0 NA l MOV-1890B l

61 Low IIead SI Discharge 1-SI-206 0.7 0.27 MOV-1890A

m M M M M M M M M M M M M M M m Pre Repair Post Repair Leakage Leakage Penetration No. Valves Tested SCFil SCFli Remarks 62 Low IIead SI Discharge MOV-1890C,MOV-1890D 2.6 0.17 1-SI-197,1-SI-199 l-SI-195 l 63 QS Pump Discharge MOV-OS-101B 0 NA l-OS-19 64 QS Pump Discharge MOV-OS-101A 0 NA

l-OS-11 66 Casing Cooling to MOV-RS-100A 1.55 0.6 Recirculation Spray MOV-RS-101A 67 Casing Cooling to MOV-RS-100B .11 4.85 Recirculation Spray

• 70 Recirculation Spray MOV-RS-156B 0.17 0.05 7 Pump Dicharge 1-RS-27 w

71 Recirculation Spray MOV-RS-156A 0 NA Pump Discharge 1-RS-18 79 Recirculation Spray MOV-SW-103D 89 0 Valve Service Water Reworked i

80 Recirculation Spray MOV-SW-103C -

10.5 2.87 Valve Service Water Reworked 81 Recirculation Spray MOV-SW-103B 10 5.9 l Service Water .

82 Recirculation Spray MOV-SW-103A 3.6 89 0

< Service Water i

83 Recirculation Spray MOV-SW-104D 89 0.85 Service Water

m m M M M M M M M M M M M M M M M M Pre Repair Post Repair Leakage Leakage Penetration No. Valves Tested SCFil SCFil Remarks

, 84 Recirculation Spray MOV-SW-104C 15 0 Valve Service Water Reworked 85 Recirculation Spray MOV-SW-104B 9 0 Valve Service Water Reworked 86 Recirculation Spray MOV-SW-104A 89 4.7 Service Water 89 Air Ejector Vent TV-SV-102-1 4 0.12 TV-SV-102-1 TV-SV-103 Reworked 90 Purge Duct MOV-:lV-100C 6.4 6.4 MOV-IIV-100D

• MOV-IIV-101

& 91 Purge Duct MOV-IIV-10 0 A 4.2 4.2 y MOV-IIV-100B m MOV-liv-102

• 92 Containment Vacuum TV-CC-150C 0 NA Pump Suction TV-CC-150D 93 Containment Vacuum TV-CC-150A 0 NA Pump Suction TV-CC-150B 94 Ejection Suction TV-CV-100 11.2 1.25 1-CV-4 97 Liquid Sample TV-SS-103B -

0 NA 97B PZR Dead Weight 1-RC-176 0 NA Calibrator 1-RC-178 97C Containment Leakage TV-LM-100B 0 NA Monitor System TV-T.M-100A

Pre Repair Post Repair Leakage Leakage Penetration No. Valves Tested SCFil SCFil Remarks 100 Wet Layup 1-WT-491 0 NA 1-WT-488 103 Refueling Purification 1-RP-28 O NA Inlet 1-RP-26 104 Refueling Purification 1-RP-6 Outlet 1-RP-8 -

0 NA 105 Containment Leakage TV-LM-100D 5.6 2.47 Sonitor System TV-LM-100C 105B Containment Leakage TV-LM-101B 19.77 0 Monitor System TV-LM-101C 105C Centainment Leakace TV-LM-10lD 0.35 0.10 Monitor System TV-LM-101A

" TV-1842 106 SI Test Line 0 NA TV-1859 109 Containment ATM l-lic-18,1-I:0-16 0.95 0.37 Cleanup 1-IIC-28 113 Iligh IIead SI 1-SI-90 0.26 0.20 MOV-1869B 114 Iligh IIead SI l-SI-201 3 3 MOV-1869A

M M M M M M M M M M M M M M M M 1981 TYPE C TESTING

SUMMARY

Pre Repair Post Repair Leakage Leakage Penetration No. Valves Tested SCFII SCFII Remarks 1 Component Cooling TV-CC-103B 0 N/A From RIIR lleat Exchanger 2 Component Cooling 1-CC-193 0 N/A to RIIR lleat Exchanger 4 Component Cooling 1-CC-198 0 N/A to RilR IIeat Echanger 5 Component Cooling TV-CC-103A 0 N/A From RiiR IIeat Exchanger 7 Iligh IIcad Safety 1-SI-79 MOV-186?C Injection 1-SI-77 MOV-1867D .10 fl0

$i 8 Component Cooling TV-CC-101A Prom RCP Thermal Barrier TV-CC-101B 0 N/A 9 Air Recirc Cooling Water 1-CC-572 0 N/A 10 Air Recirc Cooling Water 1-CC-559 0 N/A 11 Air Recirc Cooling Water 1-CC-546 0 N/A 12 Air Recirc Cooling Water TV-CC-100B 0 N/A TV-CC-105B 13 Air Recirc Cooling Water TV-CC-100C 0 N/A TV-CC-105C 14 Air Recirc Cooling Water TV-CC-100A 0 N/A Inside cont. TV-CC-105A 15 Charging 1-CII-3 2 2 .15 .15 MOV-1289A 16 Comp. Cooling to 1-CC-154 0 N/A RCP,s Shroud Cooling TV-CC-104C Coils

M M M M M M M M M M M M M M M M Pre Repair Post Repair Leakage Leakage Penetration No. Valves Tested SCFil SCFil Remarks 17 Comp. Cooling to 1-CC-119 0 N/A RCP's Shroud Cooling TV-cc-104B Coils 18 Comp. Cooling to 1-CC-119 0 N/A RCP's Shroud Cooling TV-CC-104A Colis 19 Seal Water From RCP's MOV-1380 -

0 N/A 1-Cll-4 02 MOV-1381 .

20 SI Accumulater Makeup 1-SI-110 . O N/A 1-SI-58 22 liigh IIead SI 1-SI-185 0 N/A

$ MOV-1836 I 24 RIIR to RWST l-RII-3 6 0 N/A

l-Ril-3 7 25 Comp. Cooling From TV-CC-102E 0 N/A I RCP's & Shroud Cooling TV-CC-102F Coils 26 Comp. Cooling From TV-CC-102A .6 .6 I RCP's & Shroud Cooling TV-CC-102B d

Coils 27 Comp. Cooling From TV-CC-102C 0 N/A RCP's & Shroud Cooling TV-CC-102D Coils i 28 RC Letdown RV-1203,IICV-1200A, 4 4

., IICV-120 0B ,IICV-1200C ,

IICV-ll4 2, TV-1204

M M M M M M M M M M M M M M M M M Pre Repair Post Repair Leakage Leakage Penetration No. Valves Tested SCFH SCFil Remarks 29 Cont. Atm. Cleanup 1-IIC-14 0 N/A 1-IIC-31 1-IIC-12 32 Wet Layup 1-WT-468 0 N/A 1-WT-465 33 Primary Drains Transfer TV-DG-lOOA 0 N/A Pump Discharge TV-DG-100B 34 Fire Protection 1-FP-2.52 .6 .6 1-FP-274 38 Sump Pump Dischg. TV-DA-100A .55 .55

, TV-DA-100B to E 39 SG Blowdown TV-BD-100A 0 N/A o TV-BD-100B 40 SG Blowdown TV-BD-100E .25 .25 TV-BD-100F

41 SG Blowdown TV-BD-100C 0 N/A l TV-bd-100D i

42 Service Air 1-SA-58 0 N/A 1-SA-57 43 Air Monitor Sample TV-RM-100D 0 N/A TV-RM-100A 44 Air Monitor Sample TV-RM-100B 0 N/A TV-RM-100C 45 PG Water 1-RC-149 0 N/A TV-1519A

• 46 Loop Fill 1-Cll-3 3 0 0 N/A FCV-ll60

M M M M M M M M M M M M M M M M Pre Repair Post Repair Leakage Leakage Penetration No. Valves Tested SCFil S C Fil Remarks 47 Inst. Air TV-IA-102B 0 N/A 1-IA-55 48 Primary Vent IIcader TV-VG-100A 0 N/A TV-VG-100B 50 Nitrogen to Waste Gas  !!CV-1936 0 N/A Charcoal Filters TV-SI-101 53 Nitrogen to PRT l-SI-106 ,0 N/A TV-SI-100 54 Primary Vent POT Vent 1-DA-39 0 N/A 1-DA-41 u 55 PRT Gas Space Sample TV-55-104A 0 N/A 7 Vent TV-55-104B w

55B Cont. Leakage Monitoring TV-LM-100E 0 N/A TV-LM-100P 56 Primary Coolant Cold TV-SS-102A 0 N/A Leg Sample TV-SS-102B

56B Primary Coolant Ilot TV-SS-106A 0 N/A Leg Sample TV-SS-106B 56C PZR Liquid Space TV-SS-100A 0 N/A Sample TV-SS-100B 56D SG Blowdown Sample TV-SS-ll2A 0 N/A TV-SS-ll2B

57 Cont. Leakage Monitoring TV-LM-100G 0 N/A TV-LM-100A 57B PZR Vapor Space Sample TV-SS-101B 0 N/A TV-SS-101A

_ __-._m- . _ _ _ _ _ _ _ _ _ _ _ _ _ . . _ _ _ _ _ _ _ _ _ _ _ _

Pre Repair Post Repair

. Leakage Leakage Penetration No. Valves Tested SCFII SCFil Remarks 60 Low IIcad SI Dischg. 1-SI-207 0 N ,'A MOV-1890B 61 Low Ilead SI Dischg. 1-SI-206 0 N/A Mov-1890A 62 Low Ilead SI Dischg. MOV-1890C,Mov-1890D 0 N/A 1-SI-197,1-SI-199 1-SI-195 63 QS Pump Dischg. MOV-OS-101B 0 N/A 1-QS-19 64 QS Pump Dischg. MOV-QS-101A 0 N/A g 1-OS-ll i

[ 66 Casing Cooling To MOV-RS-100A 4 4 Recirc Spray MOV-RS-101A 67 Casing Cooling To MOV-RS-100B 0 N/A Recirc Spray MOV-RS-101B 70 Recirc Spray Pump MOV-RS-156B 1.2 1.2 Dischg. 1-RS-27 71 Recirc Spray Pump MOV-RS-156A 1.3 1.3 Dischg. l_RS-18 79 Recirc. Spray Service MOV-SW-103D 790 4.6 Valve Rcworked Water 80 Recirc. Spray Service MOV-SW-103C 790 0 Valve Reworked Water 81 Recire. Spray Serv. Water MOV-SW-103B 1.0 1.0 82 Recirc. Spray Serv. Water MOV-SW-103A 3.6 3.6

m M M M M M -

Pre Repair Post Repair Leakage Leakage Penetration No. Valves Tested SCFil SCFH Remarks 83 Recire. Spray Serv. Water MOV-SW-104D .5 .5 84 Recirc. Spray Serv. Water MOV-SW-104C 90 8 Valve Reworked 85 Recirc. Spray Serv. Water MOV-SW-104B 90 0 Valve Reworked 86 Recirc. Spray Serv. Water MOV-SW-104A .5 .5 I 89 Air Ejector Vent TV-SV-102-1 17 .95 TV-SV-102-1 4

Reworked 90 Purge Duct MOV-IIV-100C 5 5 MOV-IIV-100D

, $ MOV-IIV-101 I

U 91 Purge Duct MOV-IIV-100A 3 3 MOV-liv-100B MOV-IIV-10 2 92 Cont. Vacuum Pump Suction TV-CC-150C 0 N/A TV-CC-150D 93 Cont. Vacuum Pump Suction TV-CC-150A 0 N/A i TV-CC-150B 94 Ejection Suction TV-CV-100 0 N/A 1-CV-4 97 Liquid Sample /-SS-103B 0 N/A 97B PZR Dead Wt. Caubrator 1-RC-176 0 N/A l-RC-178 -

97C Cont. Leakage Monitor TV-LM-100B 0 N/A System TV-LM-100A 100 Wet Layup 1-WT-491 0 N/A 1-WT-488

m M Pre Repair Post Repair Leakage Leakage

.,n No. Valves Tested SCFil SCFII Remarks 103 Refueling Purification 1-RP-28 0 N/A Inlet 1-RP-26 104 Refueling Purification 1-RP-6 0 N/A Outlet 1-RP-8 105 Cont. Leakage Monitor TV-IJ1-10 0 D 1.9 0 TV-LM-100D System TV-LM-100C Reworked 105B Cont. Leakage Monitor TV-LM-101B 0 N/A System TV-LM-101C 105C Cont. Leakage Monitor TV-LM-101D .255 N/A System TV-LM-101C .

106 SI Test Line TV-1842 0 N/A

[ TV-1859 108 Wet Layup 1-WT-514 0 N/A 1-WT-511 109 Cont. ATM Cleanup 1-IIC-18,1-IIC-16 0 N/A 1-IIC- 2 8 113 liigh Ilead SI l-SI-90 0 N/A MOV-1869B 114 Iligh IIead SI l-SI-201 .85 N/A MOV-1869A