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* REACTOR CONTAINMENT INTEGRATED LEAK RATE TEST FIRST RETEST -AUGUST 1979 UNIT NO. 1 SALEM NUCLEAR GENERATING STATION Prepared by P.S.E.&G.
* REACTOR CONTAINMENT INTEGRATED LEAK RATE TEST FIRST RETEST -AUGUST 1979 UNIT NO. 1 SALEM NUCLEAR GENERATING STATION Prepared by P.S.E.&G.
RESEARCH CORPORATION RESEARCH AND TESTING LABORATORY SECTION 1. 2. 3. 4.
RESEARCH CORPORATION RESEARCH AND TESTING LABORATORY SECTION 1. 2. 3. 4.
* 5. 6. 7. TABLE OF CONTENTS Introduction Integrated Leakage Rate Test Summary ILRT A Test, Procedure Instrumentation  
* 5. 6. 7. TABLE OF CONTENTS Introduction Integrated Leakage Rate Test Summary ILRT A Test, Procedure Instrumentation 4.1 Instrument Description 4.2 Primary Instrumentation 4.3 Support Instrumentation 4.4 Verification Instrumentation 4.5 Instrumentation Integrity Test 4.6 Instrument Failure 4.7 Pretest Instrument Error Analysis 4.8 Post ILRT Instrument Error Analysis Verification Test 5.1 Pump Back Method 5.2 Superimposed Leakage Rate Method Computer Program Containment Integrated Leakage Rate Test Results 7.1 7.2 7.3 7.4 7.5 7.6 7.7 7. 8-7. 9 7.10 7.11 ILRT Test Results Summary Verification Test Results Summary ILRT A Test Results ILRT A Test Regression Data ILRT A Test Average and Mass Data ILRT A Test Raw Data Stability Test Results Stability Test Data Stability Test Raw Data Pump Back Verification Test Results Pump Back Verification Test Regression Data SECTION 7. 8.
 
===4.1 Instrument===
 
Description  
 
===4.2 Primary===
Instrumentation  
 
===4.3 Support===
Instrumentation  
 
===4.4 Verification===
 
Instrumentation  
 
===4.5 Instrumentation===
 
Integrity Test 4.6 Instrument Failure 4.7 Pretest Instrument Error Analysis 4.8 Post ILRT Instrument Error Analysis Verification Test 5.1 Pump Back Method 5.2 Superimposed Leakage Rate Method Computer Program Containment Integrated Leakage Rate Test Results 7.1 7.2 7.3 7.4 7.5 7.6 7.7 7. 8-7. 9 7.10 7.11 ILRT Test Results Summary Verification Test Results Summary ILRT A Test Results ILRT A Test Regression Data ILRT A Test Average and Mass Data ILRT A Test Raw Data Stability Test Results Stability Test Data Stability Test Raw Data Pump Back Verification Test Results Pump Back Verification Test Regression Data SECTION 7. 8.
* TABLE OF CONTENTS -Cont'd. Containment Integrated Leakage Rate Test Results (Cont'd.)
* TABLE OF CONTENTS -Cont'd. Containment Integrated Leakage Rate Test Results (Cont'd.)
7.12 Pump Back Verification Test Average and Mass Data 7.13 Pump Back Verification Test -Raw Data Supporting Da_ta 8.1 Site Meteorology Prior to Test 8.2 Summary of all Type B & C Tests performed since the last Type A, ILRT .   
7.12 Pump Back Verification Test Average and Mass Data 7.13 Pump Back Verification Test -Raw Data Supporting Da_ta 8.1 Site Meteorology Prior to Test 8.2 Summary of all Type B & C Tests performed since the last Type A, ILRT .   
Line 51: Line 33:


The first Reactor Containment Integrated Leakage Rate Retest (ILRT) was conducted during the period from August 9 to August 13, 1979. The containment was pressurized to 47.9 psig temperature stablilized, and the test started at 0400 hours on August 11, 1979. The absolute method of leakage rate testing was selected for the preoperational test and all subsequent tests to be performed on the Salem containment structure.
The first Reactor Containment Integrated Leakage Rate Retest (ILRT) was conducted during the period from August 9 to August 13, 1979. The containment was pressurized to 47.9 psig temperature stablilized, and the test started at 0400 hours on August 11, 1979. The absolute method of leakage rate testing was selected for the preoperational test and all subsequent tests to be performed on the Salem containment structure.
Test data were recorded every 15 minutes and the leakage rate calculated from the slope of the linear regression line fitted to the mass plot defined by the 96 sets of data taken during the test. The ability of the instrumentation to accurately measure the containment leakage, and its sensitivity to small changes in air mass, was verified by the pump back verification method. This method is also known as the mass step change verification test. The results of the above mentioned tests and the detailed procedures by which they were performed are presented in this report.
Test data were recorded every 15 minutes and the leakage rate calculated from the slope of the linear regression line fitted to the mass plot defined by the 96 sets of data taken during the test. The ability of the instrumentation to accurately measure the containment leakage, and its sensitivity to small changes in air mass, was verified by the pump back verification method. This method is also known as the mass step change verification test. The results of the above mentioned tests and the detailed procedures by which they were performed are presented in this report.
 
2.0 INTEGRATED LEAKAGE RATE TEST  
===2.0 INTEGRATED===
 
LEAKAGE RATE TEST  


==SUMMARY==
==SUMMARY==
Line 67: Line 46:
Detailed results of the ILR'I', Pump Back Verification Test and Instrument-Integrity Test are presented in the "Test Results" Section (Section 7) of this report .   
Detailed results of the ILR'I', Pump Back Verification Test and Instrument-Integrity Test are presented in the "Test Results" Section (Section 7) of this report .   
-3.0 *
-3.0 *
* PROCEDURE  
* PROCEDURE 3.1 Following is a copy of the Reactor Containment Type A Integrated Leakage Rate Test Surveillance Procedure SP(0)4.6.l.2 used to conduct the test. Index 1.0 Purpose 2.0 Initial Conditions 3.0 Precautions 4.0 Check Off Sheets 4.1 4.2 4.3 4.4 4.5 4.6 4.7 4.8 4.9 4.10 Valve Lineup Instrument Calibration List Containment Equipment Preparations Instrument Integrity Test Pretest Instrumentation Figure Of Merit Analysis Leakage and/or Abnormality Inspection Event Log Sheet Pressurization Data Sheet Containment Data Sheet Verification Test by the Pump Back Method Test by the Superimposed Rate Method 5.0 Procedure   
 
===3.1 Following===
 
is a copy of the Reactor Containment Type A Integrated Leakage Rate Test Surveillance Procedure SP(0)4.6.l.2 used to conduct the test. Index 1.0 Purpose 2.0 Initial Conditions  
 
===3.0 Precautions===
 
===4.0 Check===
Off Sheets 4.1 4.2 4.3 4.4 4.5 4.6 4.7 4.8 4.9 4.10 Valve Lineup Instrument Calibration List Containment Equipment Preparations Instrument Integrity Test Pretest Instrumentation Figure Of Merit Analysis Leakage and/or Abnormality Inspection Event Log Sheet Pressurization Data Sheet Containment Data Sheet Verification Test by the Pump Back Method Test by the Superimposed Rate Method 5.0 Procedure   
-c / SP (0) 4. 6 .1. 2 SU?.VEILLA:iCE  
-c / SP (0) 4. 6 .1. 2 SU?.VEILLA:iCE  
?ROCEDCRE l l. 0 PUR?OSE 1.1 To the containment leakage rate with the criteria specified  
?ROCEDCRE l l. 0 PUR?OSE 1.1 To the containment leakage rate with the criteria specified  
Line 137: Line 107:
t sha 11 not be perlni tted 3. 2 3. 3 anytime the containment is pressurized.
t sha 11 not be perlni tted 3. 2 3. 3 anytime the containment is pressurized.
If an emergency situatian arises which requires irrunediate entry to the containment, then entry and exit shall be in accardance with 29CFR Part 1926, Safety and Health Regulations for Construction, Subpart 5, and Associated General Contractors of America of Accident Prevention in Construction, Chapter 30 -Compressed Air Work. The Senior Shift Supervisor/Shift Supervisor is the only individual who can authorize the pressure to be increased.
If an emergency situatian arises which requires irrunediate entry to the containment, then entry and exit shall be in accardance with 29CFR Part 1926, Safety and Health Regulations for Construction, Subpart 5, and Associated General Contractors of America of Accident Prevention in Construction, Chapter 30 -Compressed Air Work. The Senior Shift Supervisor/Shift Supervisor is the only individual who can authorize the pressure to be increased.
Except in an emergency, he is the only individual wr.o can authorize the pressure to be decreased . Access around the containment shall be restricted to personnel necessary for the proper ccnduct of the test. 3.4 All areas within 30 feet of the Unit No. 1 containment which are not shielded from the containment by a permanent wall shall be controlled access areas during this test. Access to these areas shall be limited to test personnel and persons authorized by the ILRT Test Engineer and shall be in accordance with the ILRT Test Engineer's instructions.  
Except in an emergency, he is the only individual wr.o can authorize the pressure to be decreased . Access around the containment shall be restricted to personnel necessary for the proper ccnduct of the test. 3.4 All areas within 30 feet of the Unit No. 1 containment which are not shielded from the containment by a permanent wall shall be controlled access areas during this test. Access to these areas shall be limited to test personnel and persons authorized by the ILRT Test Engineer and shall be in accordance with the ILRT Test Engineer's instructions.
 
3.5 Approved ear protection may be required in areas such as adjacent to the diesel-driven air compressors and the air charging and venting piping. 3.6 The rate of pressurization of the containment shall not exceed 5 psi per hour. 3.7 The rate of depressurization of the containment shall not exceed 15 psig per hour. 3.8 Conununications with test personnel outside the test control area shall be maintained chroughout the test. 3.9 Fan coil units shall only be run in slow speed during the conduct of the test.
===3.5 Approved===
ear protection may be required in areas such as adjacent to the diesel-driven air compressors and the air charging and venting piping. 3.6 The rate of pressurization of the containment shall not exceed 5 psi per hour. 3.7 The rate of depressurization of the containment shall not exceed 15 psig per hour. 3.8 Conununications with test personnel outside the test control area shall be maintained chroughout the test. 3.9 Fan coil units shall only be run in slow speed during the conduct of the test.
FCU motor currents to ensure that maximum limits are not exceeded.
FCU motor currents to ensure that maximum limits are not exceeded.
3.10 If the test pressure drops below 46.0 psig, repressurize the containment to psig and repeat the test. Salem Unic 1 Rev. 0   
3.10 If the test pressure drops below 46.0 psig, repressurize the containment to psig and repeat the test. Salem Unic 1 Rev. 0   
Line 681: Line 649:
_,_ ?.e' .. -. .J   
_,_ ?.e' .. -. .J   
* \. -'-*
* \. -'-*
* CHECK OFF SHEET 4.3 ATTACHMENT l CONTAINMENT EQUIPMENT PREPARATIONS LEAKAGE RATE TEST OF PENETRATION 61A and 61B SP(0)4.6.l.2  
* CHECK OFF SHEET 4.3 ATTACHMENT l CONTAINMENT EQUIPMENT PREPARATIONS LEAKAGE RATE TEST OF PENETRATION 61A and 61B SP(0)4.6.l.2 1.0 Containment penetration 61A and 61B will be leak rate tested in accordance with the following steps for Type C leakage and added to the Type A test leakage. These penetrations will be I used for the ILRT instrumentation and will not be in their normal lineup under normal operating!
 
===1.0 Containment===
 
penetration 61A and 61B will be leak rate tested in accordance with the following steps for Type C leakage and added to the Type A test leakage. These penetrations will be I used for the ILRT instrumentation and will not be in their normal lineup under normal operating!
conditions.  
conditions.  
! 1.1 1. 2 1. 3 1. 4 N. PEN. siJ 1SA270  
! 1.1 1. 2 1. 3 1. 4 N. PEN. siJ 1SA270  
Line 700: Line 664:
/_;;//ZC-:
/_;;//ZC-:
7 c*,.. ;A
7 c*,.. ;A
(..... t&deg;4&  f.,,,.<.:( c-/ U:.:i&#xa3;d I. * . " 1. 7 1. 8 2.0 Instrument Installation  
(..... t&deg;4&  f.,,,.<.:( c-/ U:.:i&#xa3;d I. * . " 1. 7 1. 8 2.0 Instrument Installation 2.1 Connect instrument to 110 volt, nominal, A.C. 60 Hz source, push power switch "on" and allow instrument to warmup for 30 minutes. 2.2 Install Local Leak Test manifold, if required . NOTE For volumetric No. 14323 -follow all steps of this procedure.
 
===2.1 Connect===
instrument to 110 volt, nominal, A.C. 60 Hz source, push power switch "on" and allow instrument to warmup for 30 minutes. 2.2 Install Local Leak Test manifold, if required . NOTE For volumetric No. 14323 -follow all steps of this procedure.
For Xodel 14325 -follow all steps those preceded by an asterisk.
For Xodel 14325 -follow all steps those preceded by an asterisk.
Salem Unit 1 Re*.;. 0 MASTER SP(0)4.6.l.2  
Salem Unit 1 Re*.;. 0 MASTER SP(0)4.6.l.2  
Line 723: Line 684:
.. to 5. 7 Release "Test Level Set" switch. 5 .. 8 Set switch to 5. 8. l Dis?lay lower values per the t<'.:bi.-r calibration.
.. to 5. 7 Release "Test Level Set" switch. 5 .. 8 Set switch to 5. 8. l Dis?lay lower values per the t<'.:bi.-r calibration.
* 5.9 Set. 11:*1ode 11 switch to "Charge 11 * *5.11 Adjust leveling feet to indicate between 0 and +4 counts en meter. 5.12 De;::ress "Test Level Set" switch. 5.13 "Reaulator" <:o establish a pressure of i;:;_ rf 5.:!.4 ?.el.ease 11 Test Level Se-:." switch. 5.15 Set 11:.1ode 11 switch to 11 Test 11* 5.15.l Display should indicate between 5.16 switch t:*::J "Cha::ge".
* 5.9 Set. 11:*1ode 11 switch to "Charge 11 * *5.11 Adjust leveling feet to indicate between 0 and +4 counts en meter. 5.12 De;::ress "Test Level Set" switch. 5.13 "Reaulator" <:o establish a pressure of i;:;_ rf 5.:!.4 ?.el.ease 11 Test Level Se-:." switch. 5.15 Set 11:.1ode 11 switch to 11 Test 11* 5.15.l Display should indicate between 5.16 switch t:*::J "Cha::ge".
::> * .Ll to establish 0 psig. 5.18 Re::-tove "Leak Test F_i;.:t"..lre" from the "':1est" port. 6.0 Tes<: Connections 6.1 instrunen-: po:-t of t11e leak detecto.:-
::> * .Ll to establish 0 psig. 5.18 Re::-tove "Leak Test F_i;.:t"..lre" from the "':1est" port. 6.0 Tes<: Connections  
 
===6.1 instrunen-===
po:-t of t11e leak detecto.:-
to ''Local Leak Test Cor..nie:cti.or:
to ''Local Leak Test Cor..nie:cti.or:
o:.--:*lan::'.cld" wi-=h "P" e.r.d a2.scc:.ated 6.2 Sale::i L'ni t * -.,-Rev. 0   
o:.--:*lan::'.cld" wi-=h "P" e.r.d a2.scc:.ated 6.2 Sale::i L'ni t * -.,-Rev. 0   
Line 731: Line 695:
s;.;itch to "Charse".
s;.;itch to "Charse".
On com;ione:-its having small test voli..:..-:ies (less tjan 2 feet 3 inches) that may be tested using nitrogen only, continue to Step 8. components that rec;c:ire the use of instrument air, continue to Step 7. Or. lar:;e volu::-.e
On com;ione:-its having small test voli..:..-:ies (less tjan 2 feet 3 inches) that may be tested using nitrogen only, continue to Step 8. components that rec;c:ire the use of instrument air, continue to Step 7. Or. lar:;e volu::-.e
: 7. 0 Lar?e Volu:ce Cor..,:ior.ents (not applicable to electrical pe!1etratio:-is) (See Page 8 of 9 for c8*!1nection) . 7.1 Conr.ect manifold to System Test Connection, if required.  
: 7. 0 Lar?e Volu:ce Cor..,:ior.ents (not applicable to electrical pe!1etratio:-is) (See Page 8 of 9 for c8*!1nection) . 7.1 Conr.ect manifold to System Test Connection, if required.
 
7.2 Close manifold test connectior.
===7.2 Close===
valve. 7.3 Open o= isclation test valve. Oper. air supply valve and pressurize to 46 psig. NOTE penetrations may be tested as a bank to reduce test lensth. Leaking penetration will be isolated and tested individually.
manifold test connectior.
7.5 Close air supply valve. Disconnect air hose if air supply is temporary.
valve. 7.3 Open o= isclation test valve. Oper. air supply valve and pressurize to 46 psig. NOTE penetrations may be tested as a bank to reduce test lensth. Leaking penetration will be isolated and tested individually.  
 
===7.5 Close===
air supply valve. Disconnect air hose if air supply is temporary.
7.6 Step 3. 8.0 Small Volume Components (See Page 9 of 9 for typical connection)
7.6 Step 3. 8.0 Small Volume Components (See Page 9 of 9 for typical connection)
: a. 2 S-2t 11 2.ar.ge" sw:tc!1 to '::i;:-.... 3.3 Set''. Salerr. Cnc.t l -::1-
: a. 2 S-2t 11 2.ar.ge" sw:tc!1 to '::i;:-.... 3.3 Set''. Salerr. Cnc.t l -::1-
* MASTER SP(0)4.6.l.2 8-4 Adjust "Regulator" to 47.0 + .5, -0 psig. 8.5 Set "!*lode" switch to "Test". 8.6 Open manifold test connection valve and monitor leakage rate until pressure returr.s to 47.0 + .5, -0 psig and gas temperature within system stabilizes as indicated by a constant flow rate on the digital readout displya. 8.7 With a low indicated leakage rate, instru."Tient may be switched to either the "Mid" or 11 Low 11 ranges. 8.8 Record leakage rate on report form. 8.9 Submit report of leak test per 7.4 of the basic procedure (Reports).  
* MASTER SP(0)4.6.l.2 8-4 Adjust "Regulator" to 47.0 + .5, -0 psig. 8.5 Set "!*lode" switch to "Test". 8.6 Open manifold test connection valve and monitor leakage rate until pressure returr.s to 47.0 + .5, -0 psig and gas temperature within system stabilizes as indicated by a constant flow rate on the digital readout displya. 8.7 With a low indicated leakage rate, instru."Tient may be switched to either the "Mid" or 11 Low 11 ranges. 8.8 Record leakage rate on report form. 8.9 Submit report of leak test per 7.4 of the basic procedure (Reports).
 
9.0 System 9.1 Close manifold tesc connection valve. 9.3 Set t8 . 9.4 Depress "Test Level Set" switch. 9. 5 2acko:: "Regula tor 11 to 0 psig. 9. 6 ?..e.:.ease "Test Level Set" s* ... ;itch. 9. 7 Se4: 5t,vitct to 11 Vent 11* 9.8 tubing from manifold test connection valve. 9.9 Crack test connection valve to depressurize or component under test. NOT.2  
===9.0 System===
 
===9.1 Close===
manifold tesc connection valve. 9.3 Set t8 . 9.4 Depress "Test Level Set" switch. 9. 5 2acko:: "Regula tor 11 to 0 psig. 9. 6 ?..e.:.ease "Test Level Set" s* ... ;itch. 9. 7 Se4: 5t,vitct to 11 Vent 11* 9.8 tubing from manifold test connection valve. 9.9 Crack test connection valve to depressurize or component under test. NOT.2  
?enetrati8ns (only) : Conduct Alna= Dew of
?enetrati8ns (only) : Conduct Alna= Dew of
: Test, is 15 psig with dry 9.10 Close er connection valve. -')-::<.e*:. 0
: Test, is 15 psig with dry 9.10 Close er connection valve. -')-::<.e*:. 0
Line 835: Line 791:
The data from both systems be compared to verify that the integrity and calibration of the tairunent leakage measuring instrumentation has been maintained.
The data from both systems be compared to verify that the integrity and calibration of the tairunent leakage measuring instrumentation has been maintained.
The pre-leak rate instrument integrity test shall consist of setting the ILRT console to record data at one minute intervals, for each sensor. The calibration check standard instrumentation shall be read at each sensor and recorded along with the time of the reading for each sensor. The reading taken with the standard instrument shall then be compared with the reading acquired on the ILRT console printout for each in-place ILRT sensor during the same time interval.
The pre-leak rate instrument integrity test shall consist of setting the ILRT console to record data at one minute intervals, for each sensor. The calibration check standard instrumentation shall be read at each sensor and recorded along with the time of the reading for each sensor. The reading taken with the standard instrument shall then be compared with the reading acquired on the ILRT console printout for each in-place ILRT sensor during the same time interval.
In addition, the integrity of the precision pressure gages shall be verified with a calibrated standard pressure gage before the start of the leakage rate test. The comparison made between the reading of each ILRT sensor and the standard shall comply with the following accuracy agreement acceptance criteria.  
In addition, the integrity of the precision pressure gages shall be verified with a calibrated standard pressure gage before the start of the leakage rate test. The comparison made between the reading of each ILRT sensor and the standard shall comply with the following accuracy agreement acceptance criteria.
 
3.0 ACCEPTANCE CRITERIA 3.1 Temperature sensors 3.1.l The difference between the temperature obtained using the ILRT instrumentation and the temperature obtained using the calibration check standard shall not exceed + l&deg;F. 3.2 Dew Point Sensors 3.2.l The difference between the dew point obtained using the ILRT instrumentation and the dew point obtained using the calibration check standard shall not exceed + 5&deg;F. 3.3 Pressure Gages 3.3.1 The di=ference between the average pressure measured with the precision pressure gages and the pressure indicated by the calibrated standard pressure gage shall not exceed+ 0.05% of reading . Salem Unit 1 Rev. 0 SP(0)4.6.l.2 PREREQUISITES  
===3.0 ACCEPTANCE===
 
CRITERIA 3.1 Temperature sensors 3.1.l The difference between the temperature obtained using the ILRT instrumentation and the temperature obtained using the calibration check standard shall not exceed + l&deg;F. 3.2 Dew Point Sensors 3.2.l The difference between the dew point obtained using the ILRT instrumentation and the dew point obtained using the calibration check standard shall not exceed + 5&deg;F. 3.3 Pressure Gages 3.3.1 The di=ference between the average pressure measured with the precision pressure gages and the pressure indicated by the calibrated standard pressure gage shall not exceed+ 0.05% of reading . Salem Unit 1 Rev. 0 SP(0)4.6.l.2 PREREQUISITES  
* "***
* "***
* 4.1 Recirculating fans are running in slow speed. 4.2 Containment temperature is relatively stable. 4.3 Equipment hatch and air lock doors are closed. 4.4 No work of a heat generating nature is taking place within the containment.  
* 4.1 Recirculating fans are running in slow speed. 4.2 Containment temperature is relatively stable. 4.3 Equipment hatch and air lock doors are closed. 4.4 No work of a heat generating nature is taking place within the containment.
 
5.0 PROCEDURE 5.1 Record data from primary ILRT sensors by setting console to scan all data points at one minute intervals until completion.
===5.0 PROCEDURE===
5.2 Record data from calibration standard instrument sensors at each in-situ location along with the time of the reading. 5.3 Correlate the readings for data obtained in 5.1 and 5.2 with respect to time and sensor location.
 
5.4 Perform instrument integrity test on the two precision pressure gages. This test shall consist of applying 45 psia and 62 psia to the precision pressure gages and the cation instruments, simultaneously, and recording the data. 5.5 Review test results for conformance to the acceptance criteria.
===5.1 Record===
data from primary ILRT sensors by setting console to scan all data points at one minute intervals until completion.  
 
===5.2 Record===
data from calibration standard instrument sensors at each in-situ location along with the time of the reading. 5.3 Correlate the readings for data obtained in 5.1 and 5.2 with respect to time and sensor location.  
 
===5.4 Perform===
instrument integrity test on the two precision pressure gages. This test shall consist of applying 45 psia and 62 psia to the precision pressure gages and the cation instruments, simultaneously, and recording the data. 5.5 Review test results for conformance to the acceptance criteria.
5.5.l If test results do not meet the acceptance criteria, an investigation shall be conducted, the cause corrected, and the test rerun. 5.5.2 If test results compare favorably with the acceptance criteria, the tests shali be considered completed . Salem Unit. 1 **2-Rev. 0 SP(0)4.6.l.2 6.0 TEST RESULTS SENSOR riEMPERATUR!
5.5.l If test results do not meet the acceptance criteria, an investigation shall be conducted, the cause corrected, and the test rerun. 5.5.2 If test results compare favorably with the acceptance criteria, the tests shali be considered completed . Salem Unit. 1 **2-Rev. 0 SP(0)4.6.l.2 6.0 TEST RESULTS SENSOR riEMPERATUR!
DEW POINT NO. e-s-1ct C> i:-Cl .,.:; 8-CF c r= TIME PRIMARY STANDARD TIME PRIMARY STANDARD I '2.\'?.0 E?1 .S<o 87. i1 I G. u-/fJ,b i 2.' 2 "Z. \ "2. cc 8.(.'1 Z \ 10. E:,
DEW POINT NO. e-s-1ct C> i:-Cl .,.:; 8-CF c r= TIME PRIMARY STANDARD TIME PRIMARY STANDARD I '2.\'?.0 E?1 .S<o 87. i1 I G. u-/fJ,b i 2.' 2 "Z. \ "2. cc 8.(.'1 Z \ 10. E:,
Line 917: Line 862:
SC.!"'.*!
SC.!"'.*!
LS superimposed expressed as lbm/Day LC containment composite leakage rate as determined by the method employed du:?:"ing the ILRT LN net containment leakage rate L:l T T T The results of thi? test shall be considered acceptable if the difference between the leakage rate (LN) established during the verification test and the leakage rate (Lam durins Integrated Leakage Rate Test) is less than 0.25 La (206.25 Lbm(air)/Day . i I ! SAT c-i ' ! , __ UN SAT Ss.2.em U:i.it l _,_ ::.e'"'.r  
LS superimposed expressed as lbm/Day LC containment composite leakage rate as determined by the method employed du:?:"ing the ILRT LN net containment leakage rate L:l T T T The results of thi? test shall be considered acceptable if the difference between the leakage rate (LN) established during the verification test and the leakage rate (Lam durins Integrated Leakage Rate Test) is less than 0.25 La (206.25 Lbm(air)/Day . i I ! SAT c-i ' ! , __ UN SAT Ss.2.em U:i.it l _,_ ::.e'"'.r  
*. J
*. J 4.0 INSTRUMENTATION 4.1 Instrument Description Containment leakage rate computations are based on the measurement of changes in absolute pressure, water vapor pressure, and drybulb temperature.
 
===4.0 INSTRUMENTATION===
 
===4.1 Instrument===
 
Description Containment leakage rate computations are based on the measurement of changes in absolute pressure, water vapor pressure, and drybulb temperature.
Since the changes in the above parameters are small, the accuracy, repeatability and resolution of the sen-sors, and in essence the complete system, require precise, reliable and accurate measurement.
Since the changes in the above parameters are small, the accuracy, repeatability and resolution of the sen-sors, and in essence the complete system, require precise, reliable and accurate measurement.
The Volumetrics ILRMS not only uses high accuracy ' sensors but also combines these inputs with high
The Volumetrics ILRMS not only uses high accuracy ' sensors but also combines these inputs with high
* accuracy, high resolution, and reliable electronic networks to provide a system that can be precisely defined from sensor input to system output. The drybulb temperature is measured by use of resistance temperature detectors (RTD) and is recorded by the data acquisition system (DAS) in degrees Fahrenheit.
* accuracy, high resolution, and reliable electronic networks to provide a system that can be precisely defined from sensor input to system output. The drybulb temperature is measured by use of resistance temperature detectors (RTD) and is recorded by the data acquisition system (DAS) in degrees Fahrenheit.
The vapor pressure is measured by use of lithium chloride (Foxboro) dewpoint sensors and is recorded by the DAS in degrees Fahrenheit.
The vapor pressure is measured by use of lithium chloride (Foxboro) dewpoint sensors and is recorded by the DAS in degrees Fahrenheit.
The absolute pressure is measured by use of a fused quartz bourdon tube. The low internal viscosity of
The absolute pressure is measured by use of a fused quartz bourdon tube. The low internal viscosity of 4.1 Continued fused quartz makes it the most perfectly elastic material known. Therefore, this type of sensor offers no measureable hysteresis, fast response, high resolution, and high accuracy.
 
===4.1 Continued===
 
fused quartz makes it the most perfectly elastic material known. Therefore, this type of sensor offers no measureable hysteresis, fast response, high resolution, and high accuracy.
The output of the pressure sensor is in parallel BCD form to the mini-computer.
The output of the pressure sensor is in parallel BCD form to the mini-computer.
The flow measur*ement, vital to the leak verification test is also an integral part of the system. The system will accommodate the superimposed leak method or the pump back method (mass change verification test) . The data acquisition portion is a microprocessor-controlled data acquisition and recording system. The system is designed around the INTEL 8080A micro-processor and it is this unit, in conjunction with ROM and RAM memory, a scanner assembly, integrating digital voltmeter and various interfaces that constitute an intelligent data acquisition system. The output of the pressure, drybulb temperature, and dewpoint can be presented to the outside world through an ASCII interface.
The flow measur*ement, vital to the leak verification test is also an integral part of the system. The system will accommodate the superimposed leak method or the pump back method (mass change verification test) . The data acquisition portion is a microprocessor-controlled data acquisition and recording system. The system is designed around the INTEL 8080A micro-processor and it is this unit, in conjunction with ROM and RAM memory, a scanner assembly, integrating digital voltmeter and various interfaces that constitute an intelligent data acquisition system. The output of the pressure, drybulb temperature, and dewpoint can be presented to the outside world through an ASCII interface.
Line 947: Line 882:
Repeatability:
Repeatability:
Stability:
Stability:
Type of Sensor: 0 to 100 PSIA +/-.02% of Reading .001% of Full Scale Less Than .001% F.S. Per Degree Fahrenheit Ambient Temperature Range Quariz Bourdon Tube
Type of Sensor: 0 to 100 PSIA +/-.02% of Reading .001% of Full Scale Less Than .001% F.S. Per Degree Fahrenheit Ambient Temperature Range Quariz Bourdon Tube 4.2 Continued 4.2.4 4.2.5 4. 2. 6 4. 2. 7 4.2.8 Ambient Pressure Operating Range: Accuracy:
 
===4.2 Continued===
 
4.2.4 4.2.5 4. 2. 6 4. 2. 7 4.2.8 Ambient Pressure Operating Range: Accuracy:
Repeatability:
Repeatability:
Stability:
Stability:
Line 980: Line 911:
-Not specified   
-Not specified   
*
*
* 4.4 Verification Instrumentation Calibration Check Standard Instruments  
* 4.4 Verification Instrumentation Calibration Check Standard Instruments 4.4.1 Pressure Gage (1) Texas Instruments, Model 145-01 with Type 12 pressure capsule Range: Resolution:
 
====4.4.1 Pressure====
Gage (1) Texas Instruments, Model 145-01 with Type 12 pressure capsule Range: Resolution:
Accuracy:
Accuracy:
Repeatability:
Repeatability:
Line 1,014: Line 942:
Perform instrument integrity test on the two precision pressure gages. The test shall consist of applying pressures of approximately 45 psia and 62 psia to the precision pressure gages and the verification instruments, simultaneously and the data recorded.
Perform instrument integrity test on the two precision pressure gages. The test shall consist of applying pressures of approximately 45 psia and 62 psia to the precision pressure gages and the verification instruments, simultaneously and the data recorded.
Review test results for conformance to the acceptance criteria.
Review test results for conformance to the acceptance criteria.
If test results do not meet the acceptance criteria, an investigation shall be conducted, the cause corrected, and the test rerun. If test results compare favorably with the acceptance criteria the tests shall be considered completed .
If test results do not meet the acceptance criteria, an investigation shall be conducted, the cause corrected, and the test rerun. If test results compare favorably with the acceptance criteria the tests shall be considered completed .
 
4.6 Instrument Failure 4.6.l 4.6.2 Introduction While it is hoped that all instrumentation functions properly during the 6onduct of the test, instrument failure is a possibility and must therefore be considered.
===4.6 Instrument===
 
Failure 4.6.l 4.6.2 Introduction While it is hoped that all instrumentation functions properly during the 6onduct of the test, instrument failure is a possibility and must therefore be considered.
In general, the number of temperature and dew point sensors that may fail before the test must be aborted is a function of the number of sensors used, the sensor locations, the volume fractions assigned to each sensor and the instrumentation error analysis.
In general, the number of temperature and dew point sensors that may fail before the test must be aborted is a function of the number of sensors used, the sensor locations, the volume fractions assigned to each sensor and the instrumentation error analysis.
While all of these factors enter into a decision to abort the test, the system error analysis is the only one that may be applied objectively.
While all of these factors enter into a decision to abort the test, the system error analysis is the only one that may be applied objectively.
Therefore, any decision to abort or continue the test shall be governed by the error analysis.
Therefore, any decision to abort or continue the test shall be governed by the error analysis.
NOTE: The error analysis (system figure of merit) is also a function of time. Good engineering judgment shall be applied if it becomes necessary to extend the test to maintain an able system figure of merit. Failure Criteria (General)
NOTE: The error analysis (system figure of merit) is also a function of time. Good engineering judgment shall be applied if it becomes necessary to extend the test to maintain an able system figure of merit. Failure Criteria (General)
Instrument failure, at its onset, can* usually be identified by data from the failing instru-ment constantly drifting apart from the average
Instrument failure, at its onset, can* usually be identified by data from the failing instru-ment constantly drifting apart from the average 4.6 Continued
 
===4.6 Continued===
: 4. 6. 2 4.6.3 Cont'd of similar instruments monitoring the same test parameter.
: 4. 6. 2 4.6.3 Cont'd of similar instruments monitoring the same test parameter.
If, during the conduct of this test, data obtained from a given sensor drifts by more than 10% of the weighted average temperature or dew point, whichever applies, that sensor shall be considered to have failed. Data from the failed sensor shall be recorded throughout the duration of the test, and the failure verified after the test is concluded.
If, during the conduct of this test, data obtained from a given sensor drifts by more than 10% of the weighted average temperature or dew point, whichever applies, that sensor shall be considered to have failed. Data from the failed sensor shall be recorded throughout the duration of the test, and the failure verified after the test is concluded.
Line 1,031: Line 954:
In the event of instrument failure during the conduct of the test, the following courses of action, and criteria to abort the test shall apply. Temperature If a temperature sensor fails during the test, the volume that sensor was monitoring shall be: transferred to one or more adjacent sensors and the weighting factors .adjusted accordingly.
In the event of instrument failure during the conduct of the test, the following courses of action, and criteria to abort the test shall apply. Temperature If a temperature sensor fails during the test, the volume that sensor was monitoring shall be: transferred to one or more adjacent sensors and the weighting factors .adjusted accordingly.
transferred to a sensor that had for all practical purposes indicated the same temperature for a minimum of four hours prior to sensor failure and the weighting factors adjusted accordingly.
transferred to a sensor that had for all practical purposes indicated the same temperature for a minimum of four hours prior to sensor failure and the weighting factors adjusted accordingly.
The decision to abort the test shall be based on:
The decision to abort the test shall be based on:
 
4.6 Continued 4.6.3 Cont'd the impact each sensor failure has on obtaining valid data. the effect each sensor failure has on the system figure of merit. Total Pressure a second precision pressure gage is provided for redundancy only, the loss of one gage shall not be considered cause to abort the test. NOTE: The change in the system figure of merit due to the loss of one precision pressure gage is in the order of magnitude of io-5 and is therfore considered negligible.
===4.6 Continued===
 
====4.6.3 Cont'd====
the impact each sensor failure has on obtaining valid data. the effect each sensor failure has on the system figure of merit. Total Pressure a second precision pressure gage is provided for redundancy only, the loss of one gage shall not be considered cause to abort the test. NOTE: The change in the system figure of merit due to the loss of one precision pressure gage is in the order of magnitude of io-5 and is therfore considered negligible.
Vapor Pressure If a dew point sensor fails during the test the volume that sensor was monitoring shall be: transferred to one or more adjacent sensors and the weighting factors adjusted accordingly.
Vapor Pressure If a dew point sensor fails during the test the volume that sensor was monitoring shall be: transferred to one or more adjacent sensors and the weighting factors adjusted accordingly.
transferred to a sensor that had indicated the same dew point temperature for a imum of four hours prior to sensor failure. The decision to abort the test shall be based on: the impact each sensor failure has on obtaining valid data. the effect each sensor failure has on the system figure of merit. NOTE: If data recorded over the preceding five hours indicates that dew point temperatures have stabilized, or that any changes that may occur are not of an order to error in the leakage rate calculations, then loss of any or all of the dew point sensors shall not be considered cause for aborting the test.
transferred to a sensor that had indicated the same dew point temperature for a imum of four hours prior to sensor failure. The decision to abort the test shall be based on: the impact each sensor failure has on obtaining valid data. the effect each sensor failure has on the system figure of merit. NOTE: If data recorded over the preceding five hours indicates that dew point temperatures have stabilized, or that any changes that may occur are not of an order to error in the leakage rate calculations, then loss of any or all of the dew point sensors shall not be considered cause for aborting the test.
4.7
4.7
* Pretest Instrumentation Error Analysis The error analysis was used primarily to select a balanced integrated leak rate measurement system and evaluate, in advance, the figure of merit for the system. Initially the analysis determines the range of expected error based on the instrumentation calibra-tion tolerances and sequencially the range of expected error based on instrumentation repeatability.
* Pretest Instrumentation Error Analysis The error analysis was used primarily to select a balanced integrated leak rate measurement system and evaluate, in advance, the figure of merit for the system. Initially the analysis determines the range of expected error based on the instrumentation calibra-tion tolerances and sequencially the range of expected error based on instrumentation repeatability.
Since containment leakage rate computations are a function of changes in temperature and pressure and not the absolute value, the repeatability error analysis is more meaningful and will therefore be used to demonstrate that error introduced by the instrumentation is within the allowable limit stated in ANS N274. The leakage rate in percent per day based on an interval of measurement of 24 hours duration is: Where: L = (100) (24) (Hf To Tn Pn] Po (1) Po = Po -Pvo = total containment atmosphere absolute pressure, in psia, at the start of the test, corrected for water vapor pressure.
Since containment leakage rate computations are a function of changes in temperature and pressure and not the absolute value, the repeatability error analysis is more meaningful and will therefore be used to demonstrate that error introduced by the instrumentation is within the allowable limit stated in ANS N274. The leakage rate in percent per day based on an interval of measurement of 24 hours duration is: Where: L = (100) (24) (Hf To Tn Pn] Po (1) Po = Po -Pvo = total containment atmosphere absolute pressure, in psia, at the start of the test, corrected for water vapor pressure.
 
4.7 Continued Pn = Pn -Pvn = total containment atmosphere absolute pressure, in psia, at data point n after start of the test, corrected for water vapor pressure.
===4.7 Continued===
 
Pn = Pn -Pvn = total containment atmosphere absolute pressure, in psia, at data point n after start of the test, corrected for water vapor pressure.
To, Tn H M containment mean atmospheric temperature in &deg;R, at the start of the test and at data point n, respectively.  
To, Tn H M containment mean atmospheric temperature in &deg;R, at the start of the test and at data point n, respectively.  
= test interval in hours between time o and n. = Mass of air in containment structure (lbs. l The change or uncertainty interval in M due to un-certainties in the measured variables is given by: EM 2400 [ (:N . 0 ) 2 + (:a . 0 ) 2 = PN Po H ( . 6 To) 2 2] 1/2 ( 2) + +(dM *0) dTN TN where o is the standard error for each variable.
= test interval in hours between time o and n. = Mass of air in containment structure (lbs. l The change or uncertainty interval in M due to un-certainties in the measured variables is given by: EM 2400 [ (:N . 0 ) 2 + (:a . 0 ) 2 = PN Po H ( . 6 To) 2 2] 1/2 ( 2) + +(dM *0) dTN TN where o is the standard error for each variable.
This formula assumes that all errors are systematic rather than random in nature. Even though the formula is deterministic, it does allow assessment of figure of merit for various equipment to be used in the-measuring system without the need for assembling and calibrating the system as an entity.
This formula assumes that all errors are systematic rather than random in nature. Even though the formula is deterministic, it does allow assessment of figure of merit for various equipment to be used in the-measuring system without the need for assembling and calibrating the system as an entity.
 
4.7 Continued The error in M after differentiating is: 2400 [ . r ( PnTo r EM = PN + Po H p 2TN 0 ( 3) ( -r ( p T T )2] 1/2 -PN + --. T + _No -:-..::::
===4.7 Continued===
 
The error in M after differentiating is: 2400 [ . r ( PnTo r EM = PN + Po H p 2TN 0 ( 3) ( -r ( p T T )2] 1/2 -PN + --. T + _No -:-..::::
Po TN PoTN2 where: -op Po = 0 -0 PN = PN T = oT = oT 0 N Since the values of To and TN are essentially the same and with P 0 -essentially and since Po PN along and PN are -the same, let To = TN, Po = PN, and Po = PN so that equation (3) becomes 2 + 2 *1/2 On the assumptio*ns of a mean absolute pressure of 62 psia, a containment mean atmosphere temperature (drybulb) of 62&deg;F, and a containment mean dew point temperature of 60&deg;F the analysis of repeatability is made. where: PT= Repeatability  
Po TN PoTN2 where: -op Po = 0 -0 PN = PN T = oT = oT 0 N Since the values of To and TN are essentially the same and with P 0 -essentially and since Po PN along and PN are -the same, let To = TN, Po = PN, and Po = PN so that equation (3) becomes 2 + 2 *1/2 On the assumptio*ns of a mean absolute pressure of 62 psia, a containment mean atmosphere temperature (drybulb) of 62&deg;F, and a containment mean dew point temperature of 60&deg;F the analysis of repeatability is made. where: PT= Repeatability  
.001% of full scale 4.7 *
.001% of full scale 4.7 *
Line 1,071: Line 984:
.001% of full scale 2 + (.0031) 2 J PT= 0.00318 Vapor Pressure (6 Dew Cells) PV Repeatability  
.001% of full scale 2 + (.0031) 2 J PT= 0.00318 Vapor Pressure (6 Dew Cells) PV Repeatability  
+/-.5&deg;F 76.0 76.5 = . 4443 psia = . 4518 psia 1/2 PV= [( 2 + (O
+/-.5&deg;F 76.0 76.5 = . 4443 psia = . 4518 psia 1/2 PV= [( 2 + (O
* 0030) 2] 1/2 PV = .00436
* 0030) 2] 1/2 PV = .00436 4.3 Continued Temperature T =Repeatability  
 
===4.3 Continued===
 
Temperature T =Repeatability  
+/-0.1&deg;F T 2 + (.0030) T = 0.020632 24 FOM= 24 (100) 2 (* 020632 ) 2 J l/2 85 + 459.7 FOM = 0.01349074%/Day Since the FOM after test is well below the allowable limit of 0.025%/Day it is considered acceptable.
+/-0.1&deg;F T 2 + (.0030) T = 0.020632 24 FOM= 24 (100) 2 (* 020632 ) 2 J l/2 85 + 459.7 FOM = 0.01349074%/Day Since the FOM after test is well below the allowable limit of 0.025%/Day it is considered acceptable.
s.o VERIFICATION TEST 5.1 Pump Back Method 5.1.1 Description This test is performed to verify the accuracy of the instrumentation employed to measure the leakage rate during the Type A test. It is accomplished by pumping between 50% and 100% La thru a gas meter and into the containment.
s.o VERIFICATION TEST 5.1 Pump Back Method 5.1.1 Description This test is performed to verify the accuracy of the instrumentation employed to measure the leakage rate during the Type A test. It is accomplished by pumping between 50% and 100% La thru a gas meter and into the containment.
Line 1,088: Line 997:
5.2
5.2
* Continued 5.2.1 5.2.2 Cont'd P = Gas meter inlet pressure -psia. T = Absolute temperature of the air passing through the gas meter. R = 459.69 + 6Q&deg;F = 519.69&deg;F = Gas constant = 53.35 ft. lbf/lbm F Ls = Superimposed leakage expressed as lbm/Day h = Total hours from the beginning of verification test. the The containment composite leakage rate (Le) shall then be determined using the method employed during the Integrated Leakage Rate Test. NOTE: The verification test tsuperimposed method) .shall be performed over an eight hour period (minimum)  
* Continued 5.2.1 5.2.2 Cont'd P = Gas meter inlet pressure -psia. T = Absolute temperature of the air passing through the gas meter. R = 459.69 + 6Q&deg;F = 519.69&deg;F = Gas constant = 53.35 ft. lbf/lbm F Ls = Superimposed leakage expressed as lbm/Day h = Total hours from the beginning of verification test. the The containment composite leakage rate (Le) shall then be determined using the method employed during the Integrated Leakage Rate Test. NOTE: The verification test tsuperimposed method) .shall be performed over an eight hour period (minimum)  
.. The net containment leakage rate (Ln) is calculated by subtracting the superimposed leakage rate from the composite leakage rate. Acceptance Criteria Results of this test shall be considered acceptable if the difference between the leakage rate (Ln) established during the *: . .::.:
.. The net containment leakage rate (Ln) is calculated by subtracting the superimposed leakage rate from the composite leakage rate. Acceptance Criteria Results of this test shall be considered acceptable if the difference between the leakage rate (Ln) established during the *: . .::.:
 
5.2 Continued 5.2.2 5.2.3 Cont'd verification test and the leakage rate (Lam) established during the Integrated Leakage Rate Test is less than 0.25 La. Instrumentation Thermal Mass Flowmeter ILRT "A" Test instrumentation   
===5.2 Continued===
 
5.2.2 5.2.3 Cont'd verification test and the leakage rate (Lam) established during the Integrated Leakage Rate Test is less than 0.25 La. Instrumentation Thermal Mass Flowmeter ILRT "A" Test instrumentation   
*
*
* COMPUTER PROGRAM 6.1 General Discussion The computer programs used for the data acquisition, compilation, and calculation of leak rate data and the analysis of this data were developed by PSE&G Research Corporation, Research and Testing Laboratory specifically for the purposes of computing containment integrated leak rate test results of both units at Salem Nuclear Generating Station. The formulas used in these test programs are taken from formulas and guidelines presented in ANSI N45.5 -1972 and ANS 274
* COMPUTER PROGRAM 6.1 General Discussion The computer programs used for the data acquisition, compilation, and calculation of leak rate data and the analysis of this data were developed by PSE&G Research Corporation, Research and Testing Laboratory specifically for the purposes of computing containment integrated leak rate test results of both units at Salem Nuclear Generating Station. The formulas used in these test programs are taken from formulas and guidelines presented in ANSI N45.5 -1972 and ANS 274
Line 1,104: Line 1,010:
= Mean total absolute pressure, psia, of the containment at the beginning and end of the test interval (H) respectively.  
= Mean total absolute pressure, psia, of the containment at the beginning and end of the test interval (H) respectively.  
= Mean total water vapor pressure, psia, of the containment atmosphere at the beginning and the end of the test interval (H) respectively.
= Mean total water vapor pressure, psia, of the containment atmosphere at the beginning and the end of the test interval (H) respectively.
The formula for mass is as follows: Where,
The formula for mass is as follows: Where, 6.2 Continued v = Mass of air in the containment structure at time N (lb) = Total free volume of the containment structure (cu. ft.) R = Gas constant 53.35 ft. lbp/lbM &deg;F = Mean absolute temperature, 0 R, of the containment structure at time N = Mean total absolute pressure psia, of the containment atmosphere at time interval N = Mean total water vapor pressure, psia, of the containment atmosphere at time interval N 6.3
 
===6.2 Continued===
 
v = Mass of air in the containment structure at time N (lb) = Total free volume of the containment structure (cu. ft.) R = Gas constant 53.35 ft. lbp/lbM &deg;F = Mean absolute temperature, 0 R, of the containment structure at time N = Mean total absolute pressure psia, of the containment atmosphere at time interval N = Mean total water vapor pressure, psia, of the containment atmosphere at time interval N 6.3
* Calculated Leak Rate Since it is assumed that the leak rate is constant during the testing period, a plot of the Measured Mass versus Time would ideally yield a straight line. Obviously, sampling techniques and test conditions are not perfect and consequently the values of measured mass deviate from the ideal straight line plot situation.
* Calculated Leak Rate Since it is assumed that the leak rate is constant during the testing period, a plot of the Measured Mass versus Time would ideally yield a straight line. Obviously, sampling techniques and test conditions are not perfect and consequently the values of measured mass deviate from the ideal straight line plot situation.
The method of Least Squares was the statistical method used for determining the "best fit" straight line, commonly called a regression line. The function of the least squares fit is to minimize the sum of the deviations between the measured and calculated mass points. After establishing the regression line, the values of Calculated Mass and Calculated Leak Rate can be determined.
The method of Least Squares was the statistical method used for determining the "best fit" straight line, commonly called a regression line. The function of the least squares fit is to minimize the sum of the deviations between the measured and calculated mass points. After establishing the regression line, the values of Calculated Mass and Calculated Leak Rate can be determined.
The regression line equation for the Least Squares "best fit" straight line is: Y = AX + B Where, Y = Calculated Mass X = Time interval of test therefore, the calculated mass at some specific time
The regression line equation for the Least Squares "best fit" straight line is: Y = AX + B Where, Y = Calculated Mass X = Time interval of test therefore, the calculated mass at some specific time 6.3 Continued (X) is expressed as: The deviation of the measured mass (W) from the calculated mass (Y) is: Deviation  
 
===6.3 Continued===
(X) is expressed as: The deviation of the measured mass (W) from the calculated mass (Y) is: Deviation  
= WN -YN As mentioned previously, the minimization of the sum of the squares between the regression line (calculated mass) and the measured mass will yield the following equation:
= WN -YN As mentioned previously, the minimization of the sum of the squares between the regression line (calculated mass) and the measured mass will yield the following equation:
where SSQ is the sum of the squares of the deviations and therefore can be written: By the use of differential calculus the values for A and B that will minimize SSQ can be determined.
where SSQ is the sum of the squares of the deviations and therefore can be written: By the use of differential calculus the values for A and B that will minimize SSQ can be determined.
Line 1,129: Line 1,028:
The procedure used to establish the 95% confidence limits was to find the variance by dividing the SSQ by N-2 which is the degrees of freedom. a2 = SSQ N-2 The standard deviation was then found by taking the 6.4
The procedure used to establish the 95% confidence limits was to find the variance by dividing the SSQ by N-2 which is the degrees of freedom. a2 = SSQ N-2 The standard deviation was then found by taking the 6.4
* Continued square root of both sides of the equation . cr = . ( SSQ) 1/2 N-2 The standard deviation has more practical significance because it returns the measure of variability to the original units of measurement and that given a normal distribution of measurements, approximately 95% of the measurements will fall within two (2) standard deviations of the mean. However, because we are dealing with a regression analysis an additional factor must be used for determining the standard deviation of the slope of the line. cr and because of the small sample size the number of standard deviations either side of the regression line to establish a 95% confidence interval are more accurately determined by using a student's "t" distribution.
* Continued square root of both sides of the equation . cr = . ( SSQ) 1/2 N-2 The standard deviation has more practical significance because it returns the measure of variability to the original units of measurement and that given a normal distribution of measurements, approximately 95% of the measurements will fall within two (2) standard deviations of the mean. However, because we are dealing with a regression analysis an additional factor must be used for determining the standard deviation of the slope of the line. cr and because of the small sample size the number of standard deviations either side of the regression line to establish a 95% confidence interval are more accurately determined by using a student's "t" distribution.
t = 1.95996 + 2.37226 + 2.8225 N-2 (N-2)2 from which the confidence limits are obtained by
t = 1.95996 + 2.37226 + 2.8225 N-2 (N-2)2 from which the confidence limits are obtained by 6.4 Continued C.L. = t*95 (J which were added to and subtraced from the various calculated mass points obtained from the regression analysis to determine the upper and lower confidence limits.
 
===6.4 Continued===
 
C.L. = t*95 (J which were added to and subtraced from the various calculated mass points obtained from the regression analysis to determine the upper and lower confidence limits.
: 7. 0 *
: 7. 0 *
* CONTAINMENT INTEGRATED LEAKAGE RATE TEST RESULTS 7.1 ILRT Test Results Summary The Integrated Leakage Rate Test (ILRT) was conducted in accordance with procedure SP(0)4.6.l.2 "Reactor Containment Type A Integrated Leakage Rate Test". A pre ILRT instrument integrity test was also performed to make certain that no significant changes in the instrumentation had occurred prior the ILRT. Results of these tests are presented in tabular and graphical form as follows: ILRT OF RESULTS INSTRUMENT INTEGRITY 1'EST  
* CONTAINMENT INTEGRATED LEAKAGE RATE TEST RESULTS 7.1 ILRT Test Results Summary The Integrated Leakage Rate Test (ILRT) was conducted in accordance with procedure SP(0)4.6.l.2 "Reactor Containment Type A Integrated Leakage Rate Test". A pre ILRT instrument integrity test was also performed to make certain that no significant changes in the instrumentation had occurred prior the ILRT. Results of these tests are presented in tabular and graphical form as follows: ILRT OF RESULTS INSTRUMENT INTEGRITY 1'EST  
Line 1,321: Line 1,216:
<Lbm) DIFF MASS (TOT TIME) (Lbm) -----------------------------------------*w--------------------------------------------------------------------
<Lbm) DIFF MASS (TOT TIME) (Lbm) -----------------------------------------*w--------------------------------------------------------------------
o.oo 8 30 224 62.190 14.661 82.800 73. 35'1 o. '106 62.096 80'1160. o.o 0.0 0.25 8 45 224 62.309 14.661 82.686 73. 216 0.404 62.082 804170. 9.9 9.9 0.50 9 0 224 62.695 14.675 82.592 73.051 0,402 62.068 804155. -15.9 -5.9 0.75 9 15 224 62.081 14.681 82. 5011 72.877 0. '100 62.057 80'1171. l.6.7 10.8 1. 00 9 30 224 61.516 14.690 82.418 73.251 0.405 62.044 804074. -96.9 -86.1 PAGE 1 TEST STARTING DAY 224 READ TIME 0.00 0.25 0.50 0.75 1.00 REAL TIME & DAY 8 30 2211 8 45 224 9 0 2211 9 15 22'+ 9 30 2211 PRESS SENS PI-1 PI-2 61. 989 62.202 61. 975 62.188 61. 961 62.1711 61. 950 62.163 61. 938 62.151 I 4, AMBIENT TEMP & PRESS 62.190 14.661 62.309 l't.661 62.695 1'1. 675 62.081 14.681 61. 516 14.690 PSE&G RESEARCH CORP. RESEARCH & TESTING LABORATORY SALEM N0.1 ILRT VERIFICATION TEST -PUMP BACK METHOD SENSOR READINGS 1 9 17 82.314 82.829 83. 10'1 82.205 82.591 83.034 82.086 82.601 82.915 81.997 82.412 82.846 81. 917 82.422 82.736 TEMPERATURE SENSORS <RTD Is) 6 14 2 10 18 82.818 82.833 82.504 82.678 82.694 82.385 82.579 82.62'+ 82.266 82.499 82.545 82.176 82.399 82.485 82.067 3 4 5 11 12 13 19 20 21 83.207 82.789 83.0'+2 82.558 82.666 82.551 81. 163 82.831 82.845 83.167 82.729 82.933 82.'+19 82.576 82.392 81.133 82.771 82.756 83.018 82.570 82.8'+'+ 82. 3110 82. 1176 82.322 80. 971, 82.563 82.687 82.918 82.500 82.725 82.271 82.377 82.262 80.716 82. 1174 82.588 82.838 82.1121 82.686 82.151 82.307 82.133 80.597 82.404 82.519 22 83.069 83.088 83. 0111 83.000 82.959 82.952 82.8111 82.909 82.822 82.792 82.830 82.753 82.703 82.730 82.673 7 15 23 83.1'+3 83.296 82.921 82.986 177 82.804 82.937 83.087 82.733 82. 8'19' 83.017 82. 63'1 82.751 82.938 82.555 8 16 24 82.763 82. 5115 78.614 82. 6611 82. 4115 78.604 82.574 82.316 78.653 82. 50'1 82.267 78.623 82.355 82.138 78. 56'+
o.oo 8 30 224 62.190 14.661 82.800 73. 35'1 o. '106 62.096 80'1160. o.o 0.0 0.25 8 45 224 62.309 14.661 82.686 73. 216 0.404 62.082 804170. 9.9 9.9 0.50 9 0 224 62.695 14.675 82.592 73.051 0,402 62.068 804155. -15.9 -5.9 0.75 9 15 224 62.081 14.681 82. 5011 72.877 0. '100 62.057 80'1171. l.6.7 10.8 1. 00 9 30 224 61.516 14.690 82.418 73.251 0.405 62.044 804074. -96.9 -86.1 PAGE 1 TEST STARTING DAY 224 READ TIME 0.00 0.25 0.50 0.75 1.00 REAL TIME & DAY 8 30 2211 8 45 224 9 0 2211 9 15 22'+ 9 30 2211 PRESS SENS PI-1 PI-2 61. 989 62.202 61. 975 62.188 61. 961 62.1711 61. 950 62.163 61. 938 62.151 I 4, AMBIENT TEMP & PRESS 62.190 14.661 62.309 l't.661 62.695 1'1. 675 62.081 14.681 61. 516 14.690 PSE&G RESEARCH CORP. RESEARCH & TESTING LABORATORY SALEM N0.1 ILRT VERIFICATION TEST -PUMP BACK METHOD SENSOR READINGS 1 9 17 82.314 82.829 83. 10'1 82.205 82.591 83.034 82.086 82.601 82.915 81.997 82.412 82.846 81. 917 82.422 82.736 TEMPERATURE SENSORS <RTD Is) 6 14 2 10 18 82.818 82.833 82.504 82.678 82.694 82.385 82.579 82.62'+ 82.266 82.499 82.545 82.176 82.399 82.485 82.067 3 4 5 11 12 13 19 20 21 83.207 82.789 83.0'+2 82.558 82.666 82.551 81. 163 82.831 82.845 83.167 82.729 82.933 82.'+19 82.576 82.392 81.133 82.771 82.756 83.018 82.570 82.8'+'+ 82. 3110 82. 1176 82.322 80. 971, 82.563 82.687 82.918 82.500 82.725 82.271 82.377 82.262 80.716 82. 1174 82.588 82.838 82.1121 82.686 82.151 82.307 82.133 80.597 82.404 82.519 22 83.069 83.088 83. 0111 83.000 82.959 82.952 82.8111 82.909 82.822 82.792 82.830 82.753 82.703 82.730 82.673 7 15 23 83.1'+3 83.296 82.921 82.986 177 82.804 82.937 83.087 82.733 82. 8'19' 83.017 82. 63'1 82.751 82.938 82.555 8 16 24 82.763 82. 5115 78.614 82. 6611 82. 4115 78.604 82.574 82.316 78.653 82. 50'1 82.267 78.623 82.355 82.138 78. 56'+
* DATE 8/12/1979 TEST STARTING TIME 8/30 DEW POINT SENSORS 1 2 3 4 5 6 73.537 75.084 0.000 73.59'+ 71. 108 71.898 73.228 75.700 0.000 72.915 72.386 72.266 ....i I-' w 711. '163 75.271 0.000 72.951 69.831 71. 99'+ 't1 q 't1 73.682 73.959 0.000 tr; 73.313 69.362 71.749 () ?>: < 73.592 75.262 0.000 to: ::<! 73.413 71.182 71. 1125 H '"".! H () >'3 H 0 z 8 1:1 UJ 8 fg ::;;: t:' :i:< 1-3 :i:<
* DATE 8/12/1979 TEST STARTING TIME 8/30 DEW POINT SENSORS 1 2 3 4 5 6 73.537 75.084 0.000 73.59'+ 71. 108 71.898 73.228 75.700 0.000 72.915 72.386 72.266 ....i I-' w 711. '163 75.271 0.000 72.951 69.831 71. 99'+ 't1 q 't1 73.682 73.959 0.000 tr; 73.313 69.362 71.749 () ?>: < 73.592 75.262 0.000 to: ::<! 73.413 71.182 71. 1125 H '"".! H () >'3 H 0 z 8 1:1 UJ 8 fg ::;;: t:' :i:< 1-3 :i:<
 
8.0 SUPPORTING DATA   
===8.0 SUPPORTING===
 
DATA   
*
*
* 8.1 Site Meterology and Containment Conditions before start of test
* 8.1 Site Meterology and Containment Conditions before start of test

Revision as of 16:31, 5 May 2019

Reactor Containment Integrated Leak Rate Test,First Retest - Aug 1979.
ML18082A122
Person / Time
Site: Salem PSEG icon.png
Issue date: 08/31/1979
From:
PSE&G RESEARCH CORP., Public Service Enterprise Group
To:
Shared Package
ML18082A121 List:
References
NUDOCS 8004080394
Download: ML18082A122 (150)


Text

{{#Wiki_filter:* DOCKET .fllE COPf ,*'* :,,_ .. . *** ... * !St)-2. '12.. Docket# 800'l8803'fO Control# l /ts Document: REGULATORY FltE . 04 0 so3'lt 8 0 -.. ' REPORT ON REACTOR CONTAINMENT INTEGRATED LEAK RATE TEST UNIT NO. 1 -FIRST RETEST -AUGUST 1979 SALEM NUCLEAR GENERATING STATION Prepared by: Edited by: Approved by: Approved by: Laborator. Reviewed by: Engineering & Construction Dept. Approved by: Chief MechariiCa1Ei19"iiieer Approved by: Approved by: Approved by: Reviewed by: I I I I I c9 *

  • REACTOR CONTAINMENT INTEGRATED LEAK RATE TEST FIRST RETEST -AUGUST 1979 UNIT NO. 1 SALEM NUCLEAR GENERATING STATION Prepared by P.S.E.&G.

RESEARCH CORPORATION RESEARCH AND TESTING LABORATORY SECTION 1. 2. 3. 4.

  • 5. 6. 7. TABLE OF CONTENTS Introduction Integrated Leakage Rate Test Summary ILRT A Test, Procedure Instrumentation 4.1 Instrument Description 4.2 Primary Instrumentation 4.3 Support Instrumentation 4.4 Verification Instrumentation 4.5 Instrumentation Integrity Test 4.6 Instrument Failure 4.7 Pretest Instrument Error Analysis 4.8 Post ILRT Instrument Error Analysis Verification Test 5.1 Pump Back Method 5.2 Superimposed Leakage Rate Method Computer Program Containment Integrated Leakage Rate Test Results 7.1 7.2 7.3 7.4 7.5 7.6 7.7 7. 8-7. 9 7.10 7.11 ILRT Test Results Summary Verification Test Results Summary ILRT A Test Results ILRT A Test Regression Data ILRT A Test Average and Mass Data ILRT A Test Raw Data Stability Test Results Stability Test Data Stability Test Raw Data Pump Back Verification Test Results Pump Back Verification Test Regression Data SECTION 7. 8.
  • TABLE OF CONTENTS -Cont'd. Containment Integrated Leakage Rate Test Results (Cont'd.)

7.12 Pump Back Verification Test Average and Mass Data 7.13 Pump Back Verification Test -Raw Data Supporting Da_ta 8.1 Site Meteorology Prior to Test 8.2 Summary of all Type B & C Tests performed since the last Type A, ILRT .

1.0 INTRODUCTION

The first Reactor Containment Integrated Leakage Rate Retest (ILRT) was conducted during the period from August 9 to August 13, 1979. The containment was pressurized to 47.9 psig temperature stablilized, and the test started at 0400 hours on August 11, 1979. The absolute method of leakage rate testing was selected for the preoperational test and all subsequent tests to be performed on the Salem containment structure. Test data were recorded every 15 minutes and the leakage rate calculated from the slope of the linear regression line fitted to the mass plot defined by the 96 sets of data taken during the test. The ability of the instrumentation to accurately measure the containment leakage, and its sensitivity to small changes in air mass, was verified by the pump back verification method. This method is also known as the mass step change verification test. The results of the above mentioned tests and the detailed procedures by which they were performed are presented in this report. 2.0 INTEGRATED LEAKAGE RATE TEST

SUMMARY

The containment Integrated Leakage Rate First Periodic Retest (ILRT) was conducted during the first refueling outage for Salem Unit No. 1. An inspection of the containment was conducted on August 9, 1979 at 2200 hours and all pretest conditions were found satisfactory. Pressurization of the containment for the ILRT commenced at 2330 hours on August 9, 1979 and continued until 0006 hours on August* 11. The containment pressure after the compressors had been secured was 47.9 psig. Data acquisition for the ILRT began at 0006 hours. The

  • containment temperature stabilization criterion had been satisfied by 0400 hours at which time the 24 hour ILRT was commenced.

The 24 hour ILRT was completed at 0400 hours on August 12, 1979 with the results well within the speci-fication requirements. At 0643 hours on August 12 the "pump back" test was started. At 0830 hours 1828 cubic feet of air had been pumped into the containment, the valves were secured, and the pump 2.0

  • Continued back verification program was initiated.

At 0930 hours, August 12, 1979 the data indicated that the results of this test were within the limits specified and the test was terminated. Detailed results of the ILR'I', Pump Back Verification Test and Instrument-Integrity Test are presented in the "Test Results" Section (Section 7) of this report . -3.0 *

  • PROCEDURE 3.1 Following is a copy of the Reactor Containment Type A Integrated Leakage Rate Test Surveillance Procedure SP(0)4.6.l.2 used to conduct the test. Index 1.0 Purpose 2.0 Initial Conditions 3.0 Precautions 4.0 Check Off Sheets 4.1 4.2 4.3 4.4 4.5 4.6 4.7 4.8 4.9 4.10 Valve Lineup Instrument Calibration List Containment Equipment Preparations Instrument Integrity Test Pretest Instrumentation Figure Of Merit Analysis Leakage and/or Abnormality Inspection Event Log Sheet Pressurization Data Sheet Containment Data Sheet Verification Test by the Pump Back Method Test by the Superimposed Rate Method 5.0 Procedure

-c / SP (0) 4. 6 .1. 2 SU?.VEILLA:iCE ?ROCEDCRE l l. 0 PUR?OSE 1.1 To the containment leakage rate with the criteria specified ,_ A?pendix J lOCFRSO using the method and provisions of ANSI N45.4-1972.

l. 2 de:;;onst.::-a te t!-i-s containment structural integrity of concrete surfaces through visual inscection that no aooarent have occurred in the appearance of the -f4i.r.,_ *r-c

... exte!:"ior sur£3..::es,i containraent .. .l:..est . ...pres.sure du-ri:lg i:.he A Leak Rate Tesc. the of plate dtlrir.g shut-for each Ty9e A Leakage Test. / cti-I 7he Engineering and the and Testing Laboratory share responsibility fer conduct this prior co proceeding. Overall test coordir.ation, data be Testins th0 accuracy Type A can be verifi.ed a will be by the c=iteria wil! be in l. 5 Sue:: -. . -- an1 as data . --. - oe in -::: -1. 5 .1 -:-,---. -. -* ---.-. -* SP(0)4.6.l.2 Criteria: Instrument failure 0e identified by data from the failing instrument constantly drifting apart from the average of similar instrunents monitoring the sarr1e test parameter. If, during the conduct of this te3t, obtained from a given sensor drift by more than 10% of the weighted average ature or dew point, whichever applies, that sensor shall be considered to have failed. Data fron the failed sensor shall be recorded throughout the durati:n of the test, and the failure verified after the.test is concluded. In the event of instru!:lent failure C.urinq the conduct of the test, tJ-:.e following courses of acticr:, an! criteria to abort test shall apply. (1) Temperature If a teraperature sensor fails during the cest, the volume that sensor was monitoring shall be transferred to one or more ajjacent sensors and the accordingly or to a sensor ttat for all practical purposes indicated the same te::\l_)erature f.or 3 minimurr. of four hours prior to sensor failure and the factcrs adjusted acccr..:: ir.g j_y. (:) Pressure ( 3) a second pressure gage provided orily, loss one gage be considered cause t8 abort Vapo!."" Pre2su::-e lf a dew point sensor fails during the test, the volume that sensor was monitoring shall be transferred to one or more adjacent sensors and the fact8rs adjusted or tc a sensor that had the same eew ?Oint temperatu=e for a prior to failure the factors adjusted unit is

5.

of the test dace. ths 3i= ta the seals secu=ity gate locked S?(0}4.5.l.3 ?.e-.r. O 3 rh I SP{0)4.6.l.2 o:lV The fuel transfer tube blind ::lange is installed, successfully leak tested and the connection capped. test All unnecessary maintenance equipment and combustible materials have been removed the containment. fror.i All electrical power circuits inside the containment not required for this test have been de-energized. 2:/JV A of twelve (12) RTD's have been installed approximately equally spaced in the (Located in the position of the initial ILR7 with the same weighted values as per tne Test Lab.) Record RTD weighted values on Check Off Sheet 4.2. of six (6) dew point se!1sors have been installed approximately equally spaced the ccntainment. (Located in the position of the ILRT with the same weighted values as per the Test Lab.). Record dew point sensors weighted values on Check of:: Sheet 4.2. iostrcmentation listed on Check 0££ Sbsat 4.2 has been calibrateC, installeC, and is \ in c;:-.era ti on for a minir:iu::i of 2 hours prier to tes-c 12 Vah*e l V Cl5 is operaO 1 e £ rom oc ts iC e the con ta inmen t in the North ?en et rs ti on . All stea:n generator secondary side manways and handhole covers ha,1e :been installeC..

  • t4 'I'he diesel-driven air corr.pressers are ready for operation and connected to dryer assembly. air dryer, cooler and oil separator are assembled and Cooling water is available to after cooler as required.

2.16 Compressed output from the dryer is piped to mechanical penetration (lVC5), con::e::;ted to the first ::1a:i.ge outboard o:: the penetr3.tion. 2.19 C have been between the ccmpressor, the Testing Check pur?e supply and exhaus-c fans are o::: before of valve lineup. The systems are lined cp i:i. accordaDce with Check Of:: Sheet 4.1. or (e.q., DO cf val'le by

r:.:.t l Re-:. J

SP(0)4.6.l.2 equip:nent preparaticn have in accordance Ofi Sheet '1. 3. A minimum of three (3) reactor containLlent fan coil units have been running for approximately 24 hours prior to the test. in slow s;:eed 2.22 Throttle the FCU roughing filter inlet control dar::pers to midposition by blocking them open. Position service water valves to water to the FCu's ccolers,at 50 ;.GO "!!'2.

    • ate? (This will require air bottles to be tied into the above

/l-/5"Siu223.

t'/.4 All casual water has been eliminated from the containment and the containment and reactor are pumped down. d2-..25 \*leather conditions (temperatu
ce, pressure) have been monitored daily for t{jjll approximately 24 hours prior co the beginning of pressurization. Contai:-::.:ent i:-iternal te:.l=>er:=.ture and dew poir:t have been :;:onitored 24 hours prior to the beginning of pressurization.

e*-.;e=y Spot checks cf the containment interior have been made to verify the sensors are indi-r'aAIVf cating repre'sentative values of the volumes around the::i. rl.i:riJThe pretest Instrument Integrity Test, Check Off Sheet 4.4, has been completed with results. plant insurance has been notified that the \J syste!'!'. has ::.ee!1 disabled and th=.t fire extinguishers have been re!'.loved fro;:; the ccntainmez:t. ' instrumentation figure of merit analysis, Check Sheet J.S, h=.s b*' 'ah"--use O'"' lM:-'==-----1 ...... .i***::--...., .......... .J.,.J,.J_._, ... .L. *...... .::._._ __ .... (.i**r . I

  • n tem;:ierature o: approxi:nately 50°F to has been
  • er {C \ Fl* "!

to th<> '"e-t ,JJ filled to at Per::cr11 a :inal i:ispection o-: the exte::-ior and interio= to 1:.::e s tr-1..1c t:*.Jre for test. Resord data Check t .... ?.*:"':. 0

  • SP(0)4.6.l.2 personnel are removed from the containment.

The tubing for the Superimposed Leak Rate Method Test has been installed under the direction of the Materials Test Engineer. block open 1VC6. 2.38 ReffiOB8 llCl'.431and12CA431 and install 011 de11nst:J::a&?R aiS:c. Att.achrnent 1 _of Check Off Sheet 4.3 has been /J

3. t . R!:.CAUT
3. l ::::-:c12pt in emergency si tua "C.i:Jns .-pe:r sonnel en t!."'y to the cont.ainrner.

t sha 11 not be perlni tted 3. 2 3. 3 anytime the containment is pressurized. If an emergency situatian arises which requires irrunediate entry to the containment, then entry and exit shall be in accardance with 29CFR Part 1926, Safety and Health Regulations for Construction, Subpart 5, and Associated General Contractors of America of Accident Prevention in Construction, Chapter 30 -Compressed Air Work. The Senior Shift Supervisor/Shift Supervisor is the only individual who can authorize the pressure to be increased. Except in an emergency, he is the only individual wr.o can authorize the pressure to be decreased . Access around the containment shall be restricted to personnel necessary for the proper ccnduct of the test. 3.4 All areas within 30 feet of the Unit No. 1 containment which are not shielded from the containment by a permanent wall shall be controlled access areas during this test. Access to these areas shall be limited to test personnel and persons authorized by the ILRT Test Engineer and shall be in accordance with the ILRT Test Engineer's instructions. 3.5 Approved ear protection may be required in areas such as adjacent to the diesel-driven air compressors and the air charging and venting piping. 3.6 The rate of pressurization of the containment shall not exceed 5 psi per hour. 3.7 The rate of depressurization of the containment shall not exceed 15 psig per hour. 3.8 Conununications with test personnel outside the test control area shall be maintained chroughout the test. 3.9 Fan coil units shall only be run in slow speed during the conduct of the test. FCU motor currents to ensure that maximum limits are not exceeded. 3.10 If the test pressure drops below 46.0 psig, repressurize the containment to psig and repeat the test. Salem Unic 1 Rev. 0 -'---M/\S1ER SP(0}4.6.l.2 3.11 Test data and the containment boundaries should be watched carefully for signs of imminent failure of any components under test. 3.12 Maintain FCU service water outlet pressure greater than 75 psig.* 4.0 CHECK OFF SHEETS 4.1 Valve Lineup 4.2 Instrumenc Calibration List 4.3 Containment Equipment Preparations

4. 4 Instrument Integrity Test 4.5 Pretest Figure of Merit Analysis 4. 6 4. 7
  • Q ... u 4.9 Leakage and/or Abnormality Inspection Event Log Sheet Pressurization Data Sheet Sheet Verification Test by the Pump Back Method 4.10 Verification Test by Superimposed Leakage Rate Salem Unit :!_ O -:_:..::

SP(0)4.6.l.2 .0 PROCEuURE \'.'. -iG.1 _$(2 __ffi< * . Sale::;i l'r:it 1 Once e*;ery 40 + 10 months, perform this procedure. Verify that all data collection, storage and reduction instrumentation has been energized a minimum of two hours. Verify that all calibration and operational checks are complete and the zero ?ressure data has been attained. all Portable Air Compressors. Announce the commencement of the containment pressurization over the PA System. open lVClS Durin; containment pressurization, periodically the accessible exterior areas of containment and Sheet 4.6. Check o== Sheet 4.7. Record pressurizaLion data per When the containment pressure reaches 47.75 + 0.25 psig, close 1VC15 ar.:3. lVC:J and secure the air compressors . Vent the pressurization air header and remove a section of piping irnnediately outboard of penetration £40 and install a blank flange on the outboard side of the penetration. Corr!.'":1ence rec'.:lrdin<; data every half-hour on the first hour or half-hour, following securing of the compressors and complete Check Off SheeL 4.8. four hours for containment atmosphere to stabilize. NOTE The containment atmosphere shall be considered stabilized when the change of the weighted average temperaLure over the last hour does not deviate b:' more than Q.5°F from the average change of the weighted average temperatures of contained air taken over the ?r2vicus hours. stabilization has a: for of testa Initiate Leakage Rate Test com9uter progran ty recorded the containment stabilized .

  • MAS.TER SP(0)4.6.l.2 NOTE If the trend indicates that measured leakage is within the allowable limits as specified in N274, then test may be continued.

If the trend indicates that measured leakage is greater than allowable leakage, an investigation of the exterior of the should be initiated to determine the source of leakage. Evaluation and repair will be determined by the Reactor Engineering Department. If leakage is discovered during the test, which could cause the test not to meet the acceptance criteria, the offending leak may be isolated and the test continued provided that: a) The penetration is locally testable and is given a local leak rate test (LLRT) both before and after repair. bl The pre-repair LLRT results are added to the CILRT results to determine the success of the initial CE . .R.T attenpt (as found leakage); and c) The post-repair results are added to the CILT results to determine the of the final CILRT attempt (as left leakage).

  • . {Ji 2 nu e oCe lea ;;age rate test for a period o' twenty-four hours
  • C hack--O-Of
  • J ( h J.

P.a. t;_;er-n-_;,:.appi-ng_, .. on Selected-*A-r-eas* -o-f-Hle--*ontain:nent. ,f,/ Or. of obtaining acceptable data, !?erforr.t the -:.,*erificat.:..on tes;: by t!'le ?u.::-.;; f 3ack Re::;c'.'e the bla;;k fla:1ge fror.t pene'tration i140 and recon:1ect compressor piping. gas in the air line. I:istall Repressurize air header. Continue measuring contai;;ed air mass with equipment used in the Integratej Leak Rate Test. Record the gas meter register. feet) on Check Off Sheet 4.9. J..VCS, conc:rollinc;

  • ,:ith l.1 1ClS c<::.rmnence pllil'.pir.g appro:.;:imately 2000 ftJ s.. :..r F..eco:-=.

qas ir:.let and eve::y :nir:.1..1-:.e 3.nd barone-tr:ic pres.sl.1.ce 5 Gtf Sheet 4.9. back flow after 1900 ft 3 and at 2000 1VC5. Sale:n :.:r.i t 1 -a-0 5?(0)4.6.1.2 --** Determine mass of air pumped into the containment by performing the calculations on Check Off Sheet 4.9.

  • Contir.ue measuring contained air mass with in the Integrated Leakage u Rate Test. cg*I ii /.f*\ 25 'J.;..pare est results to the Acceptance Criteria list,ed on Check Off Sheet 4. 9, Ste;; 4. S . ( . 25.1 If test results compare favorably with the acceptance criteria listed on Check Off Sheet 4.9, step 5.25.2 thru 5.25.9 need not be co:npleted.

5.25.2 Continue measuring contained air mass with equipment used in the Integrated Leakilge Rate Test and perform the Verification Test by the Leakage Rate 5.25.3 At the installed tubing flow regulating valve, provide for the superimposed age rate and adjust to the flow rate to approximately 7.6 SCFM. lea.}:s.;e 5.25.5 Sheet 4.10. *...J ,"":,. 25. 5 containnent composite leakage rate every half hour employed during the Integrated Leakage Rate Test and record on Check Off Sheet 4.10. Deter.nine the net contain:nent lea::age rate (L:<) by pe.::-for!r.ir.g step 4. l of C!":eck Off Sheet 4.10. Compare results to the Acce;tance Criteria Check Off Sheet 4.lC, step 4.2. of the verification test, close the va.:.ve. -'5 Dioooc.nect Che ?i;>inc fcorn the air cornore"or to lVCS. Gbt:i:.:i a cor.tai:'.r..ent air sal'.'.;:le a::d complete OI II-17.3.l, .'.'>.tt=.c'.".r:-.er.t 1, lj Gas Release. release rate will be that which on OI. :LI-17. 3. 1. Attachn1ent

  • o. J.. Q.,,_,1 S.21.l
.e :00 1 3r;d 130' El.

Air ..... . . - ""=. , * := e-;:. .; I PL:., ""1 SALEM 0 PERI'. // //'* /:J* ,. *, .*/-/ PROBLEM/WORK DESCRIPTION DATE WRITTEN ,;--?-/ 7 REQUESTED' /I l.D. TAG NO. "--""/ I -1 ___ _L_* ,._,. ___ 9 2 ,-' / I / -" : "9T. /' ( /-. / '/ -;. / ;-/ ' -... /-/ ---7', _/ / -RECEIVED BY r--..:. . /\..._ " " Sr..rETY QA REQUIRED<:::::/ I DREP. REQUIRED NO. QA NOTlFlt:"ATION/_.fEVIEW (QA) NAME b (QA) DATE/TIMli. YES 0 ND YES 0 NO lp.... , 2:,-.;_j --; .:r \

  • 8-Sss/ss PERM1ss10N REQUIRED
  • S:..-t TIMEC ?&{) DATE i::

SPARE PARTS PLANNED SPECIAL INSTRUCTIONS REVIEWED BY _L-/lJ ,J-:.,_. *;:::::.?,'

  • ....J..c .,/'-' '*NNER 1'*** AN START DATE ACT. START DATE SUPV. ASSIGNED DR'S. INITIATED AUTH./ACCT.

REPAIR CODE I CLASSIFICATION ELECTRICIAN* TECHNICIAN MACHINIST BOILER REPAIR MECHANIC TECHNICAL STATION MECHANIC* ASSISTANT TECHNICAL. UTILITY MECHANIC -HELPER CLEARED & TURNED OVER TO OPERATIONS SSS/SS DATE DESCRIPTION OF WORK PERFORMED QA SURVEILLANCE COMPLETED BY FOLLOW-UP/RETEST REQUIRED FO LLOW*UP/R ET EST COMPLETE SIGNATUr<t MANPOWER REQUIREMENTS ESTIMATED NO.MEN CLOCK HOURS TOTALS ESTIMATED MAN HOURS EST./UMP ACTUAL MAN HOURS ACTUAL DOES THIS MALFUNCTION CONSTITU_!E AN INCl.9ENT D YE;s c-;:::::z=?.p* / ,/ SPARE PARTS USED P.o./a.c. No. DATE SUPERVl!;OR MA-)JER S?('J)4.6.::..2

  • .
  • Depressurize the contairunent to 0
  • 5.31 Perform a post test visual inspection of the interior and exterior.

Record 5.30 data on Check Off Sheet 4.7 and any abnormalities on Chedk Off Sheet 4.6. This surveillance shall be acceptable if the leakage at the con=iaence level ?lus the type C is less than .75 LA and the verification test by the purn? back method are within .25 LA of t!<e Integrated Leakage Rate Test. (. S"\T D C:lSAT 5.32 Plant Restoration -&5.32.1 frj . /)!JL-5.32.2 pi( 5.32. 3 fi.L 5.33.s *I M._5.33.6 1 15.33.7 k.£_5.33.8 Restore systems valve lineup in accordance with the respective System OI's. Remove the the dew point sensors and. tteir temporary cables inside the containment. the pressurization air header to penetration No. 40 and install the flange on the North penetration roof sleeve. Remove the RTD and dew point sensor cabling from outside the contain2ent. Remove the pressure and superimposed leak tubing going to the Energy Labs' trailer. Reinstall vent ducting to penetration No. 40 (to be in accordance with blCJ;l ..l.....9* 137). \,\>,() l O\=) *-l\c;:i 104\ ( y(. <\. Ll. \Ld.') Restore containment Fan Coil Units to normal. ;.' f)f;,{__5.33.9 Restore 1VC6 to normal condition. I .. /Zl 5. 33. l.O U'r.L s.JJ. iJ Reinscall the 90° elbow o: 1DR30. t/\iSTJ1U, //l) ff.!.JfaZ 9 J...OJ.7'-j o(;.f<J! ... f;5. l!/f l-1,1£5 by t l(./1 1

    • Date __

Se:!io:-Shift by J .A. Nichols ;.1anG.:;-er 1-sfum St.:;.::.i..cr:.. C:ate ___ &_,__9_2_7.,__:/_7_7 ____ _ . -!. ?.e*.-.. J


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  • MAS1ER SPIO)

.* 2 OFF SnEET 4.1 ------.---------------------.-------,,------,-----*

  • ---*--*------

--*------------- ________ ___________ =L_,il'-+----' ... .::_ _ __:.: __ = __ ::....:.. _____ . FE-542 INST VEXT & BLWDN V x 123:'23 SG TJ1::'/EL T,!1.P x 13B?23 SG LE\1 EL T_:l_p .** -*--*--***------*--*******---

  • -

SG LEVEL x ___ 2 s ___ i SG_L_E_\'_E_L_':'_A_P ___________ ___ x __ -'""""'"'--""'---'-----*-*---**


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  • -:"': l t -
  • ll3F57 SG Fl'i INLET DRAI:1 12BF57 SG INLET DRC..IN CHECK OFF SHEET 4.1 V.-:i.LVE AND DEVIATION

! -r .... 1"""1-i--YT! -r,-..-rr-T i , .. r .L .. -...L. ... .i.A.L.. i x x _______ _ -'-" FW DlLET RAIN X """<t"'\../ l 43F 57 ll3F53 12!3:'58 l3E?58 143:58 I.T-50::. l2G33 SG FW INLET DRAIN x SG ?Iv IN!oET DR.n.Io; x SG FW DRAIN x x SG IiRJ..IN x INSTR VENT & V x I l>=>>{ _ l _:iG3 _:; __ --,--s G 3 s 'r_Q.?_-_**:_i __________

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___________ _;*:.;_*..; ____ SP{O) 4.6.::..2 OF? SHEET 4. l ,e \ *--------;--------------------.,---

    • ----*-*-

.. -...... -* ------------ __ ::_.;_L_'*_,.E_c_'JC_,_*_._ _______ __________ ..,.i_?_'J_S_I_"'_- __ :_r_:,_1I_';'_. ___ :'_--_O_R_O_F_ '.#! -_:;

.*.:*:
  • l'GBlB SG BL;*;u:-1 OUTLET DC-: TO FLR X

'\."--=-LC;b..:l . I c; __ l_l_G_B_l __ 9 _ ___ ____ -+-__ x __ ___ 'C:: ' -' __ 1_2_G_3_1_9_-+ _S_G_B_L_l*_*o_N_O_U_'T_L_E_T_D_'.'_' _T_O.:.._*_::"'_*

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__ I I ?':\::- _____ 13G!319 SG OUTLET DN TC FLR I x ! ____ )-=ss3 .. ! /2JC--'


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!:_'.*:D:J OUTLET ::J:l T'J FL?. i SG N2 V l4G319 x llGB-< 7 x l3G34 7 SG LINE N2 SUP?LY V x SG LINE N2 V x SG N2 x l2G343 x ;!'((:--' I . ------------------ x !

-----
£ ____ ---------... l3GE48 SG ----------

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*-*-

-*----------: \.4J)L.., . --*--------*--*----,-----'----------------------*------*- TEST : Q}{ B.i16l RE?. ':':::S': VC::*lT V X ! ___ _ I 1::'5900 DEAD

SOL VP.LVE x ; i;.Ad..{., ------*---*----

---*----'?":::-45S v :.,:::r: 723 :x x ___ L_::: __ :_'.)_:_: _s_,..._,r_.J _ _,?_V _______________

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__ --*--*-- ISOL 1! X _ r_K_r__i _______ .. * :.c*.'3 LE'::J:; ::.r::::: ISOL *.1 ----------ISOL 'l

  • _1_*1 . ...:.:*:--'-c.:...:i:...:.-:_=-...:.*'----
  • 2. L_-_'l_:!._l

___ ::.,_. E: !:* ** -.I.. ... -.. -\,.... - MASTER OFF Sil:.:ET 4 . 1 SP(O) 4.6.1.2 VALVE AND D:'.:\'IATIOK


NO. d*r lC'*: 3:....*.:.l -*-'-*----------r---'='---: ! ___ lC'l 3 41 ORIF:!:CE DRN V 0 1CV342 HX V

  • lCV343 BX DR::; V *

-*-------------- 1CV378 V LTD:*/N LINE x 1SS24 HX OUTLET STOP V !----**--*-----*

  • --*---------.

>-------....,.---------------------.------.,-+--+---+-------------------------**--------- I "C" llSS32 11 HOT LEG ISOL V x --,-l:'.SS32 ! 2.3 EOT LEG ISOL "I./ 1SS33 RCS ISOL V x

  • i ---------------------

I

  • lS35l ! * ..

07 . __ _____ ?_?_,_Z_:L:....:::_.r.:.:,) __ s __ __ !-'..:.:D::._R_:::_* .:.S..:O..:L::._'_l ______ -T-__

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    • ---------------ISOL V l.3.3126 ??.z r.:-:* s.:;::? TEST v ::;o,,.+ 1 f./. I __

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  • -*-------

-*--*----*--'-....:..:..;= --.J* *: ..;...:::.e I .... -. . __ .. ,., ____ , := : ,::.*-.* MASTER SP ( 0) 4. 6. l. 2 CHECK OFF SHEET 4.1 VALVE LINEUP AND DEVIATION N;\!*1E C&T FOR OR Ol!T o;c 3*;: ';ALVE t:o. I POSITION irNITIALI .. -./ 1' rz*I -I -----1WL96 RCDT TO . \. J HiL97 RCDT TO G.'\S i\.NALYZER 'i :.; : </ / _ I __ l'_,*_i_L_l __ 6 __ 3 __ -,.-_R_C_D_'?. !O ::;_:. .. .s_. .. l;\Ll64 RCDT G.:\S TEST V -

.-_____ .. _ .. ____ ..... --* -----*---.. -.. '---=---=----+--------------------+------i------l--------------------------

lVCl CO:\T PURGE SUP? ISOL V ------+-Lwn. ! c.rr x CONT PURGE SC?? ISOL V CONT PURGE ISOL V l'fJC2 x l'lC3 __ _____ ,___ ___ x __ x ------,--------------------r------+------i----------------*------- lVC900 CONT PURGE TEST V x LA.....IX.. 1VC90l CO:\T ?Ui':GE TEST V X t!T 1NT5 N TO PRT STOP. 'I x l::T25 v 0 __:=.::....:....:__+...:..:....!...-.:....:...:_ __ ..:_ __ ....:.... _ _;_ ______ ____


**---------

N2 T0 PRT HDR TEST V x .. ------'--=--------------------'-------"'---=-.....;.


*-

--*---------* TO PRT STOP V N 2 TO RC'.:>T :SOL V .RC'.:>T TO v::::::T tiDR 9 TO EDR 0 x I i C I x x ------*-------


..------.;.-,.......,n---+------------


*-------

1 TO x RCDT VE:lT :,r:-;:;:: TES':' V 0 -----------


RCDT N 2 SC?P TEST V 0 .. i:r< lfo Ii x 2 TO Accu:.1 S':'OP x HT32 K2 IO ISOL V x 0 l::T5 5 2 HDR

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. _: __ ...

.. ___ ?_t*7 __

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_____________ __ J::jj -----______ ,, ___ .. RC? :K STOP -------'-----------------,c lea*:e

  • 1 ;:.-:-i ..r 1l -::-*-.

SP(O) 4.6.1.2 CHEC?-OFF SHEZT 4.1 VALVE LINEUP AND DE'JI.ATIO::J _I I-:-,,,;:.-. -C-&

,{ g:; I x x x L l1C.A54 2 i.:.. E!::JR co:.: PE::J v2::;':' v o M _....:.___;. _____________ -'--_______ ;....___.;;__ _ _;__,__'---'--'--_..,:""'1-"'--------------*- -lC.:'.\.930 l' !clD?. cm;T 7EST v _.., ---***----------* lS.:0..118 .3.:; HD?. co:.;'!' rsc:. SV ___ 5_-i_3 __ s_: __ '?_T_0_3_L_;*_;D_c;_* _T_:ro;_* _L_'_!L_:_* '.ll_'S_.,..,_- ____ _:_ __ :_{ ___ L...:.... ___ ! c;r wjo b/ZCf __ S? I{$ x x -------* ls.:;12 o SI>. :iuR v --- 3.::\ !clDR SV 0 x is;..24 '.i H!::JR sv x -------* lS.:..271 s.; :-ODR '\.'" 0 SJs -*--* lS.'\ 9 0 5 s.; EDR T:::S7 1* ... *-------, -------------,--x _


lt:Y920 2"o' 9.:.ip HDR 1:=::-:T *, X N o l * .J J '" c,4

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.. !P :-!DR v:::::T v ------1HY923 E-rl !DR ISOL v l::y s.;c.:p :clD?. ISOL v __ ,__-JJ __ ,-.f __ ....;-e-4._.:__.l_J_x ______ ..... ----.. ----------


*-----+--...C..o

__ .. ff§ ___ __ _ ----*--------



  • -. --* ---------l.3Jl9 C:-0'.3 SJ !-:DR .:>..CCL':*!

FILL V :.: [ v,,..j[_. . -------*-------------------------------------*- ---** --------------I" _;.cc;__:-;.1 . .,.-....:....;'--_;__:...:O...:=--------------'------"""" ....... °--"":---------


*------;

  • llSJ20 12S,.J2 0 * . ' --. --, .. * -0 G" i. -AJ

___ -'-_ ... _;;; __ _ __:_c::__...::,_:_s...:c_n_T_O_:--_: _T_0_E_-___ ----, ________ ':_""""_""-- ____ -------..... l:i..3.:-50 Le;.; H:O: .. SJ T"':.::S:....:'C':.,,.....:S:...cTo..,0 7*?:::--'-'---:-:z=---'--:J_. __ .. --.. __ I >J\T'"='* '.:eri:v o7l cf .:.1sb'"-t*J (__j(___f_!_j_ Sale:n _ MASTER SP(O) 4.6.1.2 CHECK OFF SHEET 4.1

  • VALVE LINEUP AND DEVIATION I VALVE NO. NAME POSITION INITIAL/ C&T FOH OR Ol_'.T O? P1JS 3 /: I I L.\MJL I I llSJSO LOW HD'.( 3J TEST STOP v x I I I I 12SJ50 LOW HDR SJ TEST STOP v i

_! ________ --*-* --------*--- -' . **--*---------- I 1SJ53 SJ TEST STOP v * ! I ! I I llSJ57 A CC UM DISCH TEST STOP v x ----*-; 12SJ57 .!\.CCLJM DISCH TEST STOP v x I -------* ' I l -' 13SJ57 AC CUM DISCH TEST STOP v x I ;J I I -I ' I 14SJ57 i ACCl'!-l DISCH TEST STOP v x I .AN ! llSJSB A CC UM DISCH T!':ST STOP v x I ' i 12SJ58 ACCC)I DISCH TEST STOP v x i I 13SJ58 I li.CCUM DISCH TEST STOP v x ! I ' -I I DISCH TES'!' STO? v I x i.v.!>.I I ' ! I I I ' lSJ59 ; SJ HDR ACCU:*l FILL x I I 1SJ60 CV T2ST LI:-i::: STOP v

  • lSJ62 7EST LI?:-:E DISCE TO HL'7 STOP v x
  • SJ HDR ACCU:-i FILL v 1SJ122 P.CCU:-! CV TEST*

x 0 1SJ123 ;;cc:::-1 CV LI:.'-!E STOP v *


lls.:-140 I :-IOT LEG SJ TEST ".JENT 0 ' 1SJ151 ! ?ILL LI:1E TEST co:;N v * .-1SJ155 2D::'. SJ TC v

  • i x lSJl58 V

ll5Jl62 I-iOT ......,!:,..._: Ci LINE STO? x 12SJ162 *...).:,. CV TEST LHIE STOP x I l3SJ162 EO':' LEG CV TEST LINE STOP x USJ162 EQT J...,,L'-' CV ?EST LINE ST*)P __ 1SJ163 P.OT rn '!1EST LINE STOP _, lS.716".i ':':='.S:' _. .!. v x x x -=-.:..::..:::;-=-..:o.=- _ __:_:_=--:_--==:='--"'--'--=-::OO::.-=-...c==-=c-=--=-=------1-----=-='----+----;---------------

  • -----------

*** ---------


1SJ194 SJ ?t;;*lP _:J_T_SCH HRD V"'NT v x SJ v x -1SJ195 DISCH HRD VENT


**---* ------------

1SJ196 .!\.C'.:UM CV TES'l' VE,!T v 0 :5Jl9 7 I '-. 'T!::.5T v 0 :*:

  • _l

-xopen to C:.rain. draining is car..?lete, then shut. Sale:n Unit. 1 r<.e*l.

  • 0 MASTER SP(O) 4.6.1.2 CHECK OFF SHEET 4.1 -VAL\'E LINEUP DEVIA.TION )JG. I N .. :\ME 1SJ199 ! ACCUC-! CV TEST ORN v

!3Y: Ck. I x

  • 1SJ200 I CV TEST DR:-1 v
  • wH I __ _l§J201 I AC Cm! CV TEST ORN v 1SJ202 I SJ TEST LINE ORN v I * --------r I --* bE..-L 2 0 3 I SJ T2ST LINE ORN v ' L. 1SJ204 ! SJ TEST LI:iE DRAD! v * ' I 1SJ205 SJ TEST LI"'E v
  • __

___ SJ TEST LINE'VENT v

  • 1SJ207 SJ TEST !..INE VENT v
  • 1SJ208 ACCUH FILL LINE DRl'\.IN 0 I 1SJ209 ACCU:.! FILL LINE DR.:l.Di 0 ! l.>d'\.. _ ... l5-J210 TEST LINE HOR VE:lT -----------------------

LlSJ211 TEST LINE HDR VENT x lSJ212 ACCU:*I FILL LI::-<E DRAIN x !----------

  • 1SJ213 SJ HOR TEST LI:JE LOW HOR SJ TEST VENT x i 1.-v*-w I

-* ___ lSJLU AC CUM CV TEST VENT x l3..J223 ! LOW HOR SJ TEST tlEXT

  • 1SJ229_ LO\': EDR SJ T::::ST VE'..jT
  • __1_f2.J227 I LOW HDR SJ TEST
  • i _ _is_.;r;;.;o CV TEST :.rnE DRJ>.IN
  • 1SJ241 r:;v TEST D!l.AIN
  • I ____ l,SJ242 CV TEST LINE DR.:l.IN
  • ____ g;J143 TEST LINE DRA1"l
  • ___

4_ --CV TEST LI:,rE ::JR.:'\I'.'l . _,. --------------*-**----------

  • * ------------------

--__ :..;;_J_.2.J8 __ ..=s;.::J. HOT LEG IolJ 'l""':-:.:.;T-=------------:.:.x _ ___:! __ ..wM__*_ *.!. T_}; ___________

    • -* _______ ----------**

SJ HOT L:::G INJ VE:-!T ___ _ x , , C.{T

  • -*--: ' I. S'j SJ HDR VENT v ___________

__:X:._' . ...... ' ___ x ____ : _1SJ251 SJ HOR V"'NT V SJ HOR DR:.l ',' ______ ___: __ :::.< ____ --* ___ . ____ .. ____ -------* .... --* ------------ -J.>.....M...

  • __ :\.2J2S]_

SJ l.JDR C*Rcl _:_V ______________ .x *


Salem Gnit. l

  • SP(O) 4.6.1.2 CHECK OFF SHEET 4.1 VP..LVE LINEUP .1\.ND DEVIATION

*--

1 POSITION INITIAL C&T * , llSJ268 ACCUM CV TEST VENT 12SJ268 ACCUM CV TEST LINE VENT 11SJ271 ACCUN FILL LINE VENT 12SJ271 ACCUM FILL LINE VENT 13SJ271 ACCUM FILL VENT 11SJ272 FILL LINE VENT 12SJ272 FILL LINE 13SJ272 ;..ccm-1 FILL VENT lSJ273 ACCUM FILL LINE VENT lSJ274 FILL VENT lSJ 2 7 5 1 .'I.CCU'.-! FILL :WI:<E VENT 1SJ276 1SJ283 :s.;237 .;ccc:-1 CV TEST LI:.JE DR:*: 1SJ298 ;'<.CCUM CV TEST LD<E DRN lS.:-289 .u.ccc:.; C'l TEST LINE DRN :!:SC'L V '..3SS26 ACCT.JC.! s;.MP ISOL V 1 4SS26 .::.ccu:-! s;,.:.:P :soL "J 1SS27 .:i.ccc:-1 s.::.:-1? rsoL v 1SS29 SA:!!? -S70P v lS.3103 1SS122 * * * * * * * * * * * * * * * ... x x x

  • x *
  • l t:r.B I I I lY-11'-i l>.N}y
  • i : *-----------------

S.'-.'.*'.F

ODR ':'::':ST

,, 0 I . _c=-o=-::..:..:*:..:.-=-s*:..:..-;-=s-=-'-"-=-P-=-P=L-"-Y ______ ____, ___ G _,c;:-5

c . , 2CH29 1 TEST SU?:?:SY y ... ,,.........

r 13C'l2 . ..:s:....:;*...:.i ..:S:....:C:....:'?:....:F:....::.=-*-_.- _________ __ .. c:::::: __ s_ l4C\"291 ..:S:..:l:.:'?:...:P:....:L=-'::...:.______ x i :cz.-=-x ,s_s ________ _Go_5,_.:S""'----'? _ _?5-__________ ____ .. --- .. Go15"'2 7EST -.--......... - __________ .:--.* ------NOTE 1: an to blow for le 3 ve Salerr. Unit 1 -1 'J-S?(O) 4.6.1.2 CHECK OFF SHEET 4.1 , VALVE LINEUP AND DEVIATION .* _:'\!.__i} ':0. I 14CV292 TEST CONN Sl'P?LY 11CV293 TEST CONN s;v SUI' PLY ' 12C'J2 93 T!::ST CONN SW SUP?LY 13CV293 TEST CONN SUPPLY 14CV293 TEST CONN SW SUPPLY 11CV294 TEST CONN SW SUPPLY 12CV294 I TEST CONN S\\ SUPPLY 13CV294 TEST CONN SW SUPPLY x 14CV294 TEST CONN SW SUPPLY x llCV295 STO? -v*Lv S"*' lo S'JP?LY i l2CV295 STOP VLV SUP? LY 0 5 ..,lI, .. -s:\- 0 I< .. :;:::9-{ i..;c*.:2 9 s S:':JP VLV .s:*; SL:??LY l 12 RCDT PUMP DISCH ISOL _ _, ____________ __._ __ o_...ci(....,:;)X--=-""'"-..l-------*--****-- ! _____ ,, ______ . -.... ,_ ... ------* *: 1WL13 RCDT PUc1P DISCH !SOL 1WL15 RCDT TO \*:ASTE l 16 7 RC:YI' p DISCE TES7

  • x

... ----1 JJ t-\ x l>-;Ll68 .. DISCH TEST 0 :..1*:Ll 9 3 RC:JT TO eves HOLDUP x

!.CDT TO ?.\*/ST x 0 I RCDT TO l'i;;STE 'lEKT RCDT DISCH 0 l2SJ44 CONT TO RHR x I '7 ::.2SJ126 0 ' .'*

___________ SJ TEST CONN X !...-"'S cc::::T su:.1p TO RHR x :'...:.SJ126 1EJ44 :::r;:u_;,.:zr;:G '.' o ! C;< _ ___::::_ ____________ --.... _ ..... ------* ::..1SJ14 6 CIC ---*-----------lCCll 7

  • lCCll2 ?C? CC Q?Ea I7 --*-----*---

llcc:20 __

__ ; -----*----*- .. -.-------*------ .. ---c..:-c..:-c...:-;__.c_, ...=_ _____________ .:..:._ _ __:..::_ ______ ----*---*---- --,, ____ .. -----**---*--------*--


*

  • -ll-S'.ev. :J MASTER SP(O) 4.6.1.2
  • CHECK OFF SHEET 4.1 VALVE LINEUP AND DEVIATION
  • ________ __j

__ ___ _ 14CC120 I RCP cc I v x I No"'iT.s llCC127 i RCP MOTOR cc ov x I 1 RCP CC 'JV X j ' .J -. .. u u I -I I I' fr 14CC127 RCP cc ov x ! f.!c.Tu ---------* I I i 11CC130 I RCP THER.'1 B;'-.R cc ov x i 12CC130 I RCP THERM BAR cc ov x -13CC130 RCP BAR cc ov x ! I ' :l.4CC130 I RCP ?.AR cc ov x I <'.'.'. ;T I i l(;;Cl31 ! RCP THER:*l 3AP. cc C'JNT IV * )( -*-I I ' 1C:Cl34 RCP THER!-! BAR CC CONT IV x I __ __ RCP BRG c*!OTOR OPER V *

  • 0
  • 0 * * *

'.:l I *--:------'--'--'-..:.::....-=-=--=-=..::....:...:__ ______ _________________________ _ Sale:n Unit l *

  • I PRIMARY INSTRUMENTATION Data Acquisition System MASTER CHECK OFF SHEET 4.2 INSTRUMENT CALIBRATION LIST I INST. CALIBRATION , NUMBER DATE RANGE ACCURACY ----. + .005 % uF (Ci 19 ----------

FULL SCALE SP(0)4.6.l.2 REPEATABILITY


Precision Pressure Gages(2 PI-\ -' -1q 0 -100 ... -.,*o "+/- o.

0 *00 I flfo Pl -2.. c.-1-1ct 0-100 ... c;,. ,, II I (;, -I Cf c; 0 CF-I ZCJ 0 ,:-+ O*S" °F 4-Q.\ Of=" -II ,, ,, ,, . 3 ,, It ,, ,, Temperature Sensors (Min. 12) It ,, II ,, Dry Bulb RTD 5 II ,, H ,, f, ,, ,, ,, " I ,, ,, ,, II t? ,, " II ,, . q It ,, ,, II \0 ,, I " ,, I ,, 11 II II ,, /I 12. I/ " II ,, \3 " ,, /I ,, * -.;:::_ I ) "I I II II 11 I " IS" ,, ,, II II I i 16 ,, ,, ,, I II I 11 II II II I II I 8 II II II I II ! )q II ,, II ! ,, I II II ,, II II I " It I " 22 ,, II ,, " 23 ,, ,, ,, II ,, ,. /I II \ G-1-7q 'iO 'f --' oo °F :!. O* 5'-t 0 f" :to.'5°F -Dew Poi:-it Temperature 2 ,, I ,, ,, ,, *--Sensors (Min. 6) 3 II ,, ,, " 4 ,, . ,, ,. ,, 5 /1 " ,. ,, ** I 6 ,, I " ,, I ' ,, oate Performed s>L9/79 Reviewed §' ... '::> ... ""'\Y by .

  • Date Sr. Shift Supervisor/Shift Supervisor Salem Un.it 1 Rev.* 0 1 *1 J I I .J --I *1 j i -* I I *-

CHECK OFF SP(0)4.6.l.2 CALIBRATION CHECK lNST. . CALIBRATIUN REPEATABILITY ., C::'Tll, Nn:n J:ln NUMBER DATE RANGE ACCURACY Texas Li .. ,q .. 7q -too.'\-% O* Quartz Pressure Gaqe

  • Dew Point Inaicator NA Alnor Type 7000U EGG Model 660 'i31.f"/i, E> -..s .. ""l.S"°0°F'*

'!:" o . .s'I c,: :!::' 0.1 ° . DOR\C 4 \O A 6 '"\ \C\ S'-"-; C\ -3co \6oo +/- 0.1 ° c.. -cu/coN \ .\o 4 5"-"79 -1s +/- 3/y ° F N o-T Soec\.{1(-d ' NA ,, Temperature Sensors A (Min. 12) " " ,, ' -,, ,, .. , Verification Pump l:lacK t7770Cf 7 "l-3o-'7't 0 .. 300Q C. FM , 100.1 % . N0'7 . Gas Meter Roots 3M-125 {J(iC. IF" I£"() Super:unposea LeaK 3q; .S*J0-7111 o.s% . 'T'hE>rm;:il M::>ss Flowmeter Pc\Wl'T'b t: .SS"' .,q f" 8 - +<:>.'=i% A>OT ,3-S'G.l 2.. 0-/00D.siQ ..5 t:'tE"D * ' v I . - _. ----Atmospheric Instrumentatic n ------------

  • -------------Ambient Barometric .S083 .5-2.
o. Ui" '% -to.i % s . Pressnre Transducer Ambient Temperature RTD "2. £'" C:i_. , .. ,(\ t' o. s 0 ,:: ! o. 'ct: >< -----------------Support Instrumentation

Pressure Gage 0 -60 PSIG Heise \\°3il

-O _,O,,.siea

o. l 3 F.5 \ 9a.vt '"' Sooo . * . I RTD WEIGHTING FACTORS ( C/0) DEW POINT ( t:/c"' WEIGHTING o NO. FACTOR NO. FACTOR NO. I FACTOR NO. FACTOR NO. FACTOR \ '-/.0(,C .., s. I '3 1 '4S ,q /.047 I 13.

-1 ?. .S.12..l 8 S. 7 "IS ' S.1 'fS 2.o .3,1G., 2. J."'i. ioq 3 $, J '2. I .s: 7 LJ.S IS s.. 7q$' '2. I 3 '2.S. . 4 . Lf.312 10* I Co I .O 2. 1 2. 2.. 2.. '-I 01 '-I z..s. 8S7=:. s 'I. 3, 'l. " s. 7 "I.!>-,, 2.1'Z.'I-2.3 Io, 4.3CJ G. I..:, 0 31 l. I \1 ls. ") "' S" i 3. 71., z. 'I !t.02.i /0, 'itJ.JC{i

  • (/._ c ?!J.f(] --i<!_.j 1? -

v .. (j *-\ -"\g L... J ;") .,-.._ Sa.l.e .... Un.i. t 1 Rev. 0 I:-:itials/Date CHECK OFF SHEET 4.3 CONTl'.I::-IMENT SP (0) 4. 6 .1. 2 The following items shall be completed to prevent inadvertent masking of containment leakage or shall be vented in order to prevent possible damage due to overpressurization. f({ /_-(....'l+'...,:;-t*

i. I
.:::.i 1 All fire extinguishers removed from the containment.

All oxygen, nitrogen, and tanks* =emoved from Reactor vessel vented. J ytebS II'<. ';,.J <-e\; Pressurize!:" Relief Tank vented. (SS J Reactor Coolant !:lrai!1 Tank (RCDT) vented. ('SS: J RCDTf#ll and #12 vented to containment atmosphere. ( S.5-) I "Q.-L Safety Injection Accumulators vented to containment Date ? -) ;ill =12 /TJ Date Date #24 b35e and weld NOTE Test couplings on the weld channels behind the (below elevation 112') we=e p!:ior to installing the insulaticn. fan inlet. throttled and clea!1 filters insta.ll2d.

  1. 13 ;r_".f {,,,,

elevator tagged out of service . .S.C? hec.d tanks ventE":d. by opening-ll-14\*1R74 ,,¢"461= Air lock ;ages isolated from containment 13 0 1 El. %/z/a' are :oo * :::1 . .df"C: inside/outside low

LS fan blades have a hole C.rill2C.

i:i. Supe:-*v*i.sc:- _,_ ?.e' .. -. .J

  • \. -'-*
  • CHECK OFF SHEET 4.3 ATTACHMENT l CONTAINMENT EQUIPMENT PREPARATIONS LEAKAGE RATE TEST OF PENETRATION 61A and 61B SP(0)4.6.l.2 1.0 Containment penetration 61A and 61B will be leak rate tested in accordance with the following steps for Type C leakage and added to the Type A test leakage. These penetrations will be I used for the ILRT instrumentation and will not be in their normal lineup under normal operating!

conditions. ! 1.1 1. 2 1. 3 1. 4 N. PEN. siJ 1SA270


[XJ 1SA269l I CONTAINMENT Valves: 2..1.// 1SA270, Open 1SA2 7 5 1 1 )A24' f Pressurize 1SA270 and 1SA268 in accordance with procedure page 2 thru 10 of Check Off ;z ?c_' Sheet 4.3, Attachment 1 using 1SA2-&9-.

Record leakage on data sheet of Attachment

1. 1SA274 1SA265 1SA267

+ 1SA2661 N. PEN. CONTAINMENT Cjfv.,f 1.5 lSA2615, 1SA267. Open 1SA274£l.AA-ct../5T}2r>5

1. 6 1SA265-and 1SA267 in accordance with procedure oage 2 thru 12 of Check Off -Sheet 4.3, Attachment 1 using Record leakage on data sheet of Attachment
1. Sh t .* J" -**'--.u =cri(.><-:0..

a.p_.,. -' 1 . /.. . i[d A ;/ ...,,_ . C' r * ** / * ? //Vu<-J_"lf tJ{-

  • 'j-' .44'c.C-t-t'r* ./1/fc"£e.Ftf/il:*l't.-<

/ ..4..µ***<J- /_;;//ZC-: 7 c*,.. ;A (..... t°4& f.,,,.<.:( c-/ U:.:i£d I. * . " 1. 7 1. 8 2.0 Instrument Installation 2.1 Connect instrument to 110 volt, nominal, A.C. 60 Hz source, push power switch "on" and allow instrument to warmup for 30 minutes. 2.2 Install Local Leak Test manifold, if required . NOTE For volumetric No. 14323 -follow all steps of this procedure. For Xodel 14325 -follow all steps those preceded by an asterisk. Salem Unit 1 Re*.;. 0 MASTER SP(0)4.6.l.2 .3.0 Electronic Integrity Check (to be per:ormed before each test). *

  • 3.1 Set switch to "High". 3.2 Set "Mode" switch to "Charge".
  • 3.3 After the 30 minute warmup period, adjust the leveling feet to indicate between 0 and +4 counts on the digital readout display. 3.4 Depress "Calibration" switch. 3.4.l Display should indicate figures relative ta the last calibration sheec. 3.5 Release "Calibral:ion" switch. 3.6 Set 11 Range" s* .... ,..itch to *3.7 Adjust leveling feet for 0 to T4 counts. 3.2.l 3.9 Release "Calibration" switch. 3.10 Set "Range" switah to "Lo". 3.11 Adjust leveling feec co indicate between 0 and +4 counts on meter. *3 .12 Depress "Calibraci:::in" switch. 3.12.1 Display should indicate *3.13 Release "Calibratior.

11 swits:-i. Nitrogen 4.1 cor.r.ec': 0 r:-il.et:" port a.t :-ear of instru:nent to regulator c:i \-w*it:: of 150 psi;, 250 4.2 Back off. 4.3 valve to regulator. 4.4 to establish a ;ressure of 200 psig . Salen Unit ::. i '°'" I I i !

s p ( 0 ) 4 . 6 . 1 .

2. 95.0 Flow Integrity Check (to be performed at the beginning of each day when testing).

'* 5.1 Connect "Leak Test Fixture" to the "Test" port at rear of instrument. 5.2 Set the "Range" switch to "High". 5.3 Set the "Mode" switch to "Charge".

  • 5.4 Adjust leveling feet to indicate between 0 and +4 counts on meter. 5.5 Depress "Test Level Set" switch . 5.6 . ;C.j!lst inst!."'U.'":lent

."R.egulator 11 .,L,a;ti ,__,t c'.c<..<-:t .. to 5. 7 Release "Test Level Set" switch. 5 .. 8 Set switch to 5. 8. l Dis?lay lower values per the t<'.:bi.-r calibration.

  • 5.9 Set. 11:*1ode 11 switch to "Charge 11 * *5.11 Adjust leveling feet to indicate between 0 and +4 counts en meter. 5.12 De;::ress "Test Level Set" switch. 5.13 "Reaulator" <:o establish a pressure of i;:;_ rf 5.:!.4 ?.el.ease 11 Test Level Se-:." switch. 5.15 Set 11:.1ode 11 switch to 11 Test 11* 5.15.l Display should indicate between 5.16 switch t:*::J "Cha::ge".
> * .Ll to establish 0 psig. 5.18 Re::-tove "Leak Test F_i;.:t"..lre" from the "':1est" port. 6.0 Tes<: Connections

6.1 instrunen-

po:-t of t11e leak detecto.:- to Local Leak Test Cor..nie:cti.or: o:.--:*lan::'.cld" wi-=h "P" e.r.d a2.scc:.ated 6.2 Sale::i L'ni t * -.,-Rev. 0

  • MAS1E'R SP(0)4.6.l.2 Close instrument air valve. 6.4 Open manifold test connection valve. 6.5 Set "Mode" switch to "Charge".

6.6 Set "Range" switch to "High". *6.7 Adjust leveling feet for 0 to +4 counts. 6.8 Depress "Test Level Set" switch. 6.9 Adjust "Regulator" to 47.0 + 0.5, -0 psig. *6.10 Set switch to "Test, display should indicate between 0 to +4 counts. 6.11 Se.': s;.;itch to "Charse". On com;ione:-its having small test voli..:..-:ies (less tjan 2 feet 3 inches) that may be tested using nitrogen only, continue to Step 8. components that rec;c:ire the use of instrument air, continue to Step 7. Or. lar:;e volu::-.e

7. 0 Lar?e Volu:ce Cor..,:ior.ents (not applicable to electrical pe!1etratio:-is) (See Page 8 of 9 for c8*!1nection) . 7.1 Conr.ect manifold to System Test Connection, if required.

7.2 Close manifold test connectior. valve. 7.3 Open o= isclation test valve. Oper. air supply valve and pressurize to 46 psig. NOTE penetrations may be tested as a bank to reduce test lensth. Leaking penetration will be isolated and tested individually. 7.5 Close air supply valve. Disconnect air hose if air supply is temporary. 7.6 Step 3. 8.0 Small Volume Components (See Page 9 of 9 for typical connection)

a. 2 S-2t 11 2.ar.ge" sw:tc!1 to '::i;:-.... 3.3 Set. Salerr. Cnc.t l -::1-
  • MASTER SP(0)4.6.l.2 8-4 Adjust "Regulator" to 47.0 + .5, -0 psig. 8.5 Set "!*lode" switch to "Test". 8.6 Open manifold test connection valve and monitor leakage rate until pressure returr.s to 47.0 + .5, -0 psig and gas temperature within system stabilizes as indicated by a constant flow rate on the digital readout displya. 8.7 With a low indicated leakage rate, instru."Tient may be switched to either the "Mid" or 11 Low 11 ranges. 8.8 Record leakage rate on report form. 8.9 Submit report of leak test per 7.4 of the basic procedure (Reports).

9.0 System 9.1 Close manifold tesc connection valve. 9.3 Set t8 . 9.4 Depress "Test Level Set" switch. 9. 5 2acko:: "Regula tor 11 to 0 psig. 9. 6 ?..e.:.ease "Test Level Set" s* ... ;itch. 9. 7 Se4: 5t,vitct to 11 Vent 11* 9.8 tubing from manifold test connection valve. 9.9 Crack test connection valve to depressurize or component under test. NOT.2 ?enetrati8ns (only) : Conduct Alna= Dew of

Test, is 15 psig with dry 9.10 Close er connection valve. -')-::<.e*:. 0
  • Nitrogen Permanent Air SP(0)4.6.l.2 , System Piping Gauge Gaug Connection

't.Leak Detector rfo. Val. f Test Manifold Piping Systems --t:::-) Gauge Temporary Air Supply Hose Conn. -----& Iso. Iso. Valve Individual Penet=ation Iso. Valves Supply Iso. Pressure Nitrogen Salem Unit l Iso. Nitrogen Gauge Leak5. Detector TYPICAL 'LLeak Detector ve:-' Air Lock Structure .*/'./,1 //, f" Nipple Test Air Supply 2ose u if= ld Conn. & Iso. Valve -O

  • Air Locks LARGE TESTING HOOKUP Rev. 0 Isa.
  • Salem Unit l

-MASTER Piping or Cornpon? SP(0)4.6.l.2 Test Connection Isa. Valve Leak Detector Pressure Regulator Nitrogen Supply TYPICAL SMALL VOLUME TESTING HOOKUP Rev. 0 '" :.* '. I" :: '. :1 I' *' I* "' I * Iii ,_., ..* l/1 I " ,. " I\ 1 .. " , .. l'I II " "' :J" I* "' 1: "' *I> I\ *: I" l*J \) 'I "' '" I' i!1 th 1'1, ,, ... u ,,, ,, Iii '" l d* I 1, "' " "

  • 1 "' 11. 11* ... I d II* I ;1 " I UI I i I I I I I I I I I ! I i I I I I I I I :1, fl t-1 1-* " () l. 'I Ill 0 " 11 " CD 'I f\/ n 1: rt ;] ,. ro ro CD 0 f\/ ;J rt rD f\/ ,,, rD rD Ill f\/ J1' Ill I'" ID ;l 'll ID lj t*h () ro J), 0 0 1g 1g .1'.".. *u* r., \)"" I l ( l Ill ri n i ri -:*: ... ! l () Ir . . :-: Ao'* r*,91 I l II :1 *(1 e,1 :1 l\l 'I ;,. 1*1 ID JU ... I" t) ru :v Ju Cl tU IJ '" II Cu () If, 1-* \U U1 tt i*I ::i Ill ti* 11 r: :I Ill :1 ct H :i rt rD ll t** ct u ru ,, *U 0 '" I.., f\/ Ul rt* n IU .... I" tr 11 Jll rt t*** 0 :::> l'I ;1 ,, "I **: t '" IJ' 0 I\ JU " 0 *1 **: Ill J.1 11. Ill '"

0 i: :.J "' JU () ct '1 tU 11 UI (/) rti *1 t** Jll I**' ., a* " '-. .. o' , .. r: :I Ill r1* *1 , .. 0 Ill t-< n; f\/ ;..* :u nr ct m t:,: :J .... r1 () t\ () "' JD './, 0 ).) It ;t Irr ti II r: :I Ill :1 ti Ill H t*'* ct , ... rJ .... Ill Ill ::> p. 0 Ju rt ID (.) f " \I .... 1 I 1.* 1d Ill U1 i I Cl 'I 1 i1 0 :*1 lJJ ,,, O* :J rt "' '() t'\ 1 t w JU * '" *fl tu pr rt Ill *] (!J Ill tt *u lj ll (I tu p, r: 11 Ill 1\1 'll IU I\ tU J), th 0 *1 rt tD Ill rt 1** :J Ill () () ll 11 fl, Ju :.i 0 Ill t"* rt Ill ri* Ill 'U F 0 th ti :l' rD 'll *1 I'* cl f\/ .., :tJ Ill JU () rt 0 ti n 0 :::> rt JU I"* *1 CD rt* I I I I 11 II 'I ;, JU , ... 'J J ID :J t1 ,,. lll ll , , IU n I** 0 ;.1 () () :1 'I) 0 tU ;1 rt It IU 111 " Ill fl, 1:11 lt -...J 0 l Ill :u 1\1 'II 0 II ti z 0 t' 'i-1\ °\) _.,. ... o-] *u l>J (/) Ol '" Ill . ., [-< 1'l Cl () l°"' r>l Cl l'l l'l .,, *-1 H G1 1-) ['] t-'J M (/) 1-) (/) H 0 z - ._.;::::;..

r::::)l (/J rr1 :;o Ill 'U 0 .... O> t.J NlASTER SAL"Lc*I STATION TYPES B & C LEAK.-\GE RATE TESTS SP(2)4Ji . .:..2 Con ta i"--ne n t i s::i 1 a t:io '.'. c O!'.":?O r: er: t tested: ___

__ prepared test in accordance with step /. ..3 of tt:e Reac'tor Cc.ntair_""!'.ent. Initials and Da.-te /(. Cc..../<.//o /.._.k' I ta tio:i: Leak Rate No. Serial of Last Calibration 03.z.e o: Las!: I:1-:.egrity !.eakace Rate: Reading ooJ SCCC.l Correct:..0:1 0 6 ;i_ SCC:*I A*.:u ":.al Leak3g e 0 SCC! Leakage C>

s: ------------

    • ----------------------------------------

*


.. --*-----*-::. -=-. . '-*

  • N1ASTER SP(OJ4.li.L2

?e;::ort No. z;:-5 /-#COB : i!"'_-::.e:::: iso :a tio:: co:::;::o ne:: t ::es t:ec: ____ ____ _ "PrL.*ttary Reactor "/c-.i ti--::: tr i.cs Lea;: ?..ate i

  • .8C.e1..
\o. Last Allcwabl2 Leaka;e I ...

...... .. ._ ..... :: .... --..; -----'e>=- ____ scc:-! ?e::::fome(! b:,* 12. I. *--------**-** -*****----*



*---

-:J--------*-------* ----

  • MASTER SALE!-! GENE&"\TING STATION TYPES B & C LEAKAGE RATE TESTS SP(0)4.6.l.2 Report No. ks+ 41 C. I B Containment isolation component tested: __

__ ___ Component prepared fot test in accordance with step Types B & C Rate Test Procedure". /. 7 of the "Primary Reactor Contairc*nent Initials and Date £ G /e....//o / I Ir.strlL*:1en ta tio!1: -Compone:-:t Leak Rate Monitor, No. ac turer' s Ser .i.a l / ','-/ Lcborator::* ?.::.::J.ge

>:o. NjA Date of Last Calibration D3::2 Qf Last Instrur:ie!1t I:1tegrity c::eck <SOW7 Rate: Correctio!:
\.*
utal Leak..3.ge rillowable Leakage C>O..;). SCCYl C> 6 ;2. SCCYl --------_____ C> ____ S C C:.1 -----"O ___ SCCYl Performed by tf. G./lfo /L<..-1{'

./ *-------*--* --*----*-*-----


---**----*-*-----**---------- ---.Saler;: en:..': Re'.'. G

  • MASTER GENERATING STATION TYPES B & C LEAKAGE RATE TESTS SP(0)4.6.l.2 Report clo.

__ __ _ ---'-'--- ._v ,__ c con ta inmen t isolation component tested: vc.. ve.. '--._, ---*-**-----*----------------------------- Component prepared for test in accordance with step 0 of the "Primary Reacto::: C:ontain.'T.ent" Types B & C Leakage Rate Test ProceG.u:::e". M If-/£ /?c.v.13 Initials a:id Date J:;::e..11-t'->I/ /c.....I( I I:!strumentation Volu:;iet:::ics Leak Ra t:e C-lcni tor, No. ! 't j .;t A Manu=acturer's Serial No. Energy Laboratory Badge No. 1V/J9 Date of Last Calibration Date Last Instrument Integrity Check rj71z'i I . Instrument Rea.ding + 0 ;I.(!) SCCM Correction a o J, SCCC-1 Actual Leakage 4-olOl,, SCC:-! Per=ormed by /t.a..f: I ... ***-........ ------*---------------------------

c::tair:

.. ":ler..t ?e:let.:-3.tior! Ty?e C Lea:.:age Rates to be added to Tj**r:-= A ?enet:-at:.on No. Categor*J Leakage to be Withheld 40 VIIC Sac tt r..:..-. Da i:e 'I /7 Ut:J

      • --*-----*----

Da C!J Date J *-\ :\. -"\9 L:'nit -_v-:. '2'1. 0

  • 1.0 PURPOSE CHECK OFF SHEET 4.4 INSTRUMENT INTEGRITY TEST SP(0)4.6.l.2 To verify that no significant change in instrument integrity has occurred prior to the conduct of the test.

2.0 DESCRIPTION

Within 6 months preceding the leakage rate test, after all the ILRT instrumentation has been installed in the contairunent; the contairunent pressure, temperature and dew point ILRT mentation shall be checked in-situ with NBS traceable standard instrumentation. The data from both systems be compared to verify that the integrity and calibration of the tairunent leakage measuring instrumentation has been maintained. The pre-leak rate instrument integrity test shall consist of setting the ILRT console to record data at one minute intervals, for each sensor. The calibration check standard instrumentation shall be read at each sensor and recorded along with the time of the reading for each sensor. The reading taken with the standard instrument shall then be compared with the reading acquired on the ILRT console printout for each in-place ILRT sensor during the same time interval. In addition, the integrity of the precision pressure gages shall be verified with a calibrated standard pressure gage before the start of the leakage rate test. The comparison made between the reading of each ILRT sensor and the standard shall comply with the following accuracy agreement acceptance criteria. 3.0 ACCEPTANCE CRITERIA 3.1 Temperature sensors 3.1.l The difference between the temperature obtained using the ILRT instrumentation and the temperature obtained using the calibration check standard shall not exceed + l°F. 3.2 Dew Point Sensors 3.2.l The difference between the dew point obtained using the ILRT instrumentation and the dew point obtained using the calibration check standard shall not exceed + 5°F. 3.3 Pressure Gages 3.3.1 The di=ference between the average pressure measured with the precision pressure gages and the pressure indicated by the calibrated standard pressure gage shall not exceed+ 0.05% of reading . Salem Unit 1 Rev. 0 SP(0)4.6.l.2 PREREQUISITES

  • "***
  • 4.1 Recirculating fans are running in slow speed. 4.2 Containment temperature is relatively stable. 4.3 Equipment hatch and air lock doors are closed. 4.4 No work of a heat generating nature is taking place within the containment.

5.0 PROCEDURE 5.1 Record data from primary ILRT sensors by setting console to scan all data points at one minute intervals until completion. 5.2 Record data from calibration standard instrument sensors at each in-situ location along with the time of the reading. 5.3 Correlate the readings for data obtained in 5.1 and 5.2 with respect to time and sensor location. 5.4 Perform instrument integrity test on the two precision pressure gages. This test shall consist of applying 45 psia and 62 psia to the precision pressure gages and the cation instruments, simultaneously, and recording the data. 5.5 Review test results for conformance to the acceptance criteria. 5.5.l If test results do not meet the acceptance criteria, an investigation shall be conducted, the cause corrected, and the test rerun. 5.5.2 If test results compare favorably with the acceptance criteria, the tests shali be considered completed . Salem Unit. 1 **2-Rev. 0 SP(0)4.6.l.2 6.0 TEST RESULTS SENSOR riEMPERATUR! DEW POINT NO. e-s-1ct C> i:-Cl .,.:; 8-CF c r= TIME PRIMARY STANDARD TIME PRIMARY STANDARD I '2.\'?.0 E?1 .S<o 87. i1 I G. u-/fJ,b i 2.' 2 "Z. \ "2. cc 8.(.'1 Z \ 10. E:, 3 2oS<o a'e.ctz.. 488.l.9* ,, Z.i 10.1 , \. 9 LJ "2. ' ' ra 8r3.4'4 g, I c. 33 72.'-l 1 \, R s "2...1 '2.. '2.. 88. C..P-I '=-3ct *.. 'i, . ., (::i '2.o...s-a:i 16 '4S c. 1'Z.C> 7 " <<2, 3 52.. 2..0.SO e.C:>S r:;> 8 .Z.9 9 6 '8 . ..S '!, SS.'-41 10 '2.1 '2._ b 88.3\.\

  • 11 . SB.f,5" . \ l SS>.38 98.bS 13 "2._\(_"' 8.3'-l I y <.oS2..

IS 8 0."-0 see.\' IC. . <.' oo ca . I "'\ --'2...\08 88."73 2. \f "l 89.I;> .. 'K I ct e,,4q 'C) 2.. I '-' ci. '2__l. 2. \ \ 0 cai.1cc CC?*'-.3) l.3 Bs.11 <.'-I '2.\\., , '2..5 2. It. 13 PRESSURE GAGE 1 GAGE. 2 AVG STD.GAGE

  • 45 PSIA 4S . .S-11 4S . .S18 YS..51 4S".S9E
  • 6 2 PS IA c;, I, <11 CO Gl.t:JB<o

(;J.ctcaz.. 'z. 003 S a . .le,m. Uni. t. l Rev. 0 MASTER--SP(0)4.6.l.2 CHECK OFF SHEET 4.5 -PRETEST I'.'lSTRUl-'.ENTATIO:-J FIGURE OF MERIT ANALYSIS \. *

  • Containment leakage rate determination by the absolute method depends on accurately measuring small changes in temperature and pressure with suitable corrections for vapor pressure.

One method employed to determine the ability of the instrumentation used to satisfactorily these test parameters is to calculate the figure of merit for the system. The following formulas are to be used to compute the figure of merit (FOM) for the instru-mentation package to be used for this test. The FOM is not based on a statistical analysis of the leakage rate calculations, but is the error analysis method recommended in determine the acce.ptability of the instrumentation for use in this test. errors are combined using a root-mean-square formula. The FOM is not ta be added tc the value of the calculated leakage rate, but is intended to be used for instrument selection only. FOM e 24(100) '.1 [2 ,,-[ i:-2 No. of Sensors 1/2 FOM System figure of merit (%) h duration (hours) Error associated wi t!"l me2suren:en-: Error associated measuremen-:. Error associated with measurement of of Of P Containment atmosphere total pressure change in pressure change in vapor pressure change in a.bsolu-:.e temperature T Co:-itainme:it atmosphere weighted a*1erage absolute drybulb ter:tpe:::-ature E associated with sensor (sensitivity) r Error associated with parameter readout (including etc.) excluding se:1s2r. c associated with measurement of change in a given parameter. The calculated as described above shall be less than per hour test . Sale::i Unit l _,_ ?.ev. -J 'MASIER SP(0)4.6.!.2 CHECK OFF SHEET 4.6 LEAKAGE AND/OR ABNORI1ALITY INSPECTION EVENT LOG SHEET (:<umber Sheets Co.:"!sec:.:t:i.-.;el'.') OF LEAKS OR ABNORMALITIES CaV\+'M s.x.-'\eYtD" Sv' { v e :j 00111 tf"-r TEte1o;c s.,u'°'vc.:y PRESSURE <'1-.. ./ 7' 7. (p 1js15 0 900 INITIALS hC.l \ \'\ J l}J1 YIJ.. St Yf'fJ . I '-13?.. TC**-f £0 q S-'F f3a f' Ii* 71 o ; 7,,.. J .... -, 7 1-eu,:J 7;;i.g / i.'f '3:1r /Lf.. 76 o -} -"' I D I .. / c.* / .. P,* 1 ,1, ... , I/, / .i,; I,'!.,"' 7 z . 1'6 !-,Jri/? ;.:{ .7c( /f.CU Iv /fo.'f.f!, '-f.,. b;,."""'"'-.t,._'-"<\

  • V:l"'-<.."-.

\J-<..'1--l'-"'"\.c-;) . /kl tif. 13 38 /l./l,L,-, i I DATE I js/11/F; I I I /o/i1-lh ' 1.)(,.; 0 ! f;/l/79 i I i i :eaks, check all air Sale!:\ Cni:. l REMARKS/RESOLUTION l STEP 5.7 s.:. 3 ** :;

  • 2 c
  • CHECK OFF SHEET 4.7 PRESSURIZATION DATA SHEET DESCRIPTION RCS Water Level/Cont Sump Level Containment Pressure (PSIG) 5 10 15 20 25 30 35 40 Final 't] *CJ 0 Pressure (?SIG) Ini

'j;J 1 D 45 40 35 30 20 15 10 0 ::>('s '*'aT-or T I ;'1 . * ,,. I '/. I

    • *-L.O/;;j;):...j'y*.v*1...-

/ ' -/JD (z%}; 0 Time 0/10 D{I \ .., ') 1, ..<. L -oco6 .flj 3 ') SaJ..e::i

J:ii t l -l-SP(0)4.6.l.2 INITiil.L/Di'.TE

! I l ; i I ' TIME* N-J/PM 12:30-1:00 1:30 2:00 2:30 3: 00 3:30 4:00 4:30 -_, o:OO 6:30 1:00 7:30 8:00 8::; 'J 9:00 9: 30 10:00 10:30 11: 00 ll:30 12: 0'.J I I I ! I

  • Sale:'1 Cnit l i I I I I ! 1V1ASJEJ1 CHECK OFF SHEET 4.8 CONT.ll.IN'.\'!ENT DATA SC!EET CONTAINMENT DATA (OF) 3 i i i I I I I SP(0)4.6.l.2 oa 1 -!---"(Pt'---"--

__ _ I ' I I i I I i I I I A, \I'; -* , -...:. . ._* MASTER S?(0)4!6.l .. 2 O?F 4.9 !. 0 . Veri!y t.he o: the instrument::.t::c:-1 e::-.;:loyec in the 7::-:;:e ;... test to C.eter.nine the overall integrateC. leakage rate by per!orming the :allowing: 1.1 1. 2. 3. 4. 5. 6. i. 9

  • S'. j 10 .. I I 11. I 12. i I 13. : l*L ; 15. ! I
  • I "I"':" -.. : ! '3. ' i 19. i I :o. ' --: --! 1:; _, 2.:: Initial Gas Reading ! 'ii L/ 3, 8' r<rm;l
  • t:ony?fhSC,!ft{

F i:-ial Gas er Reading ) :;-Cf 7 }1 J-0£ Air Passing chru the Gas !-!eter /f{;2'{, 1/(V) ct.t..ft, Intervals '1f'ltofr'"rei,.J ?ress::...=e 'f,t) tJ t Y"I ,,J --o& 117 JLj.6-) ob 5"2... } '1

  • l* ) ct S7 I 1../, l 5 (; J trD J y, t l Jl(,{6 {) 7 0 Jlj.l 7 / 0 7/J J'1, C, 7 v7 U> I'/. & 7 0 -, 1..:/ }Lf,J"l 2'7 D l c7JS" Jf.{I C7 ljt / c 7 vs c.7Yo tis*r o s-*oo c Sa::/' D "/Jfv /

.*MASTER. I 2. /q, 0 27. 3.t.i.o 2s. 14.61..'3 129. ! s.t"J...3 ho. s.&f.O 133. 9. (,'-f, {) 34. I -I ;13. S-f>.V I I 14. s:>, s* 13 9 . !1s. S""J' 0 40.-i16. 5'3. 0 .n. ! -. <"') .11. J' * () 42. I !.>-j, () 119. 43. I 5:"3. i) 119. 44. 120. 52. 5 ,45. I :1 i_.'5 I 1 *-.:..:. """ i.,, !-13 I 149. I I 1 23 i 32 ! 1_. /7, () 26. 3

  • I r. '.> __ -+2_0 _. ----' 4. Jes, 29. 5.

!20. s. 0 In. 32. ! 13 3. 34. 135. 111. ;i.e. I \, ,<; 1..:. -* '31. o 14. 11,7 39. ! I I 'I I 1 140. i 115. : 116. ; (1. g' l.11. i I I c1. 1 142. ! ,, -_:. I I CJ I b 14 3. l1a. ! 119. 19. L l.i.:. ; ; 120. r1. '2 l i 145. ::Z: .. 6*. i '22 l i :23

.... -i: ..::,.; -J --?.-:-*.
  • SP (0) 4. 6 .1. 2 1.2 the mass pumped back into the Containment by performing the following:

144 PV ET V Volume of air passing thru the gas meter during the pump back (ft 3) p Gas meter inlet pressure (psia) T Absolute temperature of the air the gas meter (450.59 cF) R Gas constant (53.35 ft/lbF/lbm °F) M Mass as determined by gas 1.3 The results of this *test shall be considered acceptable if the difference between added mass as by the Type A instrumentation agrees with the added mass as b'! the gas meter to within .25La M 1 nass as determined by methods during the ILRT during pump cass of that which would have been in the concainment had air pumped back into the contain2ent as by methods the ILRT . ii I __ . UNS.:\T ;;.:=v. Q /\ 1. 0 1.1

  • MASTER SP(0)4.6.l.2 CHECK OFF SHEET 4.10 VERIFICATION TEST BY SUPERD-!POSED LEAKAGC: HATE METHOD Verify the accuracy of the instrumentation employed in the Type A test to determine the overall integrated leakage rate by performing the following:

LSV superimposed leakage rate (measured with a thermal mass flowrneter) SC.!"'.*! LS superimposed expressed as lbm/Day LC containment composite leakage rate as determined by the method employed du:?:"ing the ILRT LN net containment leakage rate L:l T T T The results of thi? test shall be considered acceptable if the difference between the leakage rate (LN) established during the verification test and the leakage rate (Lam durins Integrated Leakage Rate Test) is less than 0.25 La (206.25 Lbm(air)/Day . i I ! SAT c-i ' ! , __ UN SAT Ss.2.em U:i.it l _,_ ::.e'"'.r

  • . J 4.0 INSTRUMENTATION 4.1 Instrument Description Containment leakage rate computations are based on the measurement of changes in absolute pressure, water vapor pressure, and drybulb temperature.

Since the changes in the above parameters are small, the accuracy, repeatability and resolution of the sen-sors, and in essence the complete system, require precise, reliable and accurate measurement. The Volumetrics ILRMS not only uses high accuracy ' sensors but also combines these inputs with high

  • accuracy, high resolution, and reliable electronic networks to provide a system that can be precisely defined from sensor input to system output. The drybulb temperature is measured by use of resistance temperature detectors (RTD) and is recorded by the data acquisition system (DAS) in degrees Fahrenheit.

The vapor pressure is measured by use of lithium chloride (Foxboro) dewpoint sensors and is recorded by the DAS in degrees Fahrenheit. The absolute pressure is measured by use of a fused quartz bourdon tube. The low internal viscosity of 4.1 Continued fused quartz makes it the most perfectly elastic material known. Therefore, this type of sensor offers no measureable hysteresis, fast response, high resolution, and high accuracy. The output of the pressure sensor is in parallel BCD form to the mini-computer. The flow measur*ement, vital to the leak verification test is also an integral part of the system. The system will accommodate the superimposed leak method or the pump back method (mass change verification test) . The data acquisition portion is a microprocessor-controlled data acquisition and recording system. The system is designed around the INTEL 8080A micro-processor and it is this unit, in conjunction with ROM and RAM memory, a scanner assembly, integrating digital voltmeter and various interfaces that constitute an intelligent data acquisition system. The output of the pressure, drybulb temperature, and dewpoint can be presented to the outside world through an ASCII interface. A computer can then operate on the raw data and present the calculation of the containment absolute leakage rate. A. 2 Primary Instrumentation 4.2.1 4.2.2 4.2.3 Temperature The drybulb temperature sensors (RTD) conform to the following: Configuration: Operating Range: Accuracy: 60 -120°F Repeatability: Sensitivity: Element: Resistance 3 Wire 0 to 150°F +/-0.1°F +/-0.1°F 0.01°F Platinum 100 Ohms @ 32°F Dewpoint Temperature Measurement The dewpoint temperature measurement sensors conform to the following: Dewpoint Range: Dewpoint Accuracy: Dewpoint ability: Dewpoint Sensitivity: Type of Sensor: Pressure Measurement 32 to 140°F +/-1. 0°F Over 60°F Range +/-0.50°F +/-0.1°F Lithium Chloride The pressure measurement is made with pressure sensors that conform as follows: Operating Range: Accuracy: Repeatability: Stability: Type of Sensor: 0 to 100 PSIA +/-.02% of Reading .001% of Full Scale Less Than .001% F.S. Per Degree Fahrenheit Ambient Temperature Range Quariz Bourdon Tube 4.2 Continued 4.2.4 4.2.5 4. 2. 6 4. 2. 7 4.2.8 Ambient Pressure Operating Range: Accuracy: Repeatability: Stability: Type of Sensor: Ambient Temperature Operating Range: Accuracy: Repeatability: Element: Resistance Verification Flow Sensor Operating Range: Accuracy: Repeatability: Type of Sensor: Digital Display Drybulb Temperature: Dewpoint Temperature: Pressure Sensor: Flow Meter: Ambient Pressure: Ambient Temperature: Time:

  • Channel: Type: Digital Printer Print Wheel Columns: Print Speed: Printout Vertical Spacing: 12 to 17 PSIA +/-.1% F.S. +/-.1% F.S. +/-.15% 6 Months Strain Gauge 0 to 150°F +/-.2°F +/-.15°F Platinum 100 Ohms @ 32°F 1 to 10 SCFM +/-1% F.S. +/-0.5% F.S. Thermal Mass meter 0.00 to 200.00°F 0.00 to 175.00°F 100,000 Counts For Full Scale 0.00 to 10.00 SCFM 12.00 to 17.00 PSIA 0.0 to 150.0°F Julian Date, Hours, Minutes, Seconds 000 to 999 7-Segment LED 18 Column 2.5 Lines/Sec.

5 Lines/Inch

    • -.:.: '*

ce 4.2

  • Continued 4.2.8 4. 2. 9 4.2.10 Cont'd Paper Type Internal Storage: Remote Paper Advance: Remote Print Command: Paper Runout Warning: Data Acquisition System A/D Conversion:

Display: Sampling Rate: Common Mode Rejection: Normal Mode Rejection: Input Impedance: Ambient Temp. Range: Zero Offset: Voltage Temp: Accuracy: IL RMS Channel Assignments CH 0 CH 1 CH 2 CH 3 CH 4 CH 5-9 CH 10-33 CH 34-39 Roll Paper Standard Standard Standard Dual Slope Integration V+F, Constant Scan Rate 5 + Digit, Polarity, Decimal & Legend 2.5 Channels/Seconds DC-180db, 10,000 Ohm Unbalance AC-180db at 50-60 HZ 80 db 1,000 Meg Ohms/Volt 0-50°C Recalibrate Before Each Reading Automatically +/-.002% of Reading (.25µV/°C) +/-.005% F.S., +/-.005% of Reading at 25 C with 10% A.C. Power Variation Zero Volt Reference 100 Millivolt Reference Ambient Pressure Ambient Temperature Verification Flow Skip (spare) Drybulb Temperature Dewpoint Temperature 4.3 *

  • Support Instrumentation 4.3.1 4.3.2 Pressure Gage Heise -Model C.M., 0-60 psig Temperature Compensated Resolution
  • -0.1 psi Accuracy -+/-0.1% F.S. Repeatability -1 part in 5,000 Barometer Resolution

-0.1 psia Accuracy -0.25% Repeatability -Not specified

  • 4.4 Verification Instrumentation Calibration Check Standard Instruments 4.4.1 Pressure Gage (1) Texas Instruments, Model 145-01 with Type 12 pressure capsule Range: Resolution:

Accuracy: Repeatability: 0 to 100 psia 0.001 psi 0.010% of reading +0.002% f.s. 0.0003% f.s. 4.4.2 Dew Point Hygrometer (1) EG&G System Model 660-Cl EG&G Sensor Model 660-S2 Range: Accuracy: Sensitivity: -58°F to 212°F :!:.54°F :!; 0. 1°F 4.4.3 Temperature Sensors Doric Platinum Resistance Thermometer (1) Model DS100-T5 Range: Accuracy: Repeatability: 0 to 120°F +/-0.01°F :l:0.01°F Doric Digital Trendicator (1) Model 410A Range: Accuracy Resolution: -200°c to 400°C :1:0.s 0 c 0.1°C Copper/Constantan Thermocouples (24) omega Engineering 20 Gauge, Solid, Teflon/Teflon .044" x .082" Range: Special: -75°F to 200°F :I: 3/4°F Tolerance

  • Verification Test Instruments

-Pump Back 4.4.4 4.4.5 Gas Meter (1) 3M-125 T.C. Dresser Ind. Inc. Range: 0 to 3000 CFh Accuracy: 100.75% Temperature compensated to 60°F Matheson Pressure Gage 63-5612 Range: Accuracy: 0 to 100 psig +/-0.5 psig Verification Test Instruments -Superimposed Leak Rate 4.4.6 Flow Sensor (1) Type: Thermal Mass Flowmeter Range: Accuracy: Repeatability: 0 to 10 SCFM +/-1% F.S. +/-0.5% F.S . Located in Class A Console with direct interface to DAS 4.5 *

  • Instrument Integrity Test 4.5.l 4.5.2 4.5.3 Purpose To verify that no significant changes in instrument integrity has occurred prior to the conduct of the test. Description Immediately preceding the leakage rate test, containment temperature and dew point shall be measured with primary and verification instrumentation.

The data from both systems shall be compared to verify that the integrity and calibration of the containment leakage measuring system has been maintained. The pre leakage rate instrument integrity test shall consist of recording data on both systems and comparing the results during the same time period. In addition, the integrity of the precision pressure gages* shall be verified with a calibrated precision pressure gage before the leakage rate test commences. Temperature Sensors The difference between the verification temperature and the temperature read by the primary instrumentation should be within +/-1°F *

  • ,
  • 4.5.4 4.5.5
  • 4. 5. 6 4.5.7
  • Dew Point Sensors The difference between EG&G Hygrometer dew point and the dew point temperatures read by the primary instrumentation shall not exceed +/-s°F. Pressure Gages The difference between the average pressure measured with the precision pressure gages and the pressure indicated by the precision pressure gage used as a standard shall not exceed +/-0.05%of reading. Prerequisites Recirculating fans are running in slow speed. Containment temperature is stable. Equipment hatch and air lock doors are closed if practical.

Procedure Record data from primary and verification temperature sensors for the same time intervals . 4.5.7 * * (Cont'd.) Record data from primary and verification dew point sensors at the same time intervals. Perform instrument integrity test on the two precision pressure gages. The test shall consist of applying pressures of approximately 45 psia and 62 psia to the precision pressure gages and the verification instruments, simultaneously and the data recorded. Review test results for conformance to the acceptance criteria. If test results do not meet the acceptance criteria, an investigation shall be conducted, the cause corrected, and the test rerun. If test results compare favorably with the acceptance criteria the tests shall be considered completed . 4.6 Instrument Failure 4.6.l 4.6.2 Introduction While it is hoped that all instrumentation functions properly during the 6onduct of the test, instrument failure is a possibility and must therefore be considered. In general, the number of temperature and dew point sensors that may fail before the test must be aborted is a function of the number of sensors used, the sensor locations, the volume fractions assigned to each sensor and the instrumentation error analysis. While all of these factors enter into a decision to abort the test, the system error analysis is the only one that may be applied objectively. Therefore, any decision to abort or continue the test shall be governed by the error analysis. NOTE: The error analysis (system figure of merit) is also a function of time. Good engineering judgment shall be applied if it becomes necessary to extend the test to maintain an able system figure of merit. Failure Criteria (General) Instrument failure, at its onset, can* usually be identified by data from the failing instru-ment constantly drifting apart from the average 4.6 Continued

4. 6. 2 4.6.3 Cont'd of similar instruments monitoring the same test parameter.

If, during the conduct of this test, data obtained from a given sensor drifts by more than 10% of the weighted average temperature or dew point, whichever applies, that sensor shall be considered to have failed. Data from the failed sensor shall be recorded throughout the duration of the test, and the failure verified after the test is concluded. Failure Criteria (Specific) In the event of instrument failure during the conduct of the test, the following courses of action, and criteria to abort the test shall apply. Temperature If a temperature sensor fails during the test, the volume that sensor was monitoring shall be: transferred to one or more adjacent sensors and the weighting factors .adjusted accordingly. transferred to a sensor that had for all practical purposes indicated the same temperature for a minimum of four hours prior to sensor failure and the weighting factors adjusted accordingly. The decision to abort the test shall be based on: 4.6 Continued 4.6.3 Cont'd the impact each sensor failure has on obtaining valid data. the effect each sensor failure has on the system figure of merit. Total Pressure a second precision pressure gage is provided for redundancy only, the loss of one gage shall not be considered cause to abort the test. NOTE: The change in the system figure of merit due to the loss of one precision pressure gage is in the order of magnitude of io-5 and is therfore considered negligible. Vapor Pressure If a dew point sensor fails during the test the volume that sensor was monitoring shall be: transferred to one or more adjacent sensors and the weighting factors adjusted accordingly. transferred to a sensor that had indicated the same dew point temperature for a imum of four hours prior to sensor failure. The decision to abort the test shall be based on: the impact each sensor failure has on obtaining valid data. the effect each sensor failure has on the system figure of merit. NOTE: If data recorded over the preceding five hours indicates that dew point temperatures have stabilized, or that any changes that may occur are not of an order to error in the leakage rate calculations, then loss of any or all of the dew point sensors shall not be considered cause for aborting the test. 4.7

  • Pretest Instrumentation Error Analysis The error analysis was used primarily to select a balanced integrated leak rate measurement system and evaluate, in advance, the figure of merit for the system. Initially the analysis determines the range of expected error based on the instrumentation calibra-tion tolerances and sequencially the range of expected error based on instrumentation repeatability.

Since containment leakage rate computations are a function of changes in temperature and pressure and not the absolute value, the repeatability error analysis is more meaningful and will therefore be used to demonstrate that error introduced by the instrumentation is within the allowable limit stated in ANS N274. The leakage rate in percent per day based on an interval of measurement of 24 hours duration is: Where: L = (100) (24) (Hf To Tn Pn] Po (1) Po = Po -Pvo = total containment atmosphere absolute pressure, in psia, at the start of the test, corrected for water vapor pressure. 4.7 Continued Pn = Pn -Pvn = total containment atmosphere absolute pressure, in psia, at data point n after start of the test, corrected for water vapor pressure. To, Tn H M containment mean atmospheric temperature in °R, at the start of the test and at data point n, respectively. = test interval in hours between time o and n. = Mass of air in containment structure (lbs. l The change or uncertainty interval in M due to un-certainties in the measured variables is given by: EM 2400 [ (:N . 0 ) 2 + (:a . 0 ) 2 = PN Po H ( . 6 To) 2 2] 1/2 ( 2) + +(dM *0) dTN TN where o is the standard error for each variable. This formula assumes that all errors are systematic rather than random in nature. Even though the formula is deterministic, it does allow assessment of figure of merit for various equipment to be used in the-measuring system without the need for assembling and calibrating the system as an entity. 4.7 Continued The error in M after differentiating is: 2400 [ . r ( PnTo r EM = PN + Po H p 2TN 0 ( 3) ( -r ( p T T )2] 1/2 -PN + --. T + _No -:-..:::: Po TN PoTN2 where: -op Po = 0 -0 PN = PN T = oT = oT 0 N Since the values of To and TN are essentially the same and with P 0 -essentially and since Po PN along and PN are -the same, let To = TN, Po = PN, and Po = PN so that equation (3) becomes 2 + 2 *1/2 On the assumptio*ns of a mean absolute pressure of 62 psia, a containment mean atmosphere temperature (drybulb) of 62°F, and a containment mean dew point temperature of 60°F the analysis of repeatability is made. where: PT= Repeatability .001% of full scale 4.7 *

  • Continued PT [ ( l J2 + ( . 0 0 31) 2 ] l/ 2 PT= 0.00318 Vapor Pressure PV = Repeatability

+/-.5°F 60.0°F = 0.2561 psia 60.5°F = 0.2607 psia PV = (.0030)2] 1/2 PV = 0.003539 Temperature 62°F T = -Repeatability +/-0.1°F J2 2 ]1/2 T = + (.0030) T = 0.020632 FOM (100) [ 2 ( 0.00318)2 24 62 ( 0. 0206 ) 2 ] l/2 2 521.7 2 + 2 ( 0

  • 3 sr + FOM 1.220885 x 10 or .01220885%/Day ANS N274 states that the FOM for an acceptable measuring system should be less than 0.25 La. 0.25 La = 0.25 (O.l) %/day = 0.025%/day Since the FOM for the system being used for the test is well below the allowable limit it is considered acceptable.
  • *
  • 4.8 Post ILRT Instrument Error Analysis The post ILRT analysis was performed to verify that the Figure of Merit (FOM) using the Instrument Selection Guide (ISG) formula meets the acceptance criteria.

ANS N274 states that the FOM for an acceptable measuring system shall not exceed 0.25 La, prior to the test for purposes of instrument selection, or at the end of test in order to meet the loss of sensor criteria. 0.25 La= (0.25) (0.1%/Day) = The loss of any sensor will increase the FOM and may necessitate extending the test duration to decrease the FOM to 0.25 La or less. No sensors were lost during the conduct of this first ILRT retest of Unit 1. The FOM was calculated for the post test condition, using the ISG formula as derived for the Absolute Method, to comply with the requirements of ANS N274. For the most part, the analysis that follows is based on random error due to instrument repeatability and readability. This approach is justified because we are dealing with very small changes in the test 4.8

  • Continued parameters when compared to their absolute values. Further justification is the fact that bias error has been minimized thru the application of calibration correction factors to all recorded data. The calculation for the post test FOM was accomplished by substituting the average pressure, vapor pressure and temperature encountered during the test for the assumed values used in the pretest analysis.

The equations could also be modified to reflect the loss of any sensors if required. FOM After Test Where: PT Repeatability .001% of full scale 2 + (.0031) 2 J PT= 0.00318 Vapor Pressure (6 Dew Cells) PV Repeatability +/-.5°F 76.0 76.5 = . 4443 psia = . 4518 psia 1/2 PV= [( 2 + (O

  • 0030) 2] 1/2 PV = .00436 4.3 Continued Temperature T =Repeatability

+/-0.1°F T 2 + (.0030) T = 0.020632 24 FOM= 24 (100) 2 (* 020632 ) 2 J l/2 85 + 459.7 FOM = 0.01349074%/Day Since the FOM after test is well below the allowable limit of 0.025%/Day it is considered acceptable. s.o VERIFICATION TEST 5.1 Pump Back Method 5.1.1 Description This test is performed to verify the accuracy of the instrumentation employed to measure the leakage rate during the Type A test. It is accomplished by pumping between 50% and 100% La thru a gas meter and into the containment. The mass of air added to the containment is then calculated as follows: M = 144 PV RT Where: V = Volume of air passing thru the gas meter during pump back P = Gas meter inlet pressure -psia. T = Absolute temperature of the air passing through the gas meter. 459.69 + °F R = Gas constant = 53.35 ft lbf/lbm F M = Mass as determined by gas meter The mass of contained air (M 1) shall then be calculated using the method employed during the Integrated Leakage Rate Test. The air mass (M 2) that would have been in the ment had air not been pumped back into it will 5.1 *

  • Continued 5 .1.1 5 .1. 2 5 .1. 3 Cont'd. be determined by extrapolating the least square line developed during the Integrated Leakage Rate Test. The difference between M 1*and M 2 will be the mass of air pumped back into the containment.

Acceptance Criteria Results of this test will be considered acceptable provided the difference between the added mass as measured by the Type A test instrumentation agrees with the added mass as determined by the gas meter to within 25% of La. i.e. M-(M 1-M 2) < .25 La Instrumentation The instrumentation used for the pump back verification test is given in Section 4 (4.4.4 and 4.4.5) of this report. The gas meter used is temperature compensated to read SCF at 60°F

  • 5.2
  • Superimposed Leakage Rate Method 5.2.1 Description This test will be conducted to verify the capability of the instrumentation employed in the Type A test to determine the overall integrated leakage rate. NOTE: This method will be used only if results of the "Pump Back" test are Unsatisfactory.

The test will be accomplished by superimposing a controlled leakage equivalent to La on the containment. The desired superimposed leakage rate will be achieved by properly adjusting a suitable instrument control valve. The volume of air released from the containment as controlled leakage will be measured with a thermal mass flowmeter. The mass of air allowed to escape per unit of time from the containment as controlled leakage will be calculated as follows: = 144 PV 24 RT h Where: V = Volume of air as determined with the thermal mass flowmeter. 5.2

  • Continued 5.2.1 5.2.2 Cont'd P = Gas meter inlet pressure -psia. T = Absolute temperature of the air passing through the gas meter. R = 459.69 + 6Q°F = 519.69°F = Gas constant = 53.35 ft. lbf/lbm F Ls = Superimposed leakage expressed as lbm/Day h = Total hours from the beginning of verification test. the The containment composite leakage rate (Le) shall then be determined using the method employed during the Integrated Leakage Rate Test. NOTE: The verification test tsuperimposed method) .shall be performed over an eight hour period (minimum)

.. The net containment leakage rate (Ln) is calculated by subtracting the superimposed leakage rate from the composite leakage rate. Acceptance Criteria Results of this test shall be considered acceptable if the difference between the leakage rate (Ln) established during the *: . .::.: 5.2 Continued 5.2.2 5.2.3 Cont'd verification test and the leakage rate (Lam) established during the Integrated Leakage Rate Test is less than 0.25 La. Instrumentation Thermal Mass Flowmeter ILRT "A" Test instrumentation

  • COMPUTER PROGRAM 6.1 General Discussion The computer programs used for the data acquisition, compilation, and calculation of leak rate data and the analysis of this data were developed by PSE&G Research Corporation, Research and Testing Laboratory specifically for the purposes of computing containment integrated leak rate test results of both units at Salem Nuclear Generating Station. The formulas used in these test programs are taken from formulas and guidelines presented in ANSI N45.5 -1972 and ANS 274
  • Correction values for temperature, pressure and dew point obtained from a least squares fit of calibration points were incorporated in the program. Hence, all calculated values need no modification or corrections applied. Therefore, no penalty for instrument error will be applied to the final leak rate values as computed.

The following flow charts are the programs used for the test: Figure 1 -Temperature Stability Figure 2 -ILRT Test Figure 3 Superimposed Leak Verification I I 1 *

  • FIGURE 1 TEMPERATURE ST."\BILITY TEST NO NO ST.'\RT CAf.C. I PRESSUI<E CORR FROM CALIBHATION CURVES C.Z\LC. WEIQITED AVG RIDS, DE:r'7 POINI'S AND P'.1ESSURES YES YES TEST TERl1IN!\TID PRTh"I' STABILITY DATA 6 5
  • YES
  • PRESSURE CDRR FOCM CALIBRATIOi'I aJRVES CALC :*iEIG!ITED AVG RI'D'S DEW POINTS PRESSURES CAI£ VAPOR PRESS FRCM DEW POINI' c, CDNI'AINfil!l' AIR MASS MASS PTP TOTAL TTI-!E LEAKAGE RATE TEST TEST TER'ITNATED LINEAR REGRESSIOi'I 95'1; CDNFIDENCE REGRESSION DATA PRINI' our ALL TEST DATA G.'\THERED TEST C'CMPLETE NO NO 8 9 LE.'\K VERIFICATION STAR.T VOILNETRIC CALIBRATION CURVE CAI.C PRESSURE CORR. FRJt-1 CALIBRATION CURVES CAI.C WEIGHTED AVG .RI'Ds, DEl*I POINI'S A.'ID PRESSURES CAI.C VAPOR PRESS. FRCM om coINT AIR PTB MASS T<:n'AL TIME "VCAVGS" LINEAR REGRESSICA'l 95% CDNFIDENCE ru:x:;RESSICN DATA PRTh'T our ALL TEST DATA NO NO 6.2
  • Leak Rate Computations The formulas for computing the measured leak rate and mass were taken from ANSI 45.4 -1972, "Leakage Rate Testing of Containment Structures for Nuclear Reactors".

The derivation of these formulas are also given in ANSI N45.4 -1972. The formulas are as follows: LR Where, Pvo' Pvl 2400 H [ 1 -] LR = Measured leak rate in weight percent per day H = Time interval in hours, from time "O" = Mean absolute temperature, OR, of the containment atmosphere at the beginning and the end of the test interval (H) respectively. = Mean total absolute pressure, psia, of the containment at the beginning and end of the test interval (H) respectively. = Mean total water vapor pressure, psia, of the containment atmosphere at the beginning and the end of the test interval (H) respectively. The formula for mass is as follows: Where, 6.2 Continued v = Mass of air in the containment structure at time N (lb) = Total free volume of the containment structure (cu. ft.) R = Gas constant 53.35 ft. lbp/lbM °F = Mean absolute temperature, 0 R, of the containment structure at time N = Mean total absolute pressure psia, of the containment atmosphere at time interval N = Mean total water vapor pressure, psia, of the containment atmosphere at time interval N 6.3

  • Calculated Leak Rate Since it is assumed that the leak rate is constant during the testing period, a plot of the Measured Mass versus Time would ideally yield a straight line. Obviously, sampling techniques and test conditions are not perfect and consequently the values of measured mass deviate from the ideal straight line plot situation.

The method of Least Squares was the statistical method used for determining the "best fit" straight line, commonly called a regression line. The function of the least squares fit is to minimize the sum of the deviations between the measured and calculated mass points. After establishing the regression line, the values of Calculated Mass and Calculated Leak Rate can be determined. The regression line equation for the Least Squares "best fit" straight line is: Y = AX + B Where, Y = Calculated Mass X = Time interval of test therefore, the calculated mass at some specific time 6.3 Continued (X) is expressed as: The deviation of the measured mass (W) from the calculated mass (Y) is: Deviation = WN -YN As mentioned previously, the minimization of the sum of the squares between the regression line (calculated mass) and the measured mass will yield the following equation: where SSQ is the sum of the squares of the deviations and therefore can be written: By the use of differential calculus the values for A and B that will minimize SSQ can be determined. The value for B will be the Y intercept and A will be the slope of the regression line. These values of A and B constitute the solutions to the following pair of simultaneous linear equations: A = (XN -X) (WN -W) (XN -x)2

  • 6.3 Continued N IX w (IXN) (IWN) A = N N -2 2 NIX (IX ) N N --and B = w -AX -Where, w = IW N N -x = IXN and N = 2X By substitution

=

  • These equations are shown as the Least Square Equations and are used in a computer program to calculate mass for the mass point method of leak rate computations .
  • 6.4 *
  • Confidence Limits Even though the regression is statistically determined to minimize the sum of the squares of error, the values of the calculated mass cannot be considered to be exactly correct. If the containment integrated leak rate test were run a number of times, and under similar conditions, the values for calculated mass would be close in value but would not be the same for each run. Therefore by using other statistical methods, a degree of confidence which is related to the regression can be determined.

The method that was used to establish the confidence parameters is the student's "t" distribution. The limits to be used are 95% as specified in ANS N274. To determine the value of the confidence limits :the following statistical information is required: The variance, standard deviation, and student's "t" distribution. The procedure used to establish the 95% confidence limits was to find the variance by dividing the SSQ by N-2 which is the degrees of freedom. a2 = SSQ N-2 The standard deviation was then found by taking the 6.4

  • Continued square root of both sides of the equation . cr = . ( SSQ) 1/2 N-2 The standard deviation has more practical significance because it returns the measure of variability to the original units of measurement and that given a normal distribution of measurements, approximately 95% of the measurements will fall within two (2) standard deviations of the mean. However, because we are dealing with a regression analysis an additional factor must be used for determining the standard deviation of the slope of the line. cr and because of the small sample size the number of standard deviations either side of the regression line to establish a 95% confidence interval are more accurately determined by using a student's "t" distribution.

t = 1.95996 + 2.37226 + 2.8225 N-2 (N-2)2 from which the confidence limits are obtained by 6.4 Continued C.L. = t*95 (J which were added to and subtraced from the various calculated mass points obtained from the regression analysis to determine the upper and lower confidence limits.

7. 0 *
  • CONTAINMENT INTEGRATED LEAKAGE RATE TEST RESULTS 7.1 ILRT Test Results Summary The Integrated Leakage Rate Test (ILRT) was conducted in accordance with procedure SP(0)4.6.l.2 "Reactor Containment Type A Integrated Leakage Rate Test". A pre ILRT instrument integrity test was also performed to make certain that no significant changes in the instrumentation had occurred prior the ILRT. Results of these tests are presented in tabular and graphical form as follows: ILRT OF RESULTS INSTRUMENT INTEGRITY 1'EST

SUMMARY

CONTAINMENT VS. TIME CONTAINMENT PRESSURE VS. TIME CONTAINMENT TEMPERATURE VS. THIE CONTAINMENT VAPOR PRESSURE VS. TIME CONTAINMENT DEW POINT VS. TIME 1 TABLE 2 FIGURE 1 FIGURE 2 FIGURE 3 FIGURE 4 FIGURE 5

  • 7.1 Continued TABLE 1 ILRT A TEST AT 47.9 PSIG Calculated Leakage, Lam Type C Leakage to be Added Total Calculated Leakage at 95% Confidence Level Type C Leakage to be Added Total TYPE C LEAKAGE Penetration No. 40 61B 61A 19 'l'O Total Type C Leakage Results 0.056 0.000 0.056 0.062 0.000 0.062 BE ADDED Leakage Rate SCCM 22 0 0 206 228 Acceptance Criteria %/Day 0
  • 10 0 (Max * ) 0
  • 0 7 5 (Max * ) Leakage rate to be added to the Type A Leakage equals 0.0004%/Day therefore, none will be added to the above totals.

Tl'.BLE 2 INS'l'RUMENT IN'l'EGRITY TEST

SUMMARY

Temperature (°F) Dew Point (°F) RTD Temp. Std. Sensors Standard Results Average All Sensors 87.56 87 .* 2 8 70.5 72.0 Difference +0.28 -1. 5 Average Difference Acceptance Criteria +/-1. QOF +/-5.0°F Pressure (psia) Pressure Gages (Avg.) Pressure Std. At 47 45.574 At 62 61. 9 82 45.598 -0. 05 % 62.003 -0. 03 % +0.05% of reading f' . I e 'L* 80442'1. 386 + 804'103. 898 + 804383.'111 + 804362.923 + 80'1342. 435 + 804321. 947 + 804301.460 + 80'1280. 972 + 804260. '184 + 804239.996 + 804219.509 + 804199.021 + 804178.533 + 804158.046 + 804137.558 + 804117. 070 + 804096.582 + 804076.095 + 804055.607 + 804035.119 + 804014.631 + 803994.144 + 803973.656 + 803953.168 .+ 803932.680 + 803912.193 + 803891. 705 + 803871.217 803850.730

803830.242 + 803809.754 + 803789.266 + 803768.779 + 803748.291 +

  • 803727.803

+. 803707.315 + 803686.828 + 803666.340 + 80361t5.852 + 803625.365 + 803604.877 + 803584.389 + 803563.901 + 803543. '114 + 803522. 926' + 803502. /138 + 803'181. 950 + 803461. 463 + 8034110. 975 + 803420.487 + 803400.000 + 803379.512 + ., 1' * * * * ** * * * * *

  • e PSE&G RESEARCH CORPORATION RESEARCH & TESTING LABORATORY Salem No. 1 Integrated Leak Rate Test MASS PLOT DATE 8 I 12 I 1979 * * * * * *
  • 0 x * * *
  • Calculated Initial Mass 803899 lbm Calculated Final Mass (Leak Rate) 803446 lbm Calculated Final Mass 95% Level 803399 lbm Calculated Leak Rate -18.866 lbm/hr * * * * * * *
  • 95% Confidence Level * -20.820 lbm/hr * ** * * * * * ** +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time <Hours) 62.421 62.413 62.406 62.398 62.391 62.383 62.376 62.368 62.360 62.353 62.345 62.338 62.330 62.323 62.315 62.307 .,; 62.300 H Ul 62.292 p, 62.285 62.277 62.270 ::i 62.262 Ul 62. 25'1 Ul "1 62.247 p, 62.239 E-< 62.232 z 62.224 J:Ll :<: 62.217 z 62.209 H <i: 62.201 E-< z 62.19'+ a 62.186 u 62.179 62.171 62. 16'1 62.156 62.148 62.141 62.133 62.126 62.118 62.111 62.103 62.095 62.088 62.080 62.073 62.065 62.058 62.050 62.043 62.035 + + + + + + + +** + ** + ** + + + + + + + + + + + + + + + + + + + +* + + + + +. + + + + + + + + + + + + + + + + + ** ** * ** * * ** * *** .** ** PSE&G RESEARCH CORPORATION RESEARCH & TESTING LABORATORY Salem No. 1 Integrated Leak Rate Test PRESSURE PLOT * * * * * *** ** **** ******** ** ** * * * * * * * * ** * ** * * * *

  • DATE 8 I 12 I 1979 ** * ** * * **** * * * * * +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time <Hours) * , r. t:.Fr rz.. 0 ::J E-< >ii p.. ;:;: i:LI E-< E-< z i:LI ?i H ES z 0 u 85. '196 + 85.442 + 85.388 + 85.333 + 85.279 + 85.225 + 85.170 + 85.116 + 85.062 + 85.007 +* 84.953 + 84.899 + 84. 84'1 + 84.790 + 84.736 + 811. 681 + 8.f1. 627 + 84.573 + 84.518 + 84.116'1 + 84.410 + 811. 355 + 84.301 + 8'1. 247 +. 8'1.192 + 8'1. 138 + 84.084 + 8'1. 029 + 83.975 + 83.921 + 83.866 + 83.812 + 83.758 + 83.703 + 83.649 + 83.595 + 83.540 + 83.486 + 83.432 + 83.377 + 83.323 + 83.269 + 83.214 + 83.160 + 83.106 + 83.051 + 82.997 + 82.943 + 82.888 + 82. 83'1 + 82.780 + 82.725 + ** ** ** ** ** * .. .!i. * ** ** PSE&G RESEARCH CORPORATION RESEARCH & TESTING LABORATORY Salem No. 1 Integrated Leak Rate Test PLOT * * * * * ***** ****lf***

        • * * * * * * * * ** * ** ** **** *lf * ** * *
  • DATE 8 I 12 I 1979 * *** lf * * * * * * **** *** ** * * * ** w * * +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time <Hours)

  • PSE&G RESEARCH CORPORATION RESEARCH & TESTING LABORATORY Salem No. 1 Integrated Leak Rate Test VAPOR PRESSURE PLOT DATE 8 I 12 I 1979 0.512 + 0.510 + 0.508 + 0.506 +' 0.504 + 0.502 + 0.499 + 0.497 + 0.495 + 0.493 + 0.491 + 0.489 + 0.487 + 0.484 + o. '182 + 0.480 + o. '178 + o. '176 + 0.474 + o. '172 + o. '170 + 0.467 + 0.465 + o. 463 + *
  • 0.461 +
  • o. 459 + *lt *
  • o. 457 + * *
  • o. 455 +* * * * * *
  • o. 452 + * *
  • 0. 450 + *** ** * * * *
  • 0.448 + ** * * * * * ** * *
  • 0.446 + *** * ** * * ** * * ** 0.444 + 0. '142 + * * * *lf
  • o. 440 + * * * ** *lf 0.438 +
  • 0.435 + * ** 0.433 + * ** 0.431 + *
  • 0.'129 +* o. i127 + 0.425 + 0.423 + 0.420 + o. '118 '+ 0.416 + 0.41'1 + 0.1112 + 0.410 + 0.408 + 0. '106 + 0.403 + * * * *** * ** ** * ** * * * * * +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time <Hours) µ.. 0 . .S,. PSE&G RESEARCH CORPORATION RESEARCH & TESTING LABORATORY Salem No. 1 Integrated Leak Rate Test DEW POINT TEMPERATURE PLOT 77.758 + 77.670 + 77.581 + 77.493 + 77.404 + 77.316 + 77.228 + 77.139 + 77.051 +

  • 76.963 + 76.874 + 76.786 + 76.698 +*
  • 76.609 + 76.521 +
  • 76.432 + *
  • 76.344 + ** * * *
  • 76.256 + *
  • 76.167 + *** * ** * *
  • 76.079 +
  • 75.991 + 75. 902 +
  • 75.814 + 75. 725 -1: * * * *
  • lf** * * * * * * * * * ** * * * * * * * * * * * ** * *
  • DATE 8 I 12 I 1979 * * *
  • 75. 637 + * * *
  • 75.549 + 75.460 + 75.372 + 75. 2811 + 75.195 + 75.107 + 75.019 + 711. 930 + 74.842 + 74.753 + 711. 665 + 74.577 + 71,. 488 + 711. 400 + 74.312 + 74.223 + 74.135 + 74.046 + 73.958 + 73. 870 '+ 73.781 + 73.693 + 73.605 + 73.516 + 73.428 + 73. 3110 + 73.251 + ** * * * * * * * ** * * * * * * * ** * * * *
  • Ul * * * * +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Time <Hours> I . . 'n 7.2

  • Verification Test Results Summary 7.2.1 Pump Back (Mass Step Change) Method The pump back verification test was performed in accordance with the procedure, Paragraph 5.15 to 5.25 and check off sheet 4.9. The test was initiated at 0643 on August 12, 1979 and terminated at 0830 after 1828 ft 3 of air had been pumped into the containment.

The data for volume, pressure and temperature were inserted into the computer which applied applicable correction-factors to all data and computed the mass of air pumped into the containment. The computer then initiated the "Pump Back Program" which calculated the containment air mass using the method employed during the ILRT (See Section 5.1) and compared the results with the acceptance criteria. Analysis of the test data indicates that the difference between the mass of air inserted into the containment and the mass of air as calculated with the Class A ILRT

  • instrumentation is well within the allowable limits. Results Calculated Volume of air inserted Mass of air inserted Instrumentation calculated mass ILRT extrapolated mass Air mass inserted as per ILRT instrumentation Difference in added mass (M) (.M1 ) (M2) M1-M2 M-(M1-M2) 1828.4 ft 3 651. 3 lbm 804165 lbm 803362 lbm 803 lbm 152 lbm Acceptance Criteria M -(M1-M 2) 0.25 La 206.7 lbm The test is therefore considered acceptable.

Note: The pump back test data is given in Table 3 The computer analysis of the ILRT data is presented in Section 7 (7.10 to 7.13) * -:..::: TABLE 3 Verification Test Data -Pump Back Method Gas Meter -Inlet Conditions Gas Meter Time Pressure Barometer Register Reading 8-12-79 psig psi a E't3 at 50°E' 0643 66.5 14.651 0014144 0647 69.0 14.651 0652 62.0 14.649 0657 62.3 14.649 0700 62.3 14.653 0705 61. 9 14.655 0710 67.5 14.656 0715 61. 0 14.663 0720 64.0 14.667

  • 0725 62.0 14.671 0730 67.5 14.673 0735 57.5 14.671 0740 55.0 14.664 0745 53.5 14.667 0750 53.0 14.668 0755 53.0 14.664 0800 53.0 14.664 0805 53.0 14.663 0810 53.0 14.665 0815 52.5 14.668 END 0015972 Average 59.10 14.661 1828
  • e PSE&G RESEARCH .P. RESEARCH 8< TESTING L-RATORY PAGE 1 DATE 8/12/1979 SALEM UNIT NO. 1 INTEGRATED LEAf(AGE RATE TEST TEST STARTING DAY 223 TEST STARTING TIME 4 : 2 ---------------------------------------------------------------------------------------------------------------

READ REAL AMBIENT AVG AVG AVG AVG CONT CALC 95 % CALC TIME TIME TEMP PRESS CONT DEW PT VAPOR CONT MASS LEAf{ CONFIDENCE INITIAL TEMP TEMP PRESS PRESS LEVEL MASS <Hrsl(Hr/Mnl(DegF)(Psia) <Deg Fl <Deg Fl (Psial CPsia) CLbml (Lbm/Hrl(%/Dayl (Lbm/Hrl(%/Dayl CLbml *------------0.00 4 2 79.84 14.74 84.997 76.660 o. 't5't 62.371 803879.0 0.25 4 17 80.45 1'1.7'+ 8'+.973 77.091 o. 1160 62.366 803757.7 0.50 4 32 79.35 1'1. 74 811. 933 76. /105 0.1150 62.362 80390'1. 9 0.75 '1 '17 80.20 111. 7't 8'+.901 76. '197 0. '151 62.359 803887.6 1. 00 5 2 79.98 111. 74 811. 8811 76. 1120 o. '150 62.355 803882.9 1. 25 5 17 79. 61t 14.74 81t. 859 76.184 0.446 62.352 803919.5 1.50 5 32 78.78 1'1. 74 811. 824 76.139 o. 4116 62.346 803906.9 1. 75 5 '17 77.83 14. 7't 84.785 76. 164 O. l1lt6 62.342 803901.5 2.00 6 2 78.61 111. 74 84.767 76.671 o. 11511 62.337 803769.5 2.25 6 17 78.83 111. 74 84.729 76.335 o. '149 62. 33'1 803851.6 2.50 6 32 79.77 1't. 74 Sit. 725 76.315 o. 4118 62.330 803802.6 2.75 6 117 79. 112 i't. 74 84.680 76.129 o. ltl16 62.324 803839.6 -.J 3.00 7 2 79.16 1'1. 74 Sit. 6111 76.363 O. ltlt9 62.319 803780.2 -21.632 o. 061t -65.208 0.194 803885.5 w 3.25 7 17 79.57 1'1. 74 84.589 75.892 0.442 62.311 80381t8. 7 -17.221 0.051 -54.040 0.161 803880.4 H 3.50 7 32 79.54 14.75 84.556 76.363 0.449 62.306 8037111.2 -26.237 0.078 -59.449 0.177 803891. 7 t< 3.75 7 '+7 79. 311 14.74 84.526 76.189 o. 4't7 62.303 803774.0 -28.166 0.084 -56.791 0.169 80389'1. 2 >'3 4.00 8 2 79.26 14.74 8 1 t. 505 76.180 o. 4116 62.299 803761. 1 -29.971 0.089 -54.925 0.163 803896.8 :i:-4.25 8 17 79.91 14.75 84.470 76.21+6 0.1+47 62.293 803721. 2 -33.752 0.100 -56.111+ 0.167 803902.5 11. 50 8 32 80.92 1'1. 75 84.418 76.190 o. 11117 62.288 8037112. 9 -311. 288 0.102 -Slt.062 0.161 803903.3 >'3 t".l 4.75 8 47 81. 14 11+.75 8'1. 396 76.337 0.449 62.28'+ 803695.1 -37.152 0.110 -55.097 0.1611 803908.1 Ul 5.00 9 2 82.07 14.75 84.369 75.754 0. 4'10 62.282 803813.5 -31. 9112 0.095 -49.217 0.1'+6 803899.0 >'3 5.25 9 17 81. 65 14.75 8'1. 364 76.155 o. 4'16 62.281 803731.6 -31. 926 0.095 -47. 493 . 0.141 803898.9 l:rj 5.50 9 32 82. lt6 lit. 75 8'+.353 75.631 0.1+38 62.280 803840.6 -26.363 0.078 -41.975 0.125 803888.3 Ul 5.75 9 '17 83.62 14.75 84.368 76.361 o. 1149 62.282 803704.6 -27.757 0.082 -42. 06/t 0.125 803891. 1 c t< 6.00 10 2 83.78 i't. 75 811. 38/t 76.169 0.'+'+6 62.286 80376'1. 6 -26.155 0.078 -39.371 0.117 803887.7 >'3 Ul 6.25 10 17 84.87 1'+.75 8'1. '+11 76.097 0. 't'15 62.290 803791.5 -23.670 0.070 -36.154 0.107 803882.3 6.50 10 32 85.75 11+.76 *Sit. 11811 75.756 o. '+'10 62.300 803879.1 -18.521 0.055 -31.552 o. 09't 803870.8 6.75 10 117 85.55 14.76 84. SltO 75.892 o. 1+112 62.309 803895.2 -13.777 o. 0't1 -27.072 0.080 803859.7 7.00 11 2 85.52 1'1. 76 84.603 76.223 o. 1,47 62.316 803829.8 -11.809 0.035 -.2'+. 3118 0.072 80385'1. 9 7.25 11 17 86.21 1'1. 76 84.660 76.519 0 * .'+51 62.324 803793.5 -11. 1'+0 0.033 -22.820 0.068 803853.3 7.50 11 32 86.12 1'1. 77 84.730 76.493 o. 't51 62. 33't 803813.0 -10.022 0.029 -20. 98't 0.062 803850. '1 7.75 11 47 86.90 11+. 77 8't. 782 76.496 0.451 62.342 803841. 0 -8.369 0.02'+ -18.792 0.056 803846.0 8.00 12 2 87. Sit 14.77 8'1. 805 76.586 0.452 62. 34'1 803822.6 -7.379 0.022 -17.205 0.051 803843.2 8.25 12 17 88.13 1't. 77 84.806 76.670 o. f15ft 62.343 80378'1. 6 -7.330 0.021 -16.5'18 0.049 8038ft3.1 8.50 12 32 87.65 14. 77 81+.788 76.269 o. '1'18 62.339 8038113. 1 -6.073 0.018 -1'1. 862 0.044 803839.4 8.75 12 47 88.53 14. 77 Bit. 772 76.323 o. 4'19 62.337 803830.5 -5.230 0.015 -13.565 0.040 803836.9 9.00 13 2 88.25 14. 77 84.781 76.115 0.445 62.339 803882.9 -3.553 0.010 -11.659 0.034 803831. 7 9.25 13 17 88.75 14. 77 81t.791 75.886 o. 4112 62. 3't0 803926.2 -1. 379 0.004 -9.451 0.028 803824.8 9.50 13 32 89.07 14.78 84.812 76.347 0.'+49 62. 3112 803832.5 -1. 042 0.003 -8.692 0.025 803823.8 9.75 13 117 89.18 14.78 8'+.825 76.700 o. lt54 62.3'+3 803751. 2 -2.003 0.005 -9.339 0.027 803827.0 10.00 14 2 89.72 lit. 78 84.812 77.063 0.460 62.3111 803671. 7 -3.982 0.011 -11.320 0.033 803833.7 10.25 1'1 17 89.16 14.78 B't.790 76.915 0.457 62.339 803708.0 -5.166 0.015 -12.275 0.036 803837.9 10.50 14 32 86.95 14.78 84.801 76.358 o. 11119 62.338 803787.5 -5.11'+ 0.015 -11.880 0.035 803837.7 10.75 14 '+7 78.11 14.78 811.811 76.435 o. 1150 62.339 803771.3 -5.258 0.015 -11.706 o. 0311 803838.2 11. 00 15 2 76.76 1'1. 78 8'1.819 77.225 0.462 62.340 803616.3 -7.2'17 0.021 -13.819 0.041 803845.7 11. 25 15 17 72. 81 1'1. 76 8'+.837 76.723 o. '154 62.3'+1 803702.6 -7.961 0.023 -14.291 0.042 803848.4 11. 50 15 32 76.04 1'1.76 Bit. 839 76.'+15 o. '150 62.3'+0 8037'+6.1 -8.080 0.02'+ -1'+.133 0.042 8038'+8.9

11. 75 15 '+7 77.85 1'+.76 84.820 76.532 0.'+52 62.337 803719.2 -8. 't'19 0.025 -14.256 o. 0112 803850.3 12.00 16 2 77. 22 11t. 76 8'+.856 76.792 0.456 62.3'+3 803687.5 -9.076 0.027 -11+.685 0.043 803852.9 12.25 1b 17 79.10 111. 75 81+.890 76.886 o. 1157 62.3'+7 803678.0 -9.700 0.028 -15.126 0.045 803855.5 It" r .1: '
f .... * : ..
... ,. J_: e e , F'SE&G RESEARCH CORF'. RESEARCH & TESTING LAG ORATORY f'AGE 2 DATE 8/12/1979 SALEM UNIT NO. 1 INTEGF\ATED LEAf{AGE F\ATE TEST TEST STARTING DAY 223 TEST STARTING TIME 4 : 2 ----------------------------------------------------------------------------------------------------------------

READ REAL AMBIENT AVG AVG AVG AVG CONT CALC 95 /. CALC TIME TIME TEMP PRESS CONT DEW PT VAPOR CONT MASS LEAf{ CONFIDENCE INITIAL TEMP TEMP F'F\ESS f'F\ESS F\ATE LEVEL MASS <Hrsl(Hr/Mnl<DegFl<Psial <Deg Fl <Deg Fl (f'sial (f'sia) <Lbml <Lbm/Hrl(/./Dayl (Lbm/Hrl(/./Day) <Lbml ------------12.50 16 32 76.71 14.74 84.903 77.266 0.463 62.350 803622.6 -10.750 0.032 -16.097 0.048 803860.0 12.75 16 47 72.98 14.74 84.921 76.927 0.1158 62.351 803669.4 -11.2311 0.033 -16.399 0.048 803862.1 13.00 17 2 71. 29 14.73 811. 907 76.979 0.458 62.347 803634.7 -11. 9113 0.035 -16. 9711 0.050 803865.2 13.25 17 17 70.50 14.72 84.849 76.499 0.451 62.339 803702. 11 -11. 981 0.035 -16.820 0.050 803865. 11 13.50 17 32 68.65 14. 73 84.771 76.750 0.455 62.327 803617.5 -12.676 0.037 -17.403 0.051 803868.5 13.75 17 47 67. 911 1'1. 73 84.689 76.407 0.450 62.3111 803(V11. 1 -13.091 O.OJ9 -17.669 0.052 803870.5 14.00 18 2 69.02 14.72 84.634 77.060 0.460 62.305 8031t76.3 -14.677 O.Olt3 -19.lt56 0.058 803878.0 14.25 18 17 70.39 11t.72 84.580 75.912 O.lt42 62.297 803668.2 -111. 682 o. 0113 -19.291 0.057 803878.0 -.J 14.50 18 32 69.15 111. 72 81t.515 75. 6511 o. 1139 62 *. 289 803715.5 -11t.329 o. 0112 -18.796 0.056 803876.3 w 1't.75 18 117 68.88 1'1. 72 84.473 76.439 O.'t50 62.282 8035311. 7 -15.211 O.O't5 -19.6115 0.058 803880.7 H 15.00 19 2 69.22 1'1. 72 84.lt't6 76.208 0. A'i7 62.279 803573.8 -15.727 O.O't6 -20.053 0.059 803883.3 t-< 15.25 19 17 67.06 1't.72 84.lt13 76.092 0.4'i5 62. 2711 803586.4 -16.090 o. 0118 -20.293 0.060 803885.2 t-3 15.50 19 32 68.33 111. 71 811. 380 76. 2'17 0.11117 62.267 803519.'t -16.805 0.050 -20. 9511 0.062 803889.0 15.75 19 117 66.85 1'1.71 811.349 75.675 0.439 62.263 803621.5 -16.821 0.050 -*20. 837 0.062 803889.1 16.00 20 2 65.92 14.70 84.31*4 75.711 0.439 62.259 803607. 11 -16.893 0.050 -20.783 0.062 803889.4 t-3 i:':I 16.25 20 17 64.29 1'1. 69 84.267 75.267 O.'i33 62.252 803670.0 -16.585 o. 0119 -20.371 0.060 803887.7 Ul t-3 16.50 20 32 63.40 14.68 84.233 75.392 0.435 62. 2116 8036211. 6 -16.528 o. 0119 -20.199 0.060 8038B7.4 16.75 20 117 63.66 1'1.67 811.186 75.680 0.439 62.2'i0 803554.1 -16.825 0.050 -20.402 0.060 803889.1 Si 17.00 21 2 611. 72 1'1.67 84.135 75.838 o. 11111 62.231 803487.6 -17.416 0.051 -20.952 0.062 803892.5 Ul c:: 17.25 21 17 65.'i2 11t.67 84.029 75.690 0.439 62.216 803475.4 -17.996 0.053 -21.493 0.064 803895.9 t-< 17.50 21 32 65.12 14.67 83.957 75.141 0.431 62.205 803541.6 -18.186 0.054 -21.589 0.064 803897.0 Ul 17.75 21 117 65.90 111.67 83.930 75.338 o. 1134 62.202 8035011. 0 -18.515 0.055 -21.8114 0.065 803899.0 18.00 22 2 66.98 14.66 83.950 75.325 0.434 62.205 803524.0 -18.706 0.055 -21. 948 0.065 803900.2 n 18.25 22 17 66.16 14.65 83.991 75.481 o. *436 62.212 803525.0 -18.856 0.056 -22.014 0.065 803901.1 0 18.50 22 32 65.12 111. 66 83.984 75.437 o. 1135 62.212 803537.0 -18.922 0.056 -21.995 0.065 803901. 5 ::i rt 18.75 22 47 66.84 ilt.66 83.909 711. 883 0. 1127 62.198 80357'1. 9 -*18.803 0.056 -21. 796 0.065 803900.7 19.00 23 2 66.10 14.65 83. 711Ji 75.0lt1 O.'i30 62.175 8031180. 5 -19.062 0.056 -21. 990 0.065 803902.4 19.25 23 17 66.89 llt.65 83.557 75.146 o. 1131 62. 1119 8031101. 8 -19.596 0.058 -22.513 0.067 803905.9 19.50 23 32 65.41 1'1. 611 83. 1109 711. 331 o. 1120 62.127 803490.1 -19.727 0.058 -22.573 0.067 803906.7 19.75 23 47 66.66 14.63 83.381 711. 432 o. 1121 62.126 8031192. 9 -19.819 0.059 -22. 5911 0.067 803907.3 20.00 0 2 66.51 111. 611 83.239 711. 320 o. 1119 62.1011 8031141.1 -20.078 0.059 -22.799 0.068 803909.1 20.25 0 17 66. 611 14.65 83. 1'13 73.959 o. l1111 62.093 803511. 1 -20.047 0.059 -22.701 0.067 803908.9 20.50 0 32 66.19 14.65 83.186 711.175 0.417 62.099 8031t87.1 -20.085 0.059 -22.674 0.067 803909.1 20.75 0 "7 66.13 14.65 83.1119 74.207 0. 1118 62.096 8031195. 9 -20.073 0.059 -22.599 0.067 803909.1 21..00 1 2 66.71 1it.65 83.190 74.393 0.421 62.100 8031t47.8 -20.206 0.060 -22.677 0.067 803910.0 21. 25 1 17 66.76 14.65 83.206 711. 551 O.it23 62. 10.3 8031140. 9 -20.337 0.060 -22.753 0.067 803910.9 21. 50 1 32 66.66 111. 65 83.211 73.882 0.413 62.105 803575.3 -20.011 0.059 -*22. 1100 0.066 803908.6 21. 75 1 47 66.'t6 111. 66 83.187 73.952 o. 4111 62.102 803558.9 -19. 7112 0.058 -22.097 0.065 803906.6 22.00 2 2 66.10 111. 65 83.141 74.060 0.1116 62.094 803508.5 -19.631 0.058 -21.935 0.065 803905.8 22.25 2 17 66.15 l't. 65 83.014 711. 063 0.416 62. 0711 8031133. 8 -19.737 0.058 -21.992 0.065 803906.6 22.50 2 32 67.86 14.66 82.861 73.422 O.'t07 62.053 803506.6 -19.607 0.058 -21.817 0.065 803905.6 22.75 2 it7 67.40 14.66 82.805 73.638 0. 1110 62.047 80311611.1 -19.594 0.058 -21. 755 0.064 803905.5 23.00. 3 2 67.93 1'1. 66 82.780 73.500 O.'i08 62. 0113 8031174. 3 -19.539 0.058 -21.654 o. 0611 803905.1 23.25 3 17 67.91 14.66 82.824 73.3't8 o. 1106 62.049 803521. 8 -19.3114 0.057 -21. 1125 0.063 803903.5 23.50 3 32 67.76 1't.65 82.863 73.552 0.409 62.058 803532.1 -19.121 0.057 -21.173 0.063 803901. 8 23.75 3 117 67. 112 14.65 83.032 73.932 o.1111t 62.082 803536.3 -18.888 0.056 -20. 91.it 0.062 803899.9 24.00 4 2 68.18 14.65 83.111 74.571 0.423 62.092 8034311. 1 -18.866 0.056 -20.820 0.062 803899.3 -PAGE 1 TEST STARTING DAY 223 READ TIME Hours CALC LEAf( F(ATE Lbm/Hr /./Day F'SE&G RESEA. CQF(F'. RESEARCH & TESTI

  • LABORATORY SALEM N0.1 INTEGRATED LEAK RATE TEST REGRESSION ANALYSIS DATA CALC INITIAL AIR MASS STD DEV OF MASS STD DEV OF SLOPE Lbm Lbm Lbm/Hr STUDENT-T DIST. VALUE DATE 8/12/1979 TEST STARTING TIME 95% CONF. FIGURE Lbm/Hr /./Day 11/ 2 3.00 3.25 3.50 3.75 * 00 4.25 11. 50 4.75 5.00 5.25 5.50 5.75 6.00 6.25 6.50 6.75 7.00 7.25 7.50 7.75 8.00 8.25 8.50 8.75 9.00 9.25 9.50 9.75 10.00 10.25 10.50 10.75 11. 00 11.25 11. 50 11. 75 12.00 12.25 12.50 12.75 13.00 13.25 13.50 13.75 111. 00 1A.25 !A.SO 111. 75 15.00 15.25 15.50 -21.632 -17.221 -26.237 -*28. 166 -29.971 -33.752 -311. 288 -37.152 -31. 9112 -31.926 -26.363 -27.757 -26.155 -23.670 -18.521 -13.777 -11. 809 -11.140 -10.022 -8.369 -7.379 -*7. 330 -6.073 -5.230 -3.553 -1. 379 -1.042 -2.003 -3.982 -5.166 -5.114 -5.258 -7.247 -7.961 -8.080 -8.449 -9.076 -9.700 -10.750 -11.234 -11. 943 -11.981 -12.676 -13.091 -14.677

-14.682 -14.329 -15.211 -15.727 -16.090 -16.805 o. 0645 0.05111 0.0783 o. 08110 0.0894 0.1007 0.1023 o. 1109 0.0953 0.0953 0.0787 0.0828 0.0780 0.0706 0.0552 o. 01111 0.0352 0.0332 0.0299 0.02'+9 0.0220 0.0218 0.0181 0.0156 0.0106 0.00111 0.0031 0.0059 0.0118 0.015A 0.0152 0.0157 0.0216 0.0237 o. 02111 0.0252 0.0270 0.0289 0.0320 0.0335 0.0356 0.0357 0.0378 0.0390 0. 01138 o. 01138 0.0427 0.0454 o. 01169 o. 01180 0.0501 803885.5 803880.4 803891. 7 803894.2 803896.8 B03902.5 803903.3 803908.1 B03899.0 803898.9 803888.3 803891.1 803887.7 803882.3 803870.8 803859.7 803854.9 803853.3 803850.4 80381t6.0 8038113. 2 803843.1 803839. 11 803836.9 803831. 7 803824.8 803823.8 803827.0 803833.7 803837.9 I 803837. 7 803838.2 8038115. 7 803848. 11 8038't8.9 803850.3 803852.9 803855.5 803860.0 803862.1 803865.2 803865. '1 803868.5 803870.5 803878.0 803878.0 803876.3 803880.7 803883.3 803885.2 803889.0 58.53 56. 117 57.52 55.45 53.65 52.99 51. 34 50 .. 77 53.02 51. 60 55.68 511. 71 511. 03 51,.110 60.36 65.31 65.19 64.12 63.42 63.A4 62.82 6L80. 61. 71 61.20 62.15 611. 56 63. 711 63.62 66.15 66.57 65.74 64.95 68.58 68.37 67.60 67.03 66.86 66.75 67.8A 67.54 67.77 67.11 67. 4'1 67.17 72. 08 71.A2 71.08 72.40 72.A6 72. 21 73.06 19.58 16.7'i 15.25 13.25 1.1. 64 10. 1,9 9.33 8.50 8.22 7.43 7.1+8 6.88 6.37 6.03 6.31 6. 115 6.10 5.69 5.35 5.09 4.81 11. 51 11. 31 4.09 3.98 3.97 3.77 3.62 3.62 3.51 3.34 3.19 3.25 3.13 3.00 2.88 2.78 2.69 2.65 2.57 2.50 2.A1 2.35 2 .. 28 2.38 2.30 2.23 2.21 2.16 2.10 2.07 2.225 2.198 2.177 2.159 2.1A3 2. 1.30 2.119 2.l.09 2.100 2.092 2.085 2.079 2.073 2.068 2.063 2.059 2.055 2.051 2.048 2. 0115 2. 0112 2.039 2.036 2.03A 2.032 2.030 2.028 2.026 2.02A 2.022 2.021 2.019 2.018 2.016 2.015 2. 0111 2.012 2. 011 2.010 2.009 2.008 2.007 2.006 2.005 2. 0011 2.00lt 2.003 2.002 2.001 2.000 2.000 -65.208 -511. 040 -59.1+49 -56.791 -511. 925 -56. 111t -511. 062 -55.097 -49.217 -lt7.493 -111. 975 -112. 064 -39.371 -36. 1511 -31. 552 -27.072 -21t. 3118 -22.820 -20.98A -18.792 -17.205 -16. 5118 -111. 862 -13.565 -11.659 -9.1151 -8.692 -9.339 -11. 320 -12.275 -11. 880 -11. 706 -13.819 -1"1. 291 -111.133 -14.256 -!lt.685 -15.126 -16.097 -16.399 -16. 9711 -16.820 -17.lt03 -17.669 -19.A56 -19.29.1 -18.796 -19.6115 -20.053 -20.293 -20.951t 0.19116 0.1613 0.17711 0.1695 0.1639 0.1675 0.1613 0.1644 0.1A69 0.1417 0.1253 0.1255 0.1175 0.1079 0.09A2 0.0808 0.0726 0.0681 0.0626 0.0561 0.0513 0.0491t o. 04113 0.0405 o. 03118 0.0282 0.0259 0.0278 0.0337 0.0366 0.0354 o. 031,9 0.041.2 o. 01126 0.0421 0.0425 o. 01138 o. 01151 o. 01180 0.0489 0.0506 0.0502 0.0519 0.0527 0.0580 0.0575 0.0561 0.0586 0.0598 o. 0605 0.0625 ! f 1' e .,t e e . *r',, *-** F'SE&G RESEARCH CORP. PAGE 2 RESEAf(CH ix TESTING LAGOF(ATORY DATE 8/12/1979 SALEM N0.1 INTEGRATED LEAf( RATE TEST TEST STARTING DAY 223 REGRESSION ANALYSIS DATA TEST STARTING TIME 4/ 2 READ CALC CALC STD DEV STD DEV STUDENT-T 95/. CONF. TIME LEAf( INITIAL OF MASS OF SLOPE DIST. VALUE FIGLJF(E F(ATE Arn MASS Hours Lbm/Hr /./Day Lbm Lbrn Lbrn/Hr Lbrn/Hr /./Day -------------------------------------------------------------------------------------------------------------- 15.75 -16.821 0.0502 803889.1 72.46 2.00 1. 999 -20.837 0.0622 16.00 -16.893 0.0504 803889.4 71.89 1. 911 1.998 -20.783 0.0620 16.25 -16.585 0.0495 803887.7 71. 64 1.89 1.998 -20.371 0.0608 16.50 -16.528 0.0493 803887.4 71. 09 1. 83 1. 997 -20.199 0.0603 16.75 -16.825 0.0502 803889.1 70.86 1. 79 1. 997 -20.lt02 0.0609 17.00 -17.lt16 0.0519 803892.5 71. 66 1. 77 1.996 -20.952 0.0625 17.25 -17.996 0.0537 803895.9 72.lt6 1. 75 1.99Jj -21. lt93 0.0641 17.50 -18.186 o. 05112 803897.0 72.08 1. 70 1.995 -21.589 o. 06411 17.75 -18.515 0.0552 803899.0 72. 02 1.66 1. 9911 -21. 811ft 0.0652 18.00 -18.706 0.0558 803900.2 71.67 1. 62 1. 9911 --21. 9118 0.0655 18.25 -18.856 0.0562 803901. 1 71.27 1. 58 1.993 -22.01'1 0.0657 --.l 18.50 -18.922 0.0561t 803901. 5 70.80 1. Sit 1.993 -21.995 0.0656 18.75 -18.803 0.0561 803900.7 70.38 1.50 1.992 -21. 796 0.0650 19.00 -19.062 0.0569 803902. 11 70.27 1.lt6 1.992 -21. 990 0.0656 H I:"' 19.25 -19.596 0.0585 803905.9 71. 110 1. 116 1.992 -22.513 0.0672 ?:J 19.50 -19.727 0.0588 803906.7 71. 03 1. lt2 1. 991 -22.573 0.0673 t-3 19.75 -19.819 0.0591 803907.3 70.61 1.39 1. 991 -22.591t 0.0671t >' 20.00 -20.078 0.0599 803909.1 70.58 1. 36 1.990 -22.799 0.0680 t-3 20.25 -20.047 0.0598 803908.9 70.11t 1. 33 1.990 -22.701 .0.0677 l:rj trl 20.50 -20.085 0.0599 803909.1 69.71 1.30 1. 990 -22. 6711 0.0676 1-] 20.75 -20.073 0.0599 803909.1 69.28 1. 26 1. 989 -22.599 0.067'1 ::;:! 21. 00 -20.206 0.0603 803910.0 68.99 1. 2'1 1. 989 -22.677 0.0677 i:rj Gl 21.25 -20.337 0.0607 803910.9 68.71 1. 21 1. 988 -22.753 0.0679 ?:! l:rj 21. 50 -20. 011 0.0597 803908.6 69.15 1.20 1. 988 -22.1100 0.0668 trl trl 21. 75 -19.71t2 0.0589 803906.6 69.31t 1.18 1. 9f:l8 -*22. 097 0.0659 H 22.00 -19.631 0.0586 803905.8 69. 011 1.15 1.987 -21. 935 0.0651t 0 z 22.25 -19.737 0.0589 803906.6 68.71t 1.13 1.987 --21. 992 0.0656 0 22.50 .-19. 607 0.0585 803905.6 68.50 1. 11 1. 987 -21.817 0.0651 >' 22.75 -19.591t 0.0581t 803905.5 68.12 1. 08 1. 986 -21. 755 0. 061t9 t-3 >' 23.00 -19.539 0.0583 803905.1 67.77 1. 06 1.986 --2l.. 651t o. 06116 23.25 -19. 31t't 0.0577 803903.5 67.79 1. Oft 1.986 -21.lt25 0.0639 23.50 -19.121 0.0570 803901.8 67.95 1. 03 1. 986 -21.173 0.0632 n 0 23.75 -18.888 0.0563 803899.9 68.18 1. 02 1. 985 -20.911t o. 062'1 ::i rt 24.00 -18.866 0.0563 803899.3 67.83 0.98 1.985 -20.820 0.0621 -°'


PAGE ' '1! F'SE!XG e . ' 1 RESEAF(CH 5'. TEST!

  • AGORATORY DATE 8/12/1979 SALEM N0.1 INTEGRATED RATE TEST '-. TEST STAFnING DAY 223 AVERAGE & MASS DATA TEST STARTING TIME" 4/ 2 READ REAL JULIAN AMGIENT AVG AVG CALC AVG CONTMT DIFF DIFF TIME TIME DATE TEMP PRESS CONTMT CDNTMT VAPOR CONTMT MASS MASS MASS TEMP DEW F'T PRESS PRESS CF'-T-P> CTOT TIME> <Hrs) <Hr/Min) <DegF) <Psia) <DegF> <DegF> <Psia) (F'sia) <Lbm> CLbm> CLbm) ---------------------------------------------------------------------------------------------------------------

0.00 4 2 223 79.841 14. 7119 811. 997 76.660 0.11511 62.371 803879. o.o o.o 0.25 4 17 223 80.455 14.745 84.973 77.091 O.lt60 62.366 803757. -121. 2 -121.2 0.50 4 32 223 79.355 14. 7'19 8'1. 933 76.405 0.450 62.362 80390'1. 147.2 25.9 0.75 4 '17 223 80.208 14. 7411 84.901 76.497 0.451 62.359 803887. -17.3 8.6 1. 00 5 2 223 79.980 l.4.744 8'1. 88'1 76.420 o. /150 62.355 803882. -4.6 3.9 1.25 5 17 223 79. 6'13 1'1.743 84.859 76.1811 o. 4'16 62.352 803919. 36.5 40.4 1. 50 5 32 223 78.780 1'1.745 84.824 76.139 0. 11116 62. 3116 803906. -12.5 27.9 1. 75 5 '17 223 77.839 1'1. 746 811. 785 76.16" o. 11116 62.342 803901. -5. '1 22.5 2.00 6 2 223 78.612 111. 7'111 811. 767 76. 671. o. '1511 62.337 803769. -132.0 -109.11 -.J 2.25 6 17 223 78.830 14.747 811. 729 76.335 0.'149 62.334 803851. 82.1 -27.3 U1 2.50 6 32 223 79. 772 111. 7117 811. 725 76.315 o. 1148 62.330 803802. -48.9 -76.3 2.75 6 47 223 79.425 14.749 84.680 76.129 o. 11116 62. 3211 803839. 36.9 -39.3 H 3.00 7 2 223 79.167 14.7119 811. 6111 76.363 0.449 62.3:1.9 803780. -59.3 -98.7 t< 3.25 7 17 223 79.573 111. 749 811. 589 75.892 0.442 62.311 8038'+8. 68.4 -30.2 >-3 3.50 7 32 223 79. 5411 14.750 84.556 76.363 0.'149 62.306 803741. -107.4 -137.7 :::-3.75 7 117 223 79.345 111. 7'19 84.526 76.189 0.447 62.303 803774. 32.7 -105.0 1-3 4.00 8 2 223 79.266 1'1. 7118 811 .* 505 76.180 0.4116 62.299 803761. -12.8 -117.8 trl Ul lt.25 8 17 223 79.910 14.752 8'+.470 76.246 0.447 62.293 803721. -39.9 -157.7 1-3 4.50 8 32 223 80.921 111. 752 811.418 76.190 o. '1'17 62.288 803742. 21. 7 -136.0 :::-4.75 8 '17 223 81.1'19 14.756 811. 396 76.337 0.449 62. 2811 803695. -47.8 -183.8 <: trl 5.00 9 2 223 82.071 111. 756 811. 369 75.754 0.440 62.282 803813. 118.4 -65.4 5.25 9 17 223 81. 655 1'1. 757 811. 364 76.155 0. 1116 62.281 803731. -81. 9 -1117. 3 G'l 5.50 9 32 223 82.467 111. 754 811. 353 75.631 0.438 62.280 8038110. 109.0 -38.3 M 5.75 9 47 223 83.627 14.755 811. 368 76.36l. 0.449 62.282 803704 *. -135.9 -1711. 3 :::-6.00 10 2 223 83.785 1.4. 758 811. 3811 76.169 0.4'+6 62.286 803764. 59.9 -114.4 z tl 6.25 10 17 223 8'1. 876 14.757 8'1. 411 76.097 o. 4'15 62.290 803791. 26.9 -87. 11 6.50 10 32 223 85.758 llt.762 84. 4811 75.756 0.440 62.300 803879. 87.5 0.1 6.75 10 '17 223 85.559 14. 76'1 811. 5'10 75.892 0.442 62. 300 803895. 16.0 16.1 Ul Ul 7.00 11 2 223 85.520 14.769 84.603 76.223 o. 4117 62.316 803829. -65.3 -49.1 tl 7.25 11 17 223 86.21'1 14.768 8!.1. 660 76.519 0.451 62. 3211 803793. -36.2 -85. 11 . >' 7.50 11 32 223 '86.124 14. 772 84.730 76.1193 0.451 62. 3311 803813. 19.4 -65.9 1-3 >' 7.75 11 47 223 86.907 111. 773 81t.782 76.1196 0.451 62.342 803841. 27.9 -37.9 8.00 1'"' .:.. 2 223 87.542 14.775 811. 805 76.586 0.452 62. 31111 803822. -18.4 -56.3 8.25 12 17 223 88.136 14.776 811. 806 76.670 0.454 62. 3113 803784. -37.9 -94.3 8.50 12 32 223 87.651 14.777 8'1. 788 76.269 0.448 62.339 8038113. 58.5 -35.8 8.75 12 47 223 88.533 111.777 84.772 76.323 0. 1149 62.337 803830. -12.5 -48.4 9.00 13 2 223 88.255 14.776 84.781 76.115 o. 1145 62.339 803882. 52.3 3.9 9.25 13 17 223 88.751 111. 778 84.791 75.886 0.442 62.340 803926. 43.3 47.2 9.50 13 32 223 89.078 14.782 8'1.812 76.347 0.449 62. 3112 803832. -93.7 -46.4 9.75 13 117 223 89.187 14. 7811 84.825 76.700 o. 4511 62. 3113 803751. -81.3 -127.8 10.00 14 2 223 89.722 14.787 811.812 77.063 0. 1160 62. 3'11 803671. -79.4 -207.3 10.25 14 17 223 89.167 14.787 811. 790 76.915 0.457 62.339 803708. 36.3 -171. 0 10.50 1'1 32 223 86.957 111.788 84.801 76.358 0.449 62.338 803787. 79.5 -91.4 10.75 111 117 223 78.116 14.786 84.811 76.435 0.450 62.339 803771. -16.1 -107.6 11.00 15 2 223 76.769 14.786 811.819 77.225 o. '162 62. 3110 803616. -155.0 -262.6 11. 25 15 17 223 72.814 1'+. 767 84.837 76.723 o. 1154 62.341 803702. 86.2 -176.4 11. 50 15 32 223 76. 0115 14 .. 769 84.839 76.415 0.450 62.340 803746. '13. 5 -132.8 11. 75 15 47 223 77.859 14.764 811. 820 76.532 0.452 62.337 803719. -26.8 -159.7 12.00 16 2 223 77.224 14:761 811. 856 76.792 0.456 62. 3113 803687. -31. 7 -191.'1 12.25 16 17 223 79.108 111. 751 8'1. 890 76.886 o. 1157 62.347 803678. -9.5 -200.9 12.50 16 32 223 76.719 111. 7'19 84.903 77. 266 0.463 62.350 803622. -55.3 -256.3 r:* ,q:' *,'.** :j': ., ,jo* .;1 'I ---------------------------------------------- -PAGE F'SE&G RESEAi.CORP. e 2 RESEARCH & TESTIN* ABORATORY DATE 8/12/1979 SALEM N0.1 INTEGRATED LEAH r\ATE TEST TEST STARTING DAY 223 AVrnAGE & MASS DATA TEST STARTING TIME 11/ 2 READ REAL JULIAN AMBIENT AVG AVG CALC AVG CONTMT DIFF DIFF TIME TIME DATE TEMP PRESS CONTMT CONTMT VAP@ CONT MT MASS MASS MASS TEMP DEW PT F't\ESS PRESS <P-T-P) <TOT TIME) <Hrs) <Hr/Min) <DegF) <Psia) <DegF) <DegF> (Psia) <Psia) <Lbm) (Lbm) <Lbm) -------------------------------------------------------------------------------------------------------------- 12.75 16 47 223 72.983 14.71t7 811. 921 76.927 O.lt58 62.351 803669. '16. 7 -209.5 13.00 17 2 223 71.298 111.736 8ft.907 76.979 O.lt58 62. 3'17 8036311. -311. 7 -2114. 2 13.25 17 17 223 70.505 1'** 729 81t.8ft9 76.499 o. 1151 62.339 803702. 67.6 -176.5 13.50 17 32 223 68.652 1'1. 731 811. 771 76.750 0.455 62.327 803617. -84.8 -261.4 13.75 17 47 223 67 n 9118 1'1. 731 811. 689 76. 1107 o. 1150 62.314 803641. 23.5 -237.9 ift. 00 rn 2 223 69.028 111. 725 84.634 77. 060 o. 1160 -62.305 803476. -164.7 -402.7 14.25 18 17 223 70.396 14.726 84.580 75. 9:l2 o .. 442 62.297 803668. 191. 9 -210.7 111. 50 18 32 223 69.157 111. 7211 811. 515 75.654 0.439 62.289 803715. 47.2 -163.11 -.J 14.75 18 117 223 68.880 1.4. 728 84. 1,73 76.i139 0.450 62.282 8035311. -180.7 -3114. 2 U1 15.00 19 2 223 69.226 lit. 722 811. 1146 76.208 o. 4117 62.279 803573. 39.0 -305.1 15.25 19 17 223 67.066 1'1. 721 84.413 76.092 o. 1145 62.27ft 803586. 12.5 -292.5 H t:"' 15.50 19 32 223 68. 3311 111. 716 84.380 76.2'17 o. 11117 62.267 803519. -66.9 -359.5 :>;:! f-3 15.75 19 117 223 66.858 111.711 84. 31,9 75.675 0.439 62.263 803621. 102.0 -257. 11 16.00 20 2 223 65.926 14.704 811. 314 75. 711 o. 1139 62.259 803607. -14.0 -271.5 16.25 20 17 223 6'!.291 1'1. 690 84.267 75.267 0.433 62.252 803670. 62.6 -208.9 f-3 t'1 16.50 20 32 223 63.409 14.684 84.233 75.392 O.lt35 62. 2116 8036211. -45.4 -254.4 (fl 16.75 20 ft? 223 63.666 111. 677 84.186 75.680 0.439 62. 2110 803551t. -70. 11 -324.8 f-3 17.00 21 2 223 64.727 14.676 84.135 75.838 0.441 62.231 803487. -66. 11 -391. 3 < 17.25 21 17 223 65. 1121 111. 677 84.029 75.690 o. 1139 62.216 803475. -12.2 -403.6 t'1 17.50 21 32 223 65.123 111. 672 83.957 75.141 0.431 62.205 803541. 66.2 -337.3 17.75 21. 117 223 65.906 14.671 83.930 75.338 0.434 62.202 8035011. -37.6 -374.9 G) l:tj 18.00 22 2 223 66.987 14.665 83.950 75.325 o. 11311 62.205 8035211. 19.9 -355.0 18.25 22 17 223 66. 1611 14.659 83.991 75.1181 o. '136 62.212 803525. 1. 0 -3511. 0 >* z 18.50 22 32 223 65.123 14.662 83. 9811 75. 1137 0.435 62.212 803537. 11. 9 -342.0 tJ 18.75 22 47 223 66. 8118 14.662 83.909 74.883 0.427 62.198 803574. 37.9 --304. 0 19.00 23 2 223 66.105 14.656 83. 7411 75.041 0.430 62.175 8031180. -94. 11 -398.5 (fl 19.25 23 17 223 66.897 111. 650 83.557 75.146 0.431 62.1119 8031101. -78.6 -1177. 1 (fl 19.50 23 32 223 65.1111 14.641t 83.409 ?lt.331 0.420 62.127 803490. 88.2 -388.9 tJ 19.75 23 117 223 66.660 111. 637 83.381 74.1132 o. 1121 62.126 803492. 2.8 -386.0 f-3 20.00 0 2 224 66.511 1'1. 6115 83.239 74.320 0.419 62.1011 80341t1 .* -51. 7 -437.8 ::> 20.25 0 17 22'* 66. 6110 14.652 83.143 73.959 O.lt14 62.093 803511. 70.0 -367.8 20.50 0 32 224 66.194 111. 653 83.186 74.175 0.417 62.099 803487. -23.9 -391. 8 n 20.75 0 It? 22't 66.1311 14.650 83.149 711.207 0.418 62.096 803495. 8.7 -383.1 0 ::i 21. 00 1. 2 224 66.719 14.651 83.190 711.393 0.421 62.100 8034117. -48.1 -1131. 2 rT 21.25 1 17 224 66.769 1'1. 658 83.206 74.551 0.423 62.103 8034110. -6.8 -438.1 -p, 21. 50 1 32 2211 66.669 111.650 83.211 73.882 0.413 62.105 803575. 134.4 -303.6 21. 75 1 47 224 66.461 1'1. 661 83.187 73.952 0.414 62.102 803558. -16.3 -320.0 22.00 2 2 224 66.105 111. 659 83.11t1 74.060 0.416 62.094 803508. -50.3 -370.4 22.25 2 17 224 66.151t 14.657 83.01'1 74.063 0.416 62.074 803433. -74.7 -11115. 1 22.50 2 32 224 67.869 llt.661 82.861 73.422 0.407 62.053 803506. 72. 7 -372.3 22.75 2 47 224 67.1103 14.661 82.805 73.638 0.1110 62.047 80346 1 1. -42.4 -1114.8 23.00 3 2 224 67.938 1/i.661 82.780 73.500 o. 1108 62. 0113 8031174. 10.1 -1104. 6 23.25 3 17 224 67.918 1'+.663 82. 8211 73. 3118 o. 1106 62.049 803521. 47.5 -357.1 23.50 3 32 22'* 67.760 111.655 82.863 73.552 o. 1109 62.058 803532. 10.2 -3116. 8 23.75 3 Ii? 224 67.1123 111.650 83.032 73.932 o. 'i1'1 62.082 803536. '1. 2 -342.6 24.00 11 2 224 68.186 1'1. 650 83.111 74.571 O.'i23 62.092 803113'+. -102.1 -'i44.8 -PAGE 1 TEST STARTING DAY 223 READ REAL TIME TIME &. DAY 0.00 I+ 2 223 0.25 11 17 223 0.50 I+ 32 223 PRESS AMBIENT SENS TEMP PI-1 &. PI-2 PRESS 62.265 79.81+1 62.1+78 11+. 7'19 62.259 80.1+55 62.1173 11+. 71,5 62.256 79.355 62. 1169 11+. 71+9 0.75 I+ 1+7 62.252 80.208 223 62.466 11+.741+ 1.00 5 2 62.21+8 79.980 223 62.1+63 11+.71+1+ 1.25 5 17 62.21+5 79.61+3 223 62.459 11+.743 1.50 5 32 62.21+0 78.780 223 62.1+53 11+.71+5 1.75 5 1+7 223 2.00 6 2 223 2.25 6 17 223 2.50 6 32 223 2.75 6 47 223 3.00 7 2 223 62.235 77.839 62. 11/+8 111. 71+6 62.230 78.612 62. 4411 14. 71111 62.227 78.830 62.ft41 14.71+7 62.223 79.772 62. 1136 14. 7117 62. 218 79. 1125 62. 1131 14. 7119 62.213 79.167 62.425 1'!.71+9 1 9 17 PSE&.G RESEARCH &. TESTI

  • ABORATORY SALEM N0.1 INTEGRATED LEAK RATE TEST SENSOR READINGS TEMPERATURE SENSORS CRTD'S) 2 3 I+ 5 6 10 11 12 13 14 18 19 20 21 22 7 15 23 8 16 24 84.606 85.120 85.426 85.097 85.320 85.325 85.428 84.980 85.026 85.067 84.842 84.907 84.818 85.392 85.517 84.819 85.242 84.830 82.741 85.100 84.892 85.109 84.888 77.223 84.5ft7 85.060 85.4ft6 85.038 85.360 85.31+5 85.359 85.019 84.996 85.047 84.852 84.887 84.748 85.322 85.467 84.829 85.183 84.801 82.790 85.051 84.912 85.109 84.878 77.232 81+.517 85.020 85.3ft7 85.058 85.191 85.276 85.340 85.019 85.006 84.968 84.762 84.867 84.698 85.283 85.467 84.780 85.183 84.791 82.651 85.070 84.843 85.049 81+.869 77.213 84.517 85.020 85.366 84.988 85.241 85.276 85.350 84.980 84.837 85.028 84.772 84.827 84.698 85.273 85.427 84.760 85.153 84.751 81.232 85.001 84.862 85.059 84.839 77.262 84.467 85.010 85.307 84.948 85.152 85.216 85.340 84.910 84.827 84.928 84.802 84.837 84.639 85.193 85.397 84.720 85.163 84.741 82.880 85.011 84.813 85.030 84.809 77.302 84.448 84.980 85.287 84.948 85.112 85.206 85.232 84.930 84.877 84.899 84.743 84.797 84.629 85.193 85.387 84.700 85.113 84.721 82.383 85.001 84.803 85.020 84.780 77.332 84.A08 84.921 85.297 84.898 85.073 85.127 85.261 84.880 84.777 84.899 84.683 84.727 84.659 85.173 85.348 84.661 85.103 84.671 82.463 84.942 84.754 84.980 84.760 77.322 84.388 84.881 85.257 84.868 85.043 85.058 85.203 84.840 84.737 84.819 84.673 84.727 84.569 85.114 85.298 84.611 84.642 82.493 84.922 84.744 84.950 84.740 77.332 84.348 84.871 85.157 84.819 85.023 85.098 85.163 84.771 84.787 84.859 84.623 84.697 84.559 85.124 85.308 84.601 85.043 84.622 82.572 84.882 84.704 84.930 84.730 77.362 84.319 84.811 85.177 84.819 85.023 85.018 85.154 84.781 84.708 84.769 84.584 84.677 84.460 85.074 85.238 84.601 84.994 84.592 82.512 84.862 84.704 84.910 84.671 77.382 84.309 84.811 85.197 84.829 85.043 85.048 85.095 84.761 84.747 84.760 84.594 84.598 84.549 85.074 85.218 84.551 85.004 84.562 82.413 84.862 84.645 84.900 84.651 77.391 84.269 84.741 85.138 84.789 84.993 84.989 85.085 84.701 84.598 84.789 84.524 84.618 84.460 85.024 85.188 84.512 84.944 84.532 82.413 84.783 84.625 84.880 84.641 77.431 84.229 84.761 85.088 84.709 84.884 84.959 85.026 84.642 84.618 84.700 84.484 84.538 84.490 84.955 85.158 84.482 84.914 84.473 82.612 84.763 84.595 84.821 84.611 77.451 DATE 8/12/1979 TEST STARTING TIME ft/ 2 DEW POINT SENSORS 1 2 3 4 5 6 78.004 77.083 0.000 77.139 73.966 74.665 77.396 77.645 0.000 77.501 75.538 75.479 77.568 77.600 0.000 76.314 75.382 74.778 77.387 77.163 0.000 76.912 73.884 75.015 77.214 77.571+ 0.000 76.477 74.895 75.102 76.097 78.350 0.000 76.01+2 75.216 75.129 76.924 76.976 0.000 76.223 74.830 74.901 77.659 77.145 o.ooo 76.160 74:56ft 74.533 76.088 77.208 0.000 77.347 75.106 74.945 76.615 77.279 o.ooo 76.432 75.566 75.015 76.851 77.672 0.000 76.241 75.198 75.313 76.579 77.368 o.ooo 76.241 75.023 74.463 76. 606 77. 815 o. 000 -76.695 74.058 74.796 PSE&G F\ESEA 0-'0F\P. 2 DATE 8/12/1979 TEST STARTING DAY 223 RESEARCH &

SALEM N0.1 INTEGRATED LEAK RATE TEST SENSOR READINGS TEST STARTING TIME 4/ 2 READ f\EAL TIME TIME & DAY PRESS SENS PI-1 PI-2 AMBIENT TEMP & PRESS 1 9 17 TEMPERATURE SENSORS CRTD'S) 2 3 4 5 6 10 11 12 13 14 18 19 20 21 22 7 15 23 8 16 2'1 DEW POINT SENSORS 1 2 3 ,, 5 6 -------------------------------------------------------------------------------------------------------------- 3.25 7 17 223 3.50 7 32 223 3.75 7 47 223 4.00_ 8 2 223 ft.25 8 17 223 It.SO 8 32 223 * 75 8 47 223 5.00 9 2 223 5.25 9 17 223 5.50 9 32 223 5.75 9 '+7 223 6.00 10 2 223 6.25 10 17 223 62.205 79.573 62.417 14.749 62. 200 79. 5114 62. 412 1'1. 750 62.197 79.345 62.408 1'+.7'+9 62.193 79.266 62.1105 1'1.7'18 84.130 8'+.701 84.988 84.630 84.815 84.900 84.977 84.671 84.628 84.660 84.445 84.468 84.380 84.905 85.129 84.432 8'+.874 8'+.433 82.493 8'+.704 84.556 84.791 84.562 77.382 84.110 84.632 84.978 84.600 84.815 84.900 84.957 84.622 84.469 84.640 84.405 84.438 84.410 84.915 85.079 84.402 84.845 8'+.393 82.195 84.664 84.536 84.751 84.552 84.100 84.612 84.958 84.570 84.805 84.781 84.918 84.502 84.519 84.571 84.365 84.508 84.360 84.816 85.039 84.372 84.835 84.373 82.235 84.654 84.526 84.731 84.522 77.560 84.061 84.622 84.948 84.580 84.775 84.860 84.928 8'+.493 84.439 84.54l. 84.345 84.448 84.261 84.846 85.019 84.323 84.775 84.353 82.304 84.654 8'+.'+57 84.691 84.483 77.540 62.187 79.910 84.041 84.552 84.938 84.530 84.736 84.850 84.879 84.453 62.399 14.752 84.419 84.541 84.336 84.379 84.251 84.786 84.979 84.293 84.745 84.284 82.324 84.575 8'+.'+37 84.652 84.453 77.560 62.182 80.921 83.981 84.472 84.849 84.441 84.657 84.692 84.771 84.423 62.394 1'+.752 84.419 84.452 84.306 8'+.319 84.241 84.756 84.949 84.243 84.725 84.254 82.254 84.555 84.398 84.652 84.43'+ 77.650 62.178 81.149. 83.941 84.472 84.839 84.401 84.676 84.731 84.742 84.463 62.390 14.756 84.390 84.412 84.256 84.319 84.171 84.746 84.899 84.214 84.685 84.244 82.215 84.505 8'+.348 84.622 8'+.39'+ 77.610 62.175 82.071 83.941 84.452 84.779 84.431 84.587 84.692 84.722 84.'+33 62.388 14.756 84.360 84.402 84.177 84.269 84.142 84.697 84.899 84.204 84.214 82.2'+5 84.515 84.368 84.612 84.384 77.570 77.831 77.931 o.ooo 75.670 73.'+89 74.166 75.843 75.601 o.ooo 77.520 74.435 7'+.24'+ 76.62'+ 77.761 o.ooo 76.405 74.159 74.516 77.069 77.lt'+O 0.000 76.386 73.939 74.577 76.706 76.503 o.ooo 76.722 74.720 74.'+72 76.152 76.7'+4 0.000 76.586 75.097 7'+.647 75.843 78.127 0.000 77.012 73.590 74.043 76.106 77.600 0.000 75.661 74.711 74.367 62.17'1 81.655 62.387 14.757 83.922 8'+.452 84.759 84.'+'+1 8'+.587 84.642 8'+.791 8'+.363 76.'+33 77.'+93 0.000 8'+.340 8'+.'+02 8'+.187 84.269 8'+.191 8'+.716 8'+.870 84.194 76.368 7'+.830 7'+.297 8'+.656 84.20'+ 82.2'+5 84.505 8'+.338 84.572 8'+.345 77.650 62.17'+ 82.467 62. 386 14. 7511 62.176 83.627 62.388 1'+.755 62.179 83.785 62.392 1'+.758 62.183 8'+.876 62.396 14.757 83.932 8'+.'+52 8'+.769 8'+.371 84.627 84.623 84.712 8'+.373 77.577 77.136 0.000 8'+.290 8'+.382 8'+.206 84.239 8'+.181 84.716 84.880 84.164 75.426 73.167 74.577 8'+.6'+6 84.20'+ 82.215 84.496 84.358 84.572 84.354 77.640 83.9'+1 8'+.442 8'+.789 84.401 84.617 8'+.613 84.712 84.333 76.978 76.672 0.000 84.330 8'+.'+52 84.206 84.289 84.181 84.726 84.899 84.204 76.640 75.979 74.139 84.675 84.244 82.364 84.525 8'+.318 8'+.582 84.374 77.640 83.971 84.462 84.819 84.451 8'+.617 84.603 84.761 84.413 84.320 8'+.452 84.236 84.269 84.151 84.716 84.909 84.194 84.666 8'+.274 82.433 84.555 84.368 8'+.592 84.364 77.690 83.991 8'+.512 84.779 84.441 84.666 84.633 8'+.761 84.393 84.3'+0 84.402 8'+.336 84.329 84.261 84.786 84.929 84.253 84.705 8'+.314 82.453 84.575 84.368 84.612 84.40'+ 77.600 76.125 77.342 0.000 76.260 75.823 74.586 76.588 77.699 0.000 76.3'+1 74.270 73.964 -...! "' n 0 ::i rt p, -PAGE 3 TEST STARTING DAY 223 READ TIME REAL TIME &. DAY 6.50 10 32 223 6. 75 10 117 223 PRESS SENS PI-1 PI-2 AMBIENT TEMP &. PRESS 62.193 85.758 62.406 14.762 62.202 85.559 62.416 14.761+ 7.00 11 2 62.209 85.520 223 62.423 14.769 7.25 11 17 62.218 86.214 223 62.431 14.768 7.50 11 32 62.227 86.124 223 62.440 14.772 7.75 11 47 62.235 86.907 223 62.448 14.773 8.00 12 2 223 8.25 12 17 223 8.50 12 32 223 8.75 12 47 223 9.00 13 2 223 9.25 13 17 223 9.50 13 32 223 62.237 87.542 62. 452 111. 775 62.236 88.136 62.450 14.776 62.232 87.651 62.446 14.777 62.230 88.533 62.1144 14.777 62.232 88.255 62. 4116 14. 776 62.233 88.751 62. 4117 14. 778 62.235 89.078 62.450 14.782 1 9 17 F'SE&.G RESEA.COFW. RESEARCH&. TESTIN* A80RATORY SALEM NCl.1 INTEGRATED LEAK RATE TEST SENSOR READINGS 2 10 18 TEMPERATURE SENSORS 3 4 5 11 12 13 19 20 21 rnrn's> 6 22 7 15 23 8 16 211 84.080 84.592 84.849 84.580 84.716 84.722 84.889 84.473 84.419 84.501 84.415 84.329 84.311 84.836 84.989 84.323 84.745 84.423 82.542 84.684 84.447 84.642 84.453 77.540 84.160 84.652 84.889 84.620 84.785 84.731 84.928 84.572 84.519 84.531 84.375 84.418 84.340 84.915 85.059 84.392 84.795 84.512 82.592 84.773 84.516 84.691 84.513 77.540 DATE 8/12/1979 TEST STARTING TIME 4/ 2 DEW POINT SENSORS 1 2 3 4 5 6 76.506 76.289 o.ooo 76.178 73.066 74.673 76.007 76.565 o.ooo 76.241 74.224 74.796 84.219 84.731 84.978 84.669 84.825 84.840 84.967 84.622 77.005 77.600 0.000 84.568 84.611 84.504 84.468 84.410 84.955 85.119 84.452 76.133 75.134 74.927 84.864 84.562 82.691 84.823 84.566 84.761 84.572 77.471 84.279 84.781 85.028 84.709 84.874 84.880 85.055 84.691 . 75.889 77.511 0.000 84.618 84.700 84.544 84.488 84.509 85.024 85.158 84.512 76.903 75.713 74.945 84.904 84.632 82.770 84.912 84.585 84.801 84.621 77.471 84.348 84.861 85.108 84.819 84.954 84.949 85.124 84.731 77.151 77.199 o.ooo 84.658 84.720 84.683 84.598 84.539 85.104 85.238 84.581 76.903 74.426 74.735 84.974 84.731 82.810 84.961 84.665 84.870 84.661 77.441 84.428 84.881 85.138 84.859 85.013 85.009 85.163 84.831 76.234 77.431 0.000 84.698 84.750 84.762 84.648 84.599 85.153 85.258 84.641 77.003 74.775 74.822 85.033 84.801 82.850 85.041 84.724 84.920 84.740 77.362 84.457 84.931 85.197 84.898 85.053 85.009 85.203 84.840 84.688 84.829 84.753 84.638 84.619 85.163 85.278 84.661 85.024 84.791 82.959 85.060 84.754 84.930 84.760 77.461 84.428 84.891 85.177 84.908 85.043 85.078 85.203 84.821 84.757 84.849 84.733 84.638 84.589 85.173 85.308 84.661 85.043 84.791 82.969 85.001 84.773 84.950 84.760 77.421 84.398 84.861 85.167 84.849 85.043 85.048 85.193 84.801 84.708 84.779 84.743 84.638 84.599 85.143 85.298 84.631 85.024 84.761 82.989 85.041 84.744 84.930 84.760 77.471 84.388 84.841 85.177 84.809 85.023 84.999 85.154 84.840 84.678 84.769 84.653 84.648 84.619 85.104 85.278 84.621 85.024 84.741 83.068 85.021 84.714 84.910 84.760 77.531 84.408 84.871 85.147 84.829 84.993 84.999 85.163 84.771 84.747 84.799 84.673 84.608 84.599 85.153 85.298 84.601 85.033 84.791 83.108 85.041 84.773 84.950 84.760 77.481 84.408 84.871 85.167 84.819 85.082 84.979 85.183 84.821 84.737 84.740 84.713 84.677 84.589 85.134 85.298 84.651 85.033 84.801 83.128 85.041 84.783 84.930 84.780 77.461 84.438 84.881 85.147 84.868 85.063 84.979 85.183 84.840 84.767 84.819 84.723 84.648 84.619 85.193 85.328 84.680 85.053 84.821 83.217 85.080 84.803 84.960 84.809 77.451 77.777 78.413 o.ooo 76.396 75.189 74.962 77.795 76.440 0.000 77.248 74.196 75.111 77.477 77.074 o.ooo 76.550 73.424 75.085 76.424 77.922 0.000 76.486 74.941 74.665 77.405 77.948 0.000 76.087 73.268 74.997 77.169 76.583 0.000 76.205 73.176 74.411 77.178 77.333 0.000 76.522 74.472 74.971 ' 1-] t'1 Ul 1-] r. 0 ::i rt p, e TEST STARTING DAY 223 READ REAL TIME TIME & DAY PRESS SENS PI-1 PI-2 AMBIENT TEMP" & PRESS 1 9 17 F'SE&G CORP. RESEARCH & LABORATORY SALEM N0.1 INTEGRATED LEAK RATE TEST SENSOR READINGS 2 10 18 TEMPERATURE SENSORS <RTD'Sl 3 4 5 6 11 12 13 14 19 20 21 22 7 15 23 8 16 211 DATE 8/12/1979 TEST STARTING TIME 4/ 2 DEW POINT SENSORS 1 2 3 '1 5 6 -------------------------------------------------------------------------------------------------------------- 9.75 13 47 223 10.00 iii 2 223 10. 25 1'1 17 223 10.50 1'i 32 223 10.75 14 ft7 223 11.00 15 2 223 11. 25 15 17 223 11. 50 15 32 223 11. 75 15 'i7 223 12.00 16 2 223 12.25 16 17 223 12.50 16 32 223 12. 75 16 '17 223 62.236 89.187 62. '150 1'1. 79.r, 62.231t 89.722 62. '1'17 11t. 787 62.232 89.167 62.ftft5 11t.787 62.231 86.957 62. it'ift 14. 788 62.232 78.116 62. 445 1'1. 786 62.232 76.769 62. 447 1'1. 786 62. 233 72. 81.ti 62.ft48 14.767 62.233 76.045 62 * .t1.t16 14. 769 62.230 77.859 62.4'1'1 14.76'1 62. 236 77. 22'1 62.450 14.761 62.240 79.108 62. 1155 1'1. 751 62.24'i 76.719 62. 'i57 111. 749 62. 2'i'1 72. 983 62. '158 14. 747 81t.lt18 81t.901 85.197 8'i.888 85.033 85.048 85.203 84.831 84.757 84.839 84.772 84.687 8'i.629 85.173 85.31t8 84.661 85.053 84.821 83.207 85.070 84.823 84.970 84.799 77.51t0 81t.lt08 81t.871 85.167 84.878 85.063 84.989 85.222 81t.831 8'i.718 84.829 84.782 84.667 84.619 85.153 85.338 84.651 85.043 84.801 83.197 85.060 84.803 Blt.970 84.780 77.550 84.408 8'i.901 85.11t7 Bft.839 85.003 81t.989 85.212 84.741 84.648 84.809 84.7'i3 84.628 8ft.619 85.163 85.318 84.641 85.043 84.781 83.217 85.031" 84.773 8'i.9'i0 84.789 77.590 84.398 84.881 85.167 84.8'i9 85.013 84.969 85.203 8'i.831 84.767 8'i.799 8'i.693 84.667 S'i.629 85.143 85.308 84.6'i1 85.033 84.801 83.187 85.060 84.813 84.960 84.789 77.521 84.418 B'i.891 85.177 81t.8'i9 84.983 84.999 85.212 B'i.831 84.757 84.789 84.762 84.717 84.629 85.163 85.328 84.651 85.053 84.830 83.207 85.051 84.783 8ft.940 84.780 77.451 84.438 84.891 85.207 84.888 85.053 Bft.969 85.203 8'i.821 84.737 8'i.849 84.743 84.667 84.629 85.163 85.358 84.680 85.043 84.830 83.217 85.100 84.823 84.970 84.799 77.431 8'i.448 84.921 85.207 84.898 85.053 85.088 85.222 84.850 84.727 84.799 84.753 84.697 84.678 85.173 85.368 84.690 85.073 84.860 83.237 85.120 84.833 81t.990 84.819 77.441 84.448 Blt.921 85.177 84.918 85.033 85.009 85.261 84.840 84.767 84.889 84.772 84.757 84.629 85.173 85.348 84.661 85!073 84.850 83.227 85.100 84.813 84.980 84.799 77.481 84.438 84.901 85.217 84.859 84.993 84.999 85.203 84.801 84.777 84.799 84.792 84.707 84.659 85.163 85.328 84.670 85.073 84.830 83.177 85.070 84.793 84.980 84.809 77.401 84.467 84.931 85.207 84.888 85.063 85.058 85.252 84.880 84.807 84.859 84.772 84.707 84.698 85.193 85.348 84.700 85.113 84.900 83.197 85.140 84.833 85.010 84.859 77.451 76.687 76.155 o.ooo 77.656 74.941 74.463 77.042 78.457 0.000 77.828 74.233 74.306 77.042 0.000 77.483 74.316 74.656 77.804 78.118 -0.000 76.305 74.362 74.411 76.415 76.994 0.000 76.958 75.198 74.376 77.877 78.047

  • o.ooo 77.873 74.325 74.980 77.187 77.029 0.000 77.239 74.601 75.277 77.459 77.502 0.000 76.522 74.499 74.997 76.851 78.520 0.000 76.985 73.185 74.612 76.869 77.850 0.000 77.610 73.415 74.621 84.517 84.960 85.247 84.948 85.092 85.038 85.242 84.880 77.069 78.118 0.000 84.847 84.889 84.832 84.757 84.758 85.253 85.387 84.750 77.329 74.794 74.927 85.133 84.950 83.207 85.179 84.852 85.039 84.869 77.481 84.557 85.000 85.257 84.958 85.122 85.078 85.301 84.890 77.505 77.529 0.000 84.797 84.889 84.852 84.777 84.718 85.273 85.407 84.780 78.462 72.900 75.050 85.163 84.960 83.177 85.170 84.892 85.059 84.878 77.441 84.527 85.030 85.287 84.968 85.142 85.108 85.301 84.890 77.641 78.047 0.000 84.847 Bft.862 84.787 84.768 85.283 85.407 84.760 77.456 73.994 74.831 85.173 84.980 85.189 84.902 85.079 84.908 77.481 0 0 ::i rt -p.

-PAGE 5 TEST STARTING DAY 223 READ REAL TIME TIME & DAY 13.00 17 2 223 13.25 17 17 223 PF\ESS SENS PI-1 PI-2 AMBIENT TEMP &. PRESS 62.2'+1 71.298 62.'154 14. 736 62.232 70.505 62. 445 1'1. 729 1 9 17 PSE&.G RESEA.COF\P. RESEARCH &. TESTIN ABORATORY SALEM N0.1 INTEGRATED LEAK RATE TEST SENSOR READINGS TEMPERATURE SENSORS CRTD'S) 2 3 4 5 6 10 11 12 13 14 18 19 20 21 22 7 15 23 8 16 24 84.527 84.970 85.247 84.948 85.102 85.088 85.271 84.930 84.867 84.928 84.832 84.787 84.768 85.243 85.397 84.760 85.163 84.930 83.167 85.199 84.892 85.059 84.908 77.501 84.448 84.921 85.177 84.918 85.073 85.009 85.212 84.890 84.817 84.889 84.743 84.737 84.708 85.193 85.338 84.680 85.113 84.850 83.068 85.100 84.833 85.030 84.839 77.521 DATE 8/12/1979 TEST STARTING TIME 4/ 2 DEW POINT SENSORS 1 2 3 4 5 6 76.951 78.082 0.000 77.529 75.648 74.174 77.904 o.ooo 76.976 73.663 74.726 13.50 17 32 62.220 68.652 84.368 84.841 85.167 84.789 85.023 85.048 85.134 84.791 75.852 78.234 0.000 223 62.434 14.731 84.678 84.779 84.653 84.667 84.589 85.114 85.248 84.611 77.365 74.794 74.883 85.053 84.771 82.949 85.001 84.783 84.970 84.770 77.620 13.75 17 47 62.207 67.948 84.279 84.741 85.098 84.729 84.855 84.959 85.075 84.741 76.724 77.324 0.000 223 62.421 14.731 84.588 84.710 84.584 84.598 84.460 85.024 85.178 84.502 76.958 73.608 74.857 84.984 84.652 82.890 84.892 84.704 84.920 84.720 77.739 14.00 18 2 62.199 69.028 84.199 84.711 85.008 84.640 84.815 84.821 84.987 84.622 76.569 78.511 0.000 223 62.411 14.725 84.598 84.670 84.504 84.518 84.519 84.995 85.138 84.462 77.991 74.123 74.122 84.914 84.592 82.770 84.852 84.645 84.900 84.661 77.759 14.25 18 17 62.189 70.396 84.150 84.642 84.938 84.590 84.805 84.811 84.889 84.622 75.970 77.993 0.000 223 62.404 14.726 84.509 84.611 84.484 84.508 84.410 84.915 85.069 84.392 75.833 74.545 74.857 84.874 84.532 82.632 84.813 84.585 84.841 84.621 77.729 14.50 18 32 62.182 69.157 84.070 84.542 84.899 84.510 84.795 84.751 84.879 84.532 76.270 77.119 o.ooo 223 62.396 14.724 84.509 84.531 84.355 84.428 84.301 84.846 85.019 84.323 75.435 75.170 74.489 84.845 84.453 82.423 84.733 84.556 84.771 84.552 77.809 14.75 18 47 62.175 68.880 84.031 84.502 84.839 84.470 84.716 84.652 84.830 84.433 77.722 76.726 o.ooo 223 62.389 14.728 84.399 84.501 84.365 84.418 84.271 84.816 84.989 77.248 72.772 74.043 15.00 19 2 223 15.25 19 17 223 15.50 19 32 223 15.75 19 '17 223 16.00 20 2 223 62.171 69.226 62.386 14.722 62.167 67.066 62.381 14.721 62.161 68.334 62. 37'* 14. 716 62.157 66.858 62.370 14.711 62.153 65.926 62. 365 14. 70'1 84.433 82.443 84.724 84.506 84.731 84.522 77.978 83.991 84.522 84.809 84.461 84.657 84.642 84.801 84.433 84.370 84.491 84.365 84.349 84.231 84.796 84.929 84.253 84.755 84.403 82.383 84.654 84.477 84.711 84.503 78.027 83.981 84.462 84.759 84.431 84.647 84.603 84.781 84.383 84.370 84.452 84.296 84.329 84.211 84.756 84.909 84.223 84.745 84.353 82.364 84.634 84.427 84.682 84.453 77.918 83.941 84.432 84.739 84.391 84.587 84.583 84.751 84.393 84.270 84.432 84.256 84.299 84.201 84.726 84.860 84.194 84.675 84.304 82.364 84.615 84.388 84.642 84.404 78.097 83.882 84.412 84.729 84.371 84.607 84.583 84.693 84.363 84.260 84.372 84.206 84.229 84.191 84.667 84.840 84.144 84.666 84.274 82.354 84.575 84.338 84.602 84.404 78.147 83.872 84.373 84.670 84.321 84.498 84.464 84.673 84.284 84.290 84.313 84.206 84.239 84.151 84.667 84.800 84.124 84.636 84.234 82.225 84.535 84.328 84.602 84.345 78.236 76.796 77.029 o.ooo 76.631 74.306 74.166 75.961 77.583 o.ooo 76.794 72.496 74.419 76.978 77.154 o.ooo 76.704 73.783 74.297 76.406 77.806 o.ooo 75.725 73.020 74.323 76.379 76.628 0.000 75.833 74.352 74.384 .*:. :t 't :r *.I -PAGE 6 PSE&G f\ESEA-COFW. TEST STARTING DAY 223 RESEARCH & LABORATORY SALEM N0.1 INTEGRATED LEAK RATE TEST SENSOF\ F\EADINGS READ REAL TIME TIME & DAY 16.25 20 17 223 16.50 20 32 223 16.75 20 '17 223 17.00 21 2 223 17.25 21 17 223 17.50 21 32 223 17.75 21 '+7 223 18.00 22 2 223 18.25 22 17 223 18.50 22 32 223 18. 75 22 '17 223 19.00 23 2 223 19.25 23 17 223 PRESS AMBIENT SENS TEMP PI-1 & PI-2 PRESS 62.1'16 6'!.291 62.358 1'1.690 62.140 63.409 62.353 1'1.684 62.133 63.666 62.31+7 111.677 62.125 61+.727 62.338 11+.676 62.109 65.421 62.322 14.677 62.098 65.123 62. 311 14. 672 62.095 65.906 62.308 1'1.671 62.098 66.987 62.312 1'1.665 1 9 17 TEMPERATURE SENSORS <RTD'S). 2 3 4 5 6 10 11 12 13 14 18 19 20 21 22 7 15 23 8 16 24 83.842 84.313 8'1.640 84.311 84.528 84.41+4 8'1.595 84.224 8'1.260 8'1.313 84.097 84.179 84.062 84.587 84.760 84.065 8'1.586 8'1.174 82.145 84.466 84.299 84.51+2 84.325 78.226 83.793 84.283 84.590 84.271 84.429 84.454 84.575 84.214 84.181 84.263 84.058 84.169 84.072 84.538 84.710 84.045 84.556 84.155 82.264 84.436 84.249 84.542 84.285 78.107 83.733 84.243 84.540 84.222 84.419 84.385 84.546 84.174 84.111 84.223 84.028 84.080 83.972 84.538 84.680 83.985 84.506 84.085 82.304 84.367 84.220 84.463 84.265 78.127 83.61+4 84.193 8'1.570 84.162 84.350 8'1.441+ 8'1.497 84.125 84.052 84.184 83.938 84.060 83.933 84.419 84.601 83.896 84.'157 83.995 82.354 84.268 84.160 84.'123 84.216 78.196 83.574 8'1.064 84.401 84.043 84.191 84.247 84.389 84.045 83.992 84.104 83.849 83.940 83.794 8'1.349 8'1.491 83.816 84.337 83.866 82.344 84.178 84.071 8'1.393 84.107 78.226 83.485 83.974 84.311 83.963 84.152 84.197 84.281 83.966 83.853 84.015 83.760 83.911 83.784 84.250 84.451 83.747 84.288 83.787 82.314 84.089 83.992 84.294 84.048 78.405 83.455 83.974 84.301 83.923 84.112 84.138 84.281 83.916 83.863 83.955 83.799 83.831 83.724 84.240 84.412 83.717 84.248 83.787 82.294 84.079 83.982 84.244 84.018 78.405 83.475 83.984 84.292 83.963 84.132 84.167 84.291 83.956 83.903 83.965 83.809 83.861 83.744 84.260 84.412 83.747 82.314 84.099 83.972 84.264 84.028 78.355 62.105 66.161+ B3.554 84.084 84.331 84.211 84.148 84.310 83.946 62.319 14.659 83.932 84.015 83.829 83.881 83.843 84.329 84.451 83.796 84.317 83.916 82.165 84.208 84.012 84.274 84.068 78.286 62.105 65.123 83.554 84.034 84.321 84.013 84.270 84.237 84.359 83.966 62.318 14.662 83.913 83.975 83.809 83.940 83.714 84.329 84.431 83.767 84.307 83.866 82.076 84.169 84.002 84.274 84.048 78.256 62.092 66.848 83.455 83.954 84.272 83.933 84.152 84.138 84.281 83.916 62.304 14.662 83.913 83.975 83.670 83.811 83.734 84.210 84.362 83.657 84.228 83.717 81.937 84.030 83.873 84.224 83.999 78.484 62.068 66.105 83.257 83.745 84.242 83.754 84.043 84.029 84.075 83.707 62.281 14.656 83.674 83.757 83.521 83.701 83.545 84.051 84.242 83.508 84.0'19 83.508 81.709 83.792 83.765 84.125 83.840 78.415 62.043 66.897 83.058 83.575 84.023 83.545 83.815 83.841 83.928 83.558 62.255 14.650 83.485 83.647 83.323 83.472 83.356 83.843 84.063 83.300 83.890 83.280 81.609 83.584 83.587 83.826 83.662 78.484 DATE 8/12/1979 TEST STARTING TIME 4/ 2 DEW POINT SENSORS 1 2 3 4 5 6 75.108 77.538 0.000 75.172 74.178 74.052 76.315 76.610 0.000 75.353 74.270 73.894 76.415 77.458 o.ooo 75.824 73.176 74.166 76.833 77.458 0.000 75.951 73.387 74.297 75.988 77.020 o.ooo 76.114 73.185 73.955 76.070 76.895 74.990 73.847 73.658 75.489 76.895 0.000 75.707 72.790 73.815 75.916 76.967 0.000 75.598 72.376 73.990 76.324 77.351 0.000 75.362 73.682 74.306 75.643 76.931 0.000 75.879 72.680 73.772 75.108 75.807 0.000 75.009 73.580 74.052 75.671 77.413 0.000 75.299 71.568 73.299 75.707 76.797 0.000 75.888 70.906 72.808 -.J O'\ e PAGE 7 TEST STARTING DAY 223 READ REAL TIME TIME !)., DAY 19.50 23 32 223 19.75 23 47 223 20.00 0 2 22'+ 20.25 0 17 224 20.50 0 32 22'+ 20.75 0 47 224 21.00 1 2 22'+ 21.25 1 17 224 21. 50 1 32 224 21. 75 1 117 221+ 22.00 2 2 22'1 22.25 2 17 22't 22.50 2 32 224 PRESS SENS PI-1 F'I-2 AMBIENT TEMP !)., F'F\ESS 62.021 65.411 62. 234 111. 644 62.019 66.660 62.233 14.637 61.997 66.511 62.211 14.6115 61.986 66.640 62. 200 1'** 652 61. 992 66. 19'1 62. 206 1'1. 653 61.989 66.134 62. 203 1'1. 650 61.992 66.719 62.207 14.651 61. 996 66. 769 62. 211 111. 658 61. 998 66. 669 62.212 14.650 61.995 66.1161 62.208 14.661 61. 987 66.105 62.201 1'1.659 6l.. 967 66. 154 62.181 14.657 61. 9'17 67. 869 62.160 14.661 1 9 17 . F'SE!l<.G RESEA-COF\F'. RESEARCH !J.. SALEM N0.1 INTEGRATED LEAK RATE TEST SENSOR READINGS 2 10 18 TEMPERATURE SENSORS CRTD'S) 3 4 5 6 11 12 13 14 19 20 21 22 ,7 15 23 8 16 2'1 82.900 83.386 83.874 83.366 83.666 83.653 83.741 83.419 83.416 83.459 83.214 83.353 83.197 83.704 83.894 83.121 83.751 83.091 81.510 83.445 83.448 83.667 83.544 82.890 83.386 83.774 83.346 83.676 83.692 83.683 83.379 83.336 83.359 83.154 83.273 83.177 83.723 83.874 83.121 83.751 83.160 81.451 83.495 83.419 83.638 83.514 78.554 82.721 83.286 83.734 83.247 83.429 83.485 83.575 83.220 83.257 83.300 82.995 83.144 83.018 83.555 83.754 82.932 83.572 82.892 81.302 83.217 83.310 83.478 83.366 78.653 82.651 83.147 83.585 83.107 83.349 83.356 83.467 83.141 83.078 83.171 82.896 83.054 82.958 83.495 83.635 82.843 83.512 82.882 81.232 83.207 83.221 83.369 83.277 78.743 82.691 83.197 83.605 83.177 83.389 83.516 83.161 83.177 83.181 82.956 83.094 82.988 83.505 83.685 82.922 83.532 82.942 81.322 83.277 83.250 83.409 83.297 78.653 82.681 83.177 83.565 83.147 83.448 83.346 83.477 83.061 83.068 83.190 82.946 83.044 82.948 83.495 83.655 82.902 83.482 82.912 81.302 83.197 83.211 83.359 83.277 78.633 82.711 83.237 83.615 83.167 83.389 83.455 83.506 83.190 83.118 83.220 82.946 83.124 82.978 83.495 83.675 82.962 83.522 82.972 81.292 83.326 83.221 83.399 83.306 78.534 82.731 83.266 83.575 83.217 83.379 83.405 83.575 83.170 83.137 83.210 83.025 83.104 83.008 83.545 83.715 83.002 83.001 81.312 83.286 83.260 83.459 83.326 78.445 82.731 83.286 83.605 83.276 83.389 83.425 83.555 83.220 83.147 83.240 83.005 83.094 82.998 83.535 83.685 82.972 83.542 82.982 81.252 83.267 83.260 83.478 83.326 78.534 82.721 83.266 83.575 83.217 83.448 83.445 83.535 83.161 83.088 83.220 82.956 83.084 82.958 83.525 83.665 82.972 83.482 82.952 81.282 83.267 83.241 83.419 83.287 78.514 82.681 83.177 83.525 83.157 83.419 83.435 83.486 83.141 83.098 83.190 82.916 83.044 82.928 83.455 83.615 82.853 83.432 82.862 81.203 83.187 83.191 83.379 83.227 78.415 82.513 83.027 83.426 83.018 83.339 83.356 83.349 82.982 83.028 83.042 82.767 82.875 82.809 83.336 83.525 82.724 83.293 82.663 81.133 82.989 83.063 83.220 83.119 78.663 82.374 82.848 83.386 82.829 83.112 83.138 83.173 82.872 82.889 82.893 82.588 82.745 82.620 83.157 83.356 82.545 83.194 82.504 81.024 82.831 82.964 83.101 83.000 78.564 DATE 8/12/1979 TEST STARTING TIME 4/ 2 DEW POINT SENSORS 1 2 3 '1 5 6 74.672 76.726 0.000 74.111 73.194 72.966 75.616 76.289 0.000 74.229 72.597 73.281 74.717 76.128 0.000 74.356 72.707 72.861 74.064 74.334 0.000. 74.428 72.285 72.677 75.071 76.021 0.000 74.039 72.588 72.835 75.017 76.342 *o.ooo 74.129 71.899 73.036 75.653 75.539 0.000 73.948 75.079 72.756 74.872 75.557 0.000 75.072 72.009 72.773 74.000 75.584 0.000 74.093 71.595 72.730 73.628 75.557 0.000 74.020 72.707 73.176 73.864 74.156 o.ooo 74.555 72.983 72.817 74.391 75.923 0.000 74.247 71.908 72.432 74.263 75.878 0.000 73.295 70.786 72.353 -..] "' () 0 ::i rt p, J I. I ..

  • i* e PSE&G f(ESEAF\CH corw. PAGE 8 RESEAF\CH

& TESTING LAG@ATORY DATE 8/12/1979 SALEM N0.1 I NTEGF\ATED LEAi( RATE TEST TEST STARTING DAY 223 SENSOR READINGS TEST STARTING TIME 4/ 2 READ F\EAL PRESS A MG I ENT TEMPERATURE SENSOF\S <F\TD'S> DEW POINT SENSOF\S TIME TIME SENS TEMP 1 2 3 4 5 6 7 8 1 2 3 & F'I-1 & 9 10 11 12 13 1'1 15 16 '1 5 6 DAY F'I-2 PRESS 17 18 19 20 21 ,.,,., ,:_,,:... 23 2'1 -------------------------------------------------------------------------------------------------------------- 22.75 2 47 61. 940 67.403 82.294 82.798 83.207 82. 779 83.102 83.138 83.08it 82.783 73.737 75.789 0.000 22it 62.154 14.661 82.8it9 82.803 82.588 82.695 82.551 83.108 83.336 82.555 73.730 71. '1it8 72.414 83.154 82.485 80.955 82.821 82.885 83.021 82.901 78.574 23.00 3 2 61.936 67.938 82. 28'1 82. 778 83.187 82.789 83.072 83.079 83.12'1 82.7it3 73.673 75. 7'14 0.000 22it 62.150 14.661 82.720 82.803 82.578 82. 6116 82.531 83.108 83.296 82.565 73.703 70. '119 72.397 83. 09'1 82. '165 80.925 82.801 82. 8'15 82.991 82. 8'i'1r 78. 564 _, 23.25 3 17 61. 9it2 67.918 82. 3'1'1 82.868 83.197 82.829 83.1it1 83.099 83.12it 82.823 73.737 71,. 879 0.000 "" 224 62.157 1it.663 82.780 82.803 82.598 82.675 82.670 83.138 83.316 82.585 73.277 71. 926 72.598 83. 1it'1 82. 5'1it 80.955 82.860 82.875 83.031 82.931

78. it9'1 H !:"< ::ti 23.50 3 32 61.950 67.760 82.it03 82.918 83.217 82.898 83.062 83.138 83.192 82.813 7it.636 73.692 0.000 >-J 22'1 62.165 14.655 82.760 82.922 82. 6'18 82.705 82.700 83.207 83.356 82. 6'1it 73.758 72.055 72. '123 83.174 82.634 80.895 82.950 82.894 83.091 82.970 78. 50'1 1-:l 23.75 3 47 61.975 67.'123 82.602 83.117 83.376 83.077 83.221 83.178 83.339 82.992 7it.418 74. 7'15 0.000 Ul ..;; 224 62.189 14.650 82.968 83.061 82.817 82.905 82.829 83. '106 83. '195 82.833 74.120 72.597 72.633 83.343 82.882 81. 133 83. 177 83.033 83. 3'19 83.119 78.3it5 24.00 4 2 61.985 68.186 82.681 83.237 83. '156 83.177 83.339 83.326
83. 418 83.101 74.35it 76.297 0.000 0 224 62.199 14.650 83.008 83.121 82.916 82.95'i 82.938 83. '175 83.565 82.892 74.999 71. 825 73.211 t--} 83.383 82.922 81.193 83.197 83.092 83.'i09 83.208 78.385 0 0 ::i rt -p, I r TEST STARTING DAY 223 TIME t Hours 0.00 0.25 0.50 0.75 1. 00 1. 25 1. 50 1. 75 2.00 2.25 2.50 2.75 3.00 3.25 3.50 TEMP T Deg F 86.02 85.79 85. 6'1 85.53 85. 4'1 85.36 85.29 85.23 85.18 85.16 85.13 85.10 85.07 85.03 85.01 PSE&G RESEARCH CORP. RESEARCH & TESTING LAGORAT0RY SALEM UNIT NO. 1 TEMPERATURE STAGILITY TEST AVG TEMP DIFF FOR LAST 3 HRS -0.31 -*0. 25 -0.21 8/11/1979 TEST STARTING TIME 0/30 AVG TEMP DIFF FOR LAST HR -0.03 -0.03 -0.02 DIFF AVG TEMP DIFF COL3-COL4

-0.28 -0.21 -0.18 . ' . i ,.); *;, PAGE 3 .TEST STARTING DAY 223 PSE&G RESEARCH CORP. RESEARCH & TESTING LABORATORY SALEM N0.1 INTEGRATED LEAK RATE TEST STABILITY DATA DATE 8/12/1979 TEST STARTING TIME 0/30 ------------------*--------------------------------------------------------------------------------------------- READ f\EAL JULIAN AMBIENT AVG AVG AVG AVG CONT TIME TIME DAY TEMP Pf\ESS TEMP DEW PT VAPOR CONTMT MASS TEMP PRESSURE PF\ESSURE <Hrs) <Hr/Min) <Deg F> <Psia) <Deg F> <Deg F> <Psia) <Psia> <Lbm) --------------------------------------------------------- 0.00 0 30 223 82.51 14.762 86.02 77.22 O.'i62 62.503 803961.8 0.25 0 'i5 223 81.74 1".760 85.79 76.9'i O.'i58 62.'i75 803985.6 0.50 1 0 223 82.82 1'i.765 85. 6'1 77.13 0.461 62.457 803938.4 0.75 1 15 223 82.05 14.765 85.53 76.83 0. '156 62.447 80'1031. 5 1. 00 1 30 223 81. 91 1'1. 761 85.'i4 77.33 0. 46" 62.432 803883.8 1.25 1 45 223 80.61 1'i.761 85.36 76.75 O.'i55 62.421 803973.2 1. 50 2 0 223 80.58 14.756 85.29 76.83 0.456 t 62.413 8039'11. 3 1. 75 2 15 223 90;86 1'1.758 85.23 76.98 0.458 62. '103 803872.5 2.00 2 30 223 79.90 14. 75'1 85.18 76.1'1 o. '146 62.397 80'1029. 9 2.25 2 '15 223 79.71 1'1.75'1 85.16 77.15 O.'i6i 62.39'i 803831. 0 2.50 3 0 223 79.05 l'i.750 85.13 76.87 O.lt57 62.392 803892.0 2.75 3 15 223 80.32 1'1.752 85.10 76.88 O.it57 62.386 803867.1 3.00 3 30 223 80.31 14. 75'1 85.07 76.65 o. 'i5'1 62.382 803912.9 3.25 3 45 223 80.29 14.750 85.03 76.20 O.'i47 62.377 803983.8 3.50 '1 0 223 80.38 1'1. 747 85.01 76.13 o. 4'16 62.372 80397'1. 7 -i OJ rn >-3 tll H t< H 1-] ><: 1--] t<J rn >-3 0 >-3 PAGE 1 TEST STARTING DAY 223 READ REAL TIME TIME & DAY AMBIENT TEMP & PRESS PRESS SENS PI-1 PI-2 1 9 17 PSE&G RESEARCH CORP. RESEARCH & TESTING LABORATORY SALEM N0.1 INTEGRATED LEAK RATE TEST STABILITY DATA TEMPERATURE SENSORS CRTD'S> 2 3 4 5 6 10 11 12 13 14 18 19 20 21 22 7 15 23 8 16 24 DATE 8/12/1979 TEST STARTING TIME 0/30 DEW CELL SENSORS 1 2 3 4 5 6 0.00 0 30 82.517 62.396 85.757 86.186 86.909 86.252 87.033 86.790 86.732 86.371 76.924 77.467 o.ooo 223 14.762 62.610 86.258 86.309 85.666 86.221 85.693 86.127 86.204 85.574 78.154 74.518 75.383 85.750 85.298 83.664 85.576 85.426 85.646 85.373 77.531 0.25 0 45 81.744 62.369 85.489 85.907 86.551 85.923 86.746 86.345 86.428 85.994 77.314 77.056 o.ooo 223 14.760 62.581 85.930 85.961 85.467 85.913 85.563 85.988 86.094 85.515 77.365 75.474 75.733 85.710 85.278 83.644 85.546 85.386 85.566 85.333 0.50 1 0 82.824 62.351 223 14.765 62.563 85.281 85.708 86.292 85.754 86.528 86.157 86.222 85.685 77.032 78.796 o.ooo 85.771 85.792 85.348 85.773 85.374 85.898 86.055 85.386 77.556 74.913 75.260 85.670 85.248 83.535 85.536 85.337 85.507 85.274 77.282 0.75 1 15 82.051 62.341 85.182 85.698 86.113 85.684 86.003 86.028 86.046 85.616 77.350 77.600 0.000 223 14.765 62.552 85.622 85.673 85.348 85.375 85.255 85.839 86.065 85.316 77.239 74.941 75.041 85.650 85.218 83.445 85.487 85.307 85.467 85.264 77.183 1.00 1 81.912 62.326 85.063 85.558 85.993 85.575 86.023 85.870 85.977 85.546 77.205 78.314 o.ooo 223 14.761 62.539 85.542 85.554 85.209 85.335 85.156 85.739 85.965 85.266 77.982 75.143 75.207 85.551 85.129 83.406 85.417 85.218 85.427 85.155 77.183 1.25 1 45 80.614 62.315 84.983 85.489 85.884 85.525 85.766 B5.780 85.840 85.536 76.851 78.636 0.000 223 14.761 62.528 85.354 85.455 85.189 85.235 85.136 85.690 85.875 85.197 76.985 74.784 74.971 85.521 85.079 83.286 85.368 85.169 85.368 85.135 77.203 1.50 2 0 80.584 62.306 223 14.756 62.519 84.924 85.449 85.774 85.4!6 85.667 85.701 85.781 85.417 77.577 75.824 0.000 85.354 85.385 85.179 85.166 85.026 85.590 85.816 85.167 77.375 76.310 75.041 85.471 85.019 83.207 85.328 85.139 85.318 85.135 77.232 1.75 2 15 80.862 62.296 84.844 85.339 85.774 85.366 85.657 85.592 85.742 85.298 78.167 78.181 o.ooo 223 14.758 62.510 85.334 85.335 85.060 85.136 85.026 85.551 85.776 85.068 77.175 74.766 75.120 85.401 84.970 83.058 85.239 85.070 85.268 85.046 77.223 2.00 2 30 79.900 62.290 84.775 85.279 85.725 85.257 85.696 85.612 85.654 85.248 76.388 77.520 0.000 223 14.754 62.504 85.224 85.296 85.011 85.076 84.897 85.551 85.716 85.018 76.396 73.709 75.181 85.392 84.950 82.969 85.239 85.030 85.248 85.017 77.242 2.25 2 45 79.712 62.287 84.755 85.289 85.595 85.217 85.548 85.573 85.614 85.248 77.713 78.448 o.ooo 223 14.754 62.501 85.214 85.246 85.031 85.116 84.877 85.511 85.676 84.988 77.574 74.922 74.857 85.372 84.970 82.979 85.239 85.021 85.238 84.997 77.252 2.50 3 0 79.058 62.284 223 14.750 62.499 2.75 3 15 80.327 62.279 223 14.752 62.493 84.745 85.220 85.615 85.227 85.518 85.634 85.178 78.185 76.940 o.ooo 85.155 85.226 85.011 85.016 84.867 85.4B1 85.656 84.968 77.103 75.593 75.172 85.362 84.950 82.919 85.249 85.040 85.228 84.997 77.213 84.706 85.230 85.595 85.187 85.459 85.503 85.526 85.168 77.686 77.850 o.ooo 85.135 85.187 84.971 85.076 84.808 85.431 85.606 84.939 77.329 74.481 74.805 85.312 84.920 82.790 85.189 84.991 85.199 84.957 77.213 PAGE 2 TEST STARTING DAY 223 f(EAD REAL AMBIENT PRESS TIME TIME TEMP SENS 1 & & F'I-1 9 DAY PRESS F'I-2 17 3.00 3 30 80.317 62.276 84.666 223 14.754 62.489 85.075 85.302 3.25 3 45 80.297 62.270 84.626 223 14.750 62. 1184 85.026 85.272 3.50 4 0 80.386 62.266 84.596 223 14. 71,7 62.479 85.036 85.222 e* F'SE&G RESEARCH CORP. RESEARCH & TESTING LABORATORY SALEM N0.1 INTEGRATED LEAK RATE TEST STABILITY DATA TEMPERATURE SENSORS <RTD'Sl 2 3 4 5 6 10 11 12 13 14 18 19 20 21 22 85.170 85.526 85.177 85.429

85. 4011 85.147 811.981 811. 966 91,. 8117 85.422 811. 910 82.780 85.170 84.961 85.189 85.140 85.1176 85.117 85.380 85.355 85.127 84.892 84.926 84.768 85.422 84.870 82.731 85 *. 120 8 1 1. 932 85. 1'19 85.090 85.1156 85.097 85.340 85.404 85.097 84.822 84.956 91,. 758 85.352 84.840 82. 711 85.110 91,. 922 85.109 7 15 23 85.516 85.606 8 1 1. 938 85.497 85.577 84.948 85. 1128 85.547 811. 908 8 16 211 85.109 811. 929 77.163 85.119 84.839 ";{7.232 85.109 81t.859 77.252 DATE 8/12/1979 TEST STARTING TIME 0/30 DEW CELL SENSORS 1 2 3 4 5 6 76. 8211 78.600 0.000 76.640 75.180 75.470 77.132 78. 2113 0.000 76.187 73.498 75.120 77.423 77.083 0.000 76.205 73.966 75.006 () 0 ::J rt p,
  • PSE&.G RESEARCH AP . RESEARCH &. TESTING PAGE 1 DATE 8/12/1979 SALEM UNIT NO. 1 I.L.R.T. VERRIFICATION TEST -PUMP BACK METHOD* TEST STARTING DAY 224 TEST STARTING TIME 8 : 30 ---------------------------------------------------------------------------------------------------------------

READ REAL AMBIENT AVG AVG AVG AVG CONT CALC 95 % CALC TIME TIME TEMP PRESS CONT DEW PT VAPOR CONT MASS LEAf( CONFIDENCE INITIAL TEMP TEMP PRESS PF\ESS RATE LEVEL MASS <Hrsl<Hr/Mnl<DegFl<Psial <DegF l <Deg Fl <Psial <Psial CLbm l <Lbm/Hrl(%/Dayl CLbm/Hrl(%/Dayl CLbml ------------0.00 8 30 62.19 14.66 82.800 73.354 0.406 62.096 804160.9 0.25 8 '15 62.30 14.66 82.686 73.216 0.404 62.082 8011170. 9 0.50 9 0 62.69 14.67 82.592 73.051 0.'102 62.068 804155.0 0.75 9 15 62.08 14.68 82.504 72. 877 0.400 62.057 8011171. 7 1. 61111 0.004 -268.106 0.809 804165.0 1.00 9 30 61.51 111. 69 82.418 73.251 o. 1105 62. 0'14 8040711. 7 -108.699 0.324 -362.528 1. 081 804211.0 <: tr: H "1 H n H 0 z *f."

1*;

PAGE 2 'A'-TEST STARTING DAY 223 PSE&G RESEARCH CORP. RESEARCH & TESTING LABORATORY SAL.EM UN IT NO. 1 VERIFICATION TEST -PUMPBACK METHOD FINAL RESULTS DATE 8/12/1979 'A'-TEST STARTING TIME 4 ' ? Mass Pumped Into Containment CM> = 651.3 Lbm Acceptance Criteria (/M-Cm1-m2)/) < .25 La = 206.7 Lbm ----------------------------------------------*-----*----------------------------------------------------------- TEST REAL JULIAN ILRT MASS VER MASS TIME TIME DAY @t=N @t=N DUR m2 m1 CHr> <Hr/Min) <Lbm) <Lbm) --------0.75 9 15 224 803348. 804166. 1. 00 9 30 224 8033'13. 804102. DIFF MASS ILRT MASS MEAS-CALC @T=O /M-(m1-m2)/ m2 <Lbm) <Lbm) 166. 803362. 107. 803362. VER MASS @t=O mi <Lbm) 804165. 804211. DIFF MASS MEAS-CALC /M-<m1-m2)/ <Lbm) 151. 197. I-' D < tT.I H hJ H (") t-3 H 0 z t-3 tT.I (/) t-3 f;l (/) c t-< t-3 (/) 1'. PAGE 1 TEST STARTING DAY 224 READ TIME Hours CALC LEM( RATE Lbm/Hr /./Day PSE&G RESEARCH CORP. RESEARCH & TESTING LABORATORY SALEM N0.1 ILRT VERIFICATION TEST -PUMP BACK METHOD REGRESSION ANALYSIS DATA CALC INITIAL AIR MASS Lbm STD DEV OF MASS Lbm STD DEV OF SLOPE Lbm/Hr STUDENT--T DIST. VALUE DATE 8/12/1979 TEST STARTING TIME 8/30 95/. CONF. FIGURE Lbm/Hr /./Day ----*----------------------------------*------------------------------------------------------------------------ 0.75 1. 00 1.644 -108.699 0.0049 0.3243 80'1165. 0 804211.0 13.32 36.83 37.70 65.90 7.154 3.851 -268.106 -362.528 0.8099 1. 0818 ' ' t

  • F'AGE 1 TEST STARTING DAY 224 t\EAD REAL TIME TIME <Hrs) (Hr/Min) JULIAN DATE J; i, F'SE&G RESEARCH CORF'. RESEARCH & TESTING LABORATORY SALEM N0.1 ILRT VERIFICATION TEST -F'UMP BACK METHOD AVERAGE & MASS DATA AMBIENT TEMF' F'RESS <DegF) (F'sia) AVG CONTMT TEMP <Deg Fl AVG CONTMT DEW F'T <Deg Fl CALC VAF'@ PRESS (Psia) AVG CONTMT PF\ESS (F'sia) CONTMT MASS <Lbm) DATE 8/12/1979 TEST STARTING TIME 8/30 DIFF MASS (F'-T-F')

<Lbm) DIFF MASS (TOT TIME) (Lbm) -----------------------------------------*w-------------------------------------------------------------------- o.oo 8 30 224 62.190 14.661 82.800 73. 35'1 o. '106 62.096 80'1160. o.o 0.0 0.25 8 45 224 62.309 14.661 82.686 73. 216 0.404 62.082 804170. 9.9 9.9 0.50 9 0 224 62.695 14.675 82.592 73.051 0,402 62.068 804155. -15.9 -5.9 0.75 9 15 224 62.081 14.681 82. 5011 72.877 0. '100 62.057 80'1171. l.6.7 10.8 1. 00 9 30 224 61.516 14.690 82.418 73.251 0.405 62.044 804074. -96.9 -86.1 PAGE 1 TEST STARTING DAY 224 READ TIME 0.00 0.25 0.50 0.75 1.00 REAL TIME & DAY 8 30 2211 8 45 224 9 0 2211 9 15 22'+ 9 30 2211 PRESS SENS PI-1 PI-2 61. 989 62.202 61. 975 62.188 61. 961 62.1711 61. 950 62.163 61. 938 62.151 I 4, AMBIENT TEMP & PRESS 62.190 14.661 62.309 l't.661 62.695 1'1. 675 62.081 14.681 61. 516 14.690 PSE&G RESEARCH CORP. RESEARCH & TESTING LABORATORY SALEM N0.1 ILRT VERIFICATION TEST -PUMP BACK METHOD SENSOR READINGS 1 9 17 82.314 82.829 83. 10'1 82.205 82.591 83.034 82.086 82.601 82.915 81.997 82.412 82.846 81. 917 82.422 82.736 TEMPERATURE SENSORS <RTD Is) 6 14 2 10 18 82.818 82.833 82.504 82.678 82.694 82.385 82.579 82.62'+ 82.266 82.499 82.545 82.176 82.399 82.485 82.067 3 4 5 11 12 13 19 20 21 83.207 82.789 83.0'+2 82.558 82.666 82.551 81. 163 82.831 82.845 83.167 82.729 82.933 82.'+19 82.576 82.392 81.133 82.771 82.756 83.018 82.570 82.8'+'+ 82. 3110 82. 1176 82.322 80. 971, 82.563 82.687 82.918 82.500 82.725 82.271 82.377 82.262 80.716 82. 1174 82.588 82.838 82.1121 82.686 82.151 82.307 82.133 80.597 82.404 82.519 22 83.069 83.088 83. 0111 83.000 82.959 82.952 82.8111 82.909 82.822 82.792 82.830 82.753 82.703 82.730 82.673 7 15 23 83.1'+3 83.296 82.921 82.986 177 82.804 82.937 83.087 82.733 82. 8'19' 83.017 82. 63'1 82.751 82.938 82.555 8 16 24 82.763 82. 5115 78.614 82. 6611 82. 4115 78.604 82.574 82.316 78.653 82. 50'1 82.267 78.623 82.355 82.138 78. 56'+

  • DATE 8/12/1979 TEST STARTING TIME 8/30 DEW POINT SENSORS 1 2 3 4 5 6 73.537 75.084 0.000 73.59'+ 71. 108 71.898 73.228 75.700 0.000 72.915 72.386 72.266 ....i I-' w 711. '163 75.271 0.000 72.951 69.831 71. 99'+ 't1 q 't1 73.682 73.959 0.000 tr; 73.313 69.362 71.749 () ?>: < 73.592 75.262 0.000 to: ::<! 73.413 71.182 71. 1125 H '"".! H () >'3 H 0 z 8 1:1 UJ 8 fg ::;;: t:' :i:< 1-3 :i:<

8.0 SUPPORTING DATA

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  • Sununary of All Type B&C Tests performed since the last Type A, ILRT The data presented in this section was provided by the Salem Nuclear Generating Station -Maintenance Department which is responsible for the performance of these tests. All B&C tests were conducted by the PSE&G Research Corporation, Research and Testing Laboratory personnel.

The applicable procedures under which these tests were performed are as follows: Initial Tests -1976 1-PT-CONT. 1&2 Outage 1977 M 16 E ' Refueling Outage -1979 M 16 E These procedures are in compliance with Technical Specification requirements T.S.4.6.l.2(d) and T.S.4.6.1.3 (b) * /, 19 noo7;.7 r-9 ;-, f,, 1-J, G, /, 2(,. / I ! TOTAIJ LEAKAGE

SUMMARY

SHEET Total Type A,B&C Leakage 33,695 SCCM (!nit.Test Results) Total Allowable Leakage B&C (.60 La) = 129,750 SCCM NOTE:Air lock door leakage per T.S. 4.6.1.3 is ( O.OlLa) = 2,162.50 SCCM) i I VALVE/PENETRA'rION PREVIOUS LEAKAGE I DATE NUMBER SCCM REFERENCE DATA FROM 1-PT COHT. #1&2 (TYPE FEB.-JUNE Type B Test Accumulated N/A 1976 (Initial} Type c Test Accumulated N/A , (Initial} I I --l Total Type B&C Tests N/A : (Initial} 1 TYPE B&C RETES+1 DATA a/8/76 11CA330 23.2 {P.346) 8/8/76 1CC131 Not Avail. 8/8/76 1VC4 0 (P.397) 8/9/76 1VC5 110 {P.398). 8/11/76 '* Equipment Hatch 145 (P.319) 8/19/76 Hatch Cover (11SJ44 Val.Rm.} 50.l (P.435) ' 8/13/76 Hatch Cover (12SJ44 Val. Rm.} 54.9 (P.434) 8/19/76 Hatch Cover (12SJ44 Val. Rm.) 90.0 I 8V30/76. Fuel Trans. Blank Flange 0.1 9f29/76 lc'Cl87 14.0 9/30/76 1VC9 o.o 9/30/76 lVClO 16.8 9/30/76 1VC13 0.6 9/30/76 1VC14 lo. 0* INITIAL TEST RESULTS Total Type C 35S0.5 SCCM Total Type B 589.5 SCCM Total B&C 4140 SCCM CURRENT LEAKAGE LEAKAGE TOTAL B&C LEAKAGE SCCM SCCM TESTS} N/A N/A 589.5 N/A N/A 3550.5 ----N/A N/A 4140 29.0 + 6.2 4146.2 14.0 + 14.0 4160.2 948.0 +948.0 5108.2 29.0 -81. 0 5027.2 3.9 -141.1 4886.1 12.0 -48.1 90.0 + 35.1 4873.l 49.0 -41. 0 4832.1 0.2 + 0.1 4832.2 12.0 -2.0 4830.2 0.0 +-0.0 4830.2 0.0 -16.8 4813.4 0.0 -0.6 4812.8 0.0 -10.8 4802.0 ' PAGE i. i ,.*

  • TOTJ\.L LEJ\.Kl\GE SUMMJ\.RY SHEET Total Type A,B&C Leakage 33,695 SCCM {!nit.Test Results) Total l\.llowable Leakage Il&C (.60 La) = 129,750 SCCM NOTE:l\.ir lock door leakage per T.S. 4.6.1.3 is ( O.OlLa) = 2,162.50 SCCM) T.S.: 4.6.1.2. {r) INITIJ\.L TEST RESULTS Total Type c Leakage 355b.5 SCCM Total Type Il Leakage 589.5 SCCM Total B&C Leakage 4140 SCCM d 'fOTAL Vl\.LVE/PENETRATION PREVIOUS LEAKAGE CURREN'l 1 LEAKAGE LEJ\.Kl\.GE B&C Dl\.TE NUMBER SCCM SCCM SCCM LEAKAGE 10/1/76 1VC12 4.0 0.0 -4.0 4798.0 10/1/76 1VC7 0.0 0.0 --4798.0 10/1/76 lVCll 0.1 0.0 -0.1 4797.9 10/1/76 1VC8 o.o 0.0 --4797.9 \ 10/14/76 130' Overall Test-Airlock 93.3 248.0 +154.7 4952.6 10/18/76 100' Overall Test-Airlock 127.0 621. 0 +494.0 5446.6 10/22/76 11SJ44 Val. Rm. CVR. 12.0 10.0 -2.0 5444.6 10/22/76 12SJ44, Val. Rm. CVR 49.0 100.0 +51.0 5495.6 2/28/77 130' Airlock 248.0 352.0 +l 04. 0 5599.6 2/28/77 100' Airlock 621. 0 788.0 +167.0 5766.6 5/1/77 1CV69 10.0 0 -10.0 *5756.6 5/6/77 1CV68 (After Repairs) 12.0 0 -12.0 5744.6 6/10/77 12GB4 3.0 0 -3.0 5741. 6 6/10/77 14GB4 15.0 0 -15.0 5726.6 6/12/77 Elec. Pen. 1-20 (After 0 0 00.0 5726.6 #14 R.C.P. Cable Repairs) 6/13/77 Elec. Pen. 1-0 0 .0 00.0 5726.6 6/13/77 Elec, Pen. 1-21 0 0 00.0 5726.6 ISI .:... Se Jt. 19 -

14 -1977 9/19-Electrical Penetratior s 0.1 16.0 +15.9 5742.5 9/23/77 ( ' PAGE 2 .\i'! I-' 0 -2860004 CONTAINMENT TYPE B & C LEAKAGE

SUMMARY

SHEET Pre Op. Type A, B, & C Leakage: 33,695 Pre Op. Type B & C Leakage: (Type B: 589.5, Type C: 3550.5): 4140 Allowable Type B & C Leakage(0.6 La) = 129,750 SCCM Allowable Airlock Leakage (0._05 La) = 10,812 SCCM PREVIOUS CURRENT DELTA PRESENT TEST DATE COMPONENT LEAKAGE LEAKAGE LEAKAGF SUM B & c TESTED SCCM SCCM SCCM LEAKAGE ( SCCM) 9/26/77 CARRIED FO RWARD FROM SHEET 2 5,742.5 9/21/77-All Mech. 145.0 80.0 -65.0 5,677.5 9/26/77 Pen's & Equip. Sept. 77 Hatch Ex-Outage . cept 1, 3, 4, 6, 13, & 15 Pen's. Requiring Repairs 10/8/77-100' Air 621.0 23.0 -598.0 5,079.5 10/9/77 Lock & Elec. Sept. 77 Pens. Outage 130' Air 248.0 559.0 +311.0 5390.5 Lock & Elec. Pens 10/25/77-Mech. Pens After Re-pairs to Bellows 1 0.0 24.0 + 24.0 (Overall +125.0) 3 o.o o.o -4 0.0 80.0 + 80.0 6 o.o 30.0 + 30.0 13 0.0 + 3.0 ' :*i! , . REMARKS AGE p 3 \

u , CD <1 . I-' CONTAINMENT TYPE B & C LEAKAGE

SUMMARY

SHEET Pre Op. Type A, B, & C Leakage: 33,695 Pre Op. Type B & C Leakage: (Type B: 589.5, Type C: 3550.5): 4140 Allowable Type B & C Leakage(0.6 La) = 129,750 SCCM Allowable Airlock Leakage (0.05 La) = 10,812 SCCM PREVIOUS CURRENT DELTA PRESENT TEST DATE COMPONENT LEAKAGE LEAKAGE LEAKAGE -SUM B & c TESTED SCCM SCCM SCCM LEAKAGE (SCCM) 15 0.0 3.0 + 3.0 5 16.0 3.0 -13.0 8 2.0 0.0 -2.0 5,515.5 10/23/77 11SJ44 Val. 10.0 300.0 +290.0 +49 0) Sept. 77 Rm. Cover Outage 12SJ44 VaL 100.0 300. 0. +200.0 6,005.5 Rm. Cover 10/23/77-Leak Rate See Attach-See At-(Overall) 6,438.9 11/3/77 Testing ed Data tached +433.4 Sept. 77 60 Valves Sheets 3A Data Outage See Attach-& 3B Sheets Data SheetE 3A & 3B NOTE: New Total 6,438.9 Pre ISI Total 5,726.6 Ove all Change This ISI + 712. 3 , ; . . Ii! --' REMARKS . PAGE 3A re *e *2860006 ' * ,,---. -, * "-1 Prev. Prev. Pres. Pres. Leak Leak Leak Leak Dif f + ------------- 1CV3, 4, 5//1CV7 No Record 13.0 14.0 0.0 1.0 1CV284//1CV116 13.7 20.7 106.0 0.0 + 77.3 1CC113 & 1CC215 3.0 7.0 3.0 4.0 1CC117//1CC118 132.0 38.0 82.0 72.0 -50.0 1CC131//1CC190 1.0 5.0 0.0 1. 0 1.0 1CC187//1CC136 12.0 39.1 100.0 30.0 + 60.9 11CA330 29.0 123.0 + 94.0 12CA330 o.o 4.0 + 4.0 1DR29 13.5 3.0 -10.5 1FP147 1.0 300.0 +299.0 11GB4 1.0 2.0 + 1.0 13GB4 8.0 33.0 + 25.0 1NT25 0.0 14.0 -14.0 1NT32 0.5 1.0 + 0.5 1PR17//1PR18 8.0 0.0 28.0 68.0 + 60.0 1SJ123//1SJ53, 1SJ60 0.0 19.4 5.0 10.0 9.4 1SS103//1SS27 0.6 5.0 o.o 0.0 5.0 1SS104//1SS33 0.0 o.o 22.0 11. 0 + 22.0 1SS107//1SS49 0.3 0.7 3.0 1. 0 4.0 1SS110//1SS64 o.o 0.6 4.0 3.0 2.0 1SS94 1. 6 0.0 1. 6 12SS94 3.4 0.0 3.4 13SS94 0.4 0.0 0.4 14SS94 8.6 0.0 8.6 lVCl 15.0 2.0 -13.0 1VC4 948.0 0.0 -948.0 1VC5 29.0 792.0 +761. 0 Valve Test Data PAGE. 3B Rev. 1 *.r. 1/4/79 <9 Prev. Leak ------(1VC7//1VC8) a.a (1VC11//1VC12) (lVC9//lVCla) a.o ( 1VC13//1VC14) 1WL12//1WL13 a.6 1WL17//1WL16 10'. a 1WL96//1WL97 1.1 1WL98//1WL99 & lWLlaB 19. a lWRBa 3.3 liM .... --*-Pres. Pres. Leak Leak. Leak ------------------*----

  • -*---*-----*----

a.a a.a a.a a.a 4.a 5.a 17.a 73.a 95.a 9.9 8.a 2.a a.3 4.a a.a 21.4 a.a 16.a 13.a

  • Diff + (+/-) a.a + 5.a + 78.a 2.a + 1.a 5.4 + 9.7

SUMMARY

+15a2.7 -1069.3 + 433.4 Overall Change Valve Test PAGE 3C Rev . 1 1/4/79 tTj I-'* lQ i:: Ii ID -...I I-' 0 ---

CONTAINMENT TYPE B & C LEAKAGE

SUMMARY

w:fi Pre Op. Type A, B, & C Leakage: 33,695 Pre Op. Type B & C Leakage: (Type B: 589.5, Type C: 3550.5): 4140 Allowable Type B & C Leakage(0.6 La) = 129,750 SCCM Allowable Airlock Leakage {0.05 La) = 10,812 SCCM TEST DATE 11/14/77 3/21/78 3/23/78 5/1178 9/5/78 9/6/78 NOTE: PREVIOUS CURRENT DEI.TA PRESENT COMPONENT LEAKAGE LEAKAGE LEAKAGE SUM B & c REMARKS TESTED SCCM SCCM SCCM I,EAKAGE (SCCM) CARRIED FO FROM 3 6438.CJ 130' Air 559 256 -303 6135.9 Lock 100' Air 23 481 +458 n 593 .. 9 Lock 188107 2 208 +205 6798.9 100' Air 481 Lock 289 -192 6606.9 130' Air 256 847 +591 7197.9 Lock 1/4/79 Total accwulated lea}aqe correpted per request during audit on 1/4/79. Eeason: I rocedure rnecl. the least conservati lTe leakaqe of two vab es in a sirgle path. Procedutre Ml6E initiated. All past mtage d('lta corrected 1-0 reflect the conservatilTe accumulated leakage. (ii" /u te r. (I 'l IZ r /ti r ll s S S[f'fJE,; T s-/ I PAGE Lf ...... 0 CONTAINMENT TYPE B & C LEAKAGE

SUMMARY

SHEET Pre Op. Type A, B and C Leakage: 33,695 Pre Op. Type B and C Leakage: (Type B: 589.5, Type C: 3550.5): 4140 Allowable Type Band C Leakage (0.6 La) = 129,750 SCCM Allowable Airlock Leakage (0.05 La) = 10,812 SCCM PREVIOUS CURRENT DELTA PRESENT COMPONENT LEAKAGE LEAKAGE LEAKAGE SUM B & C TEST DATE TESTED SCCM SCCM SCCM LEAKAGE (SCCM) 1/22/79 CARRIED FC RWARD FROM SHEET 7 7197.7 3/30/79 100' Air 289 1240 +951 8148.7 Lock 4/2/79 130' Air 847 1048 +201 8349.7 Lock 1979 Elect. Pen. I 0 0 0 8349.7 Refuel. (100%) I Outage 1979 Valves See See Attach-! +1972 10, 321. 7 Refuel. (100%) Attached ed Data Outage Data Sheet Sheet 1979 Mech. Pen. 0 0 0 10,321. 7 Refuel. (100%) Outage NO FURTH ENTRIES ----* -*-->--* REMARKS I I ' * -.1': PAGES

  • VALVE LEAK RATE

SUMMARY

CHANGE Leak Rate Decreased Leak Rate Increased 6 Leak Rate Pre Outage Total: 100' Air Lock 130' Air Lock Electrical Penetrations Valves Mechanical Penetrations -1231 +3203 +1972 7197.7 Type B & C (1979 Outage) + 951. 0 + 201. 0 0.0 +1972. 0 0.0 10,321. 7 ....__.

SUMMARY

I 1919 REFUELlNG-; 3151270 Ref. Dwg. 205863 UNIT il ELECTRICAL PENETRATIONS .... co 11) UJ C> Penetration No. Penetration No. Penetration No. Q_ E-1 B-3 _......::;0;;__ ___ E-23 B-5 _ E-45 B-7 __ o.;,__*---- E-2 J-2 __ CJ=-----E-24 J-4 E-46 C-5 C E-3 A-5 __ Q ____ E-25 A-6 _...:.::_ ______ E-47 H-5 c E-4 G-1 _.....;t);:;;_ ____ E-26 D-8 E-48 D-4 E-5 B-6 C E-27 G-2 C E-49 D-6 ---=-----E -6 J-1 _.:..0:;..,_ ___ E-2_8 J-3 ___ D _____ E-50 C-6 {) _...;;.__ ___ _ E-7 H-4 Q E-29 I-4 0 E-51 SPARE C -----E-8 D-9 ____ E-30 SPARE ...;Qi..::*----- E-52 SPARE C E-9 A-1 0 E-31 A-2 C E-53 H-9 C E-10 C-1 *Q E-32 C-2 0 E-54 SPARE _.0......._ ___ _ E-11 C-4 0 E-33 C-3 Q E-55 SPARE _..Q_.._ ___ _ E-12 B-4 C E-34 B-2 0 E-56 K-1 0 --=-----E -l 3 B-8 E.-35 H-7 () E-57 C-7 Q --=-----E -14 D-5 C E-36 SPARE 0 E-58 SPARE Q E -l 5 F-1 __ E-37 D-3 __ o;;..._ ____ E-59 H-3 _._O:;..,__ ___ _ E-16 D-7 _-ll:V;....*---- E-38 H-8 _.....iQ"'------ E-60 I-3 -..JO....:;_ ___ _ E-17 F-3 [, . E-3.9 H-6 ---o:c?-.....-1_...Q..__ ___ E-61 I-2 fi°I --=------- I -=lJ;.__ ____ _ E-18 A-3 __ o_* ____ E-40 A-4 0 E-62 I-1 __.. . ..:::;o::;__ ___ _ E-19 F-2 6 E-41 D-2 __ O _____ E-63 H-2 Q _ _:;...______ E-20 A-7 __ o;;:;._ ____ E-42 A-8 __ o _____ E-64 B-1 _"""o ______ _ E-21 F-4 _ __::;.{) ______ E-43 D-1 _0"'------ E-65 H-1 E-22 RM Sys. Q E-44, SPARE .....;()::;,__ _____ E-66 E-1 Tubing __ .;.::,_., ___ 13 o 1 Air Lock / ( # 11 Val. Rrn.) Elec.Pen(2) D E-67 E-2 __ o ___ _ 100 1 Air Lock I Elec .Pen(2) 0 (#12 Val.Rm) > NOTE: All penetrations are accessible when is operating. Ml6E Attachment 3 Rev.* Page 6 of 15 5UMMARY (.) )919 OUTAG-E NO. 1 AND 2 UNIT 1n MECHANICAL PENETRATION NUMERICAL LIST aJ Ref.' Dwq. 240655 PEN. NO. TEST VAL. NO. PEN. NO. TEST VAL. NO. 4: a.. 1 760 CJ 32 2490 Q 2 761 t:J 33 2491 0 3 2465 0 34 2492 CJ 4 2466 0 35 2493 a 5 2467 C!:J 36 2494 0 6 2468 D 37 2495. C) ..... *. 7 2469 0 38 2432 0 8 2470 e> 39 2497 C!) 9 2471 t:!J 40 2498 Cl 10 2472 41 2499 CJ 11 2473 (') 42 2500 0 12 2474 0 43 2501 0 13 2475 o* 44 2502 0 14 2476 C> 45 2503 0 c* 15 2477 a 46 2504 CJ 16 2478 CJ 47 2505 CJ 17 . 2479 0 48 2506 CJ 18 2480 0 49* 2507 CJ 19 2481 0 50 2508 0 20 2482 () 51 2509 0 21 2483 0 52 2510 CJ 22 2484 CJ 53 2511 {) 23 2485 0 54 2512 0 24 2486 0 55 2513 0 25 2487 D 56 2514 CJ 26 2488 <!) 57 2515 CJ 27 2489 CJ 58 2516 0 28 2490 0 59 2517 C> 29 2535 0 60 2518 CJ 30 2536 CJ 61 2519 0

  • 31 2522 0 62 2520 0 ; -,/ Ml6E Attac::hment 3 Pagelo of 15 Rev. 13 .. *. ,*-.....

SUMMARY

1919 REFUE.L\NGOUTAGE PEN. NO. TEST VAL. NO. PEN. NO. TEST VAL. NO. 63 2521 a 68 2525 64 2458 0 69 2526 65 24-59 /,T, r. 70 2527 CJ 66 2523 CJ 71 2528 .0 67 2524 0 Fuel Trans. Tube Blank Flange 0 Equipment Hatch () 11 & 2.1SJ44 Val. Rm. Cvr. 0 12 & 22SJ44 Val. Rm. cvr. I 6tJ 1 /f,,/t L:a c/c: I 3o 1 A1/t A.ccrc ,/ Attachment 3 Page 11 of

  • 15 Rev. 13 VALVES PREV. LEAK PRESENT LEAK DIFFERENCE

+ -1 2 3 1 2 3 1 2 3 1 -11CA330 --123.0 --0.0 --123.0 -12CA330 --4.0 --0.0 --4.0 -1CC113 -----10.0 0 -10.0 -1CC215 -----I -1CC117 1CC118 -82.0 72.0 -755 758 +676.0 1CC190, 208 1CC131 -1.0 0.0 -443.0 120.0 -+442.0 1CC186, 187 1CC136 -100.0 30.0 -53.0 0.0 --47.0 1CV3, 4, 5 1CV7 -14.0 0.0 -86.0 0.0 -+ 72.0 1CV74 1CV69 No Prev. 0.0 3.0 0.0 -+ 3.0 Test 1CV284, 296 1CV116 -I 106.0 0.0 -653.0 48.0 -+547.0 -1DR29 --3.0 --29.0 -+ 26.0 -1FP147 --300.0 --76.0 --224.0 -11GB4 --2.0 --231.0 -+229.0 -12GB4 I --0.0 ---13GB4 I 33.0 581.0 +548.0 -I ------14GB4 I --0.0 --0.0 --1NT26 1NT25 -Not 14.0 -222.0 25.0 -+208.0 I Tested I 1NT34 1NT32 I Not 1. 0 225.0 105.0 +224.0 I ---I I Tested I 1PR17 1PR18 I -28.0 68.0 -28.0 74.0 -+ 6.0 I 1SJ123 1SJ53, 60 -5.0 10.0 -0.0 o.o* --10.0 1SS103 1SS27 -0.0 0.0 -0.0 0.0 --1SS104 1SS33 -22.0 11.0 -0.0 9.0 --13.0 ----------------I . .' PAG-E 5 E 0 Hi N 1 1SS107 lSSllO -------1VC7 lVCll 1WL12 1WL16 1WL96 1WL98 1WR81 ' VALVES 2 1SS49 1SS64 11SS94 12SS94 13SS94 14SS94 lVCl 1VC4 1VC5 1VC8 1VC12 1WL13 1WL17 1WL97 1WL99, 108 1WR80 I I I I I I I PREV. LEAK 3 1 2 -3.0 LO -4.0 3.0 --0.0 --0.0 --0.0 --0.0 --2.0 --0.0 --792.0 -0.0 0.0 -0.0 0.0 -73.0 95.0 -2.0 8.0 -4.0 0.0 -0.0 16.0 -No Prev. 13.0 Test PRESENT LEAK DIFFERENCE + -3 1 2 3 ( -8.0 7.0 -+ 5.0 -o.o o.o --4.0 --0.0 ----0.0 ----0.0 ----0.0 ----0.0 --2.0 --0.0 ----22.0 --770. 0 -0.0 0.0 ---0.0 0.0 --126.0 9LO -+ 3LO -0.0 o.o --8.0 -184.0 154.0 -+180.0 -OLO 0.0 --16.0 -19.0 LO -+ 6.0 ---------* : PAGES r-}}