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i, l
SUSQUEHANNA STEAN ELECTRIC STATIONPENNSYLVANIA POWER,AND L'IGHT CONPANY
BERN ICK ~ PENNSYLVANIA "
4 ~
REACTOR 'CONTAINMENT BUILDING
INTEGRATED LEAKAGE RATE TEST,
UNIT 2
FINAL REPORT
Bechtel Power CorporationNovember i985
Socket@ M-~~ ~Control @ 8 'LC'~»>~>>USE o '9 DOCQlllBllbREGUIATORY OCKH Fll.E
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TABLE OF CONTENTS
i . 0 INTRODUCTION
2. 0 TEST SYNOPSIS
3.0 TEST DATA SUMMARY,
4. 0 ANALYSIS AND INTERPRETATION
5.0 REFERENCES
APPENDICES
BECHTEL ILRT'OMPUTER PROGRAM SUMMARY
D
ILRT Stab'ilization Data
ILRT Summary Data
ILRT CalculationsMass Point AnalysisTotal Time AnalysisTrend Report
Veri%ication Flow TestSummary DataMass Point AnalysisTotal Time Analysis
ILRT PLOTSTemperature vs TimePressure vs TimeVapor Pressure vs TimeAir Mass vs TimeMass Point Leakage RateTotal Time Leakage Rate
vsvs
TimeTime
H
Twenty-four Hour DataSummary DataMass Point AnalysisPlots
Air Mass vs TimeTemperature vs TimeMass Point Leakage Rate vs Time
Bypass TestSummary DataTotal Time Analysis
Type B and C Leakage Rate Test Results
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1.0 INTRODUCTION
Successful preoperational Integrated Leakage Rate (ILRT) and DrywellBypass Tests were conducted on the Susquehanna Steam Electric Station(SSES) containment between November 1 and November 3, 1983. Thesetests were performed to demonstrate that the containment leakage anddrywell bypass leakage area under prescribed postaccident conditionsdo not exceed the allowable values specified in the SSES Unit 2 FSAR(Reference 1) and SSES Technical Specifications (Reference 2).
The tests were conducted in accordance with the requirements of theILRT procedure (Reference 3), Appendix J to 10CFR50 (Reference 4),ANSI 56. 8 (Ref erence 5), and BN-TOP-1 (Ref erence 6) . Test results,which satisfied all acceptance criteria are summarized below.
Test Results Allowab le
ILRT Nass Point Leakage RatewILRT Mass Point UCL+ILRT Total Time Leakage Rate+ILRT Total Time UCL+Verification Nass Point RateVerification Total Time RateDrywell Bypass Area
0.367//day0.370%/day0.375//day0.432%/day1.093//day1.080//day0.002 sq in
0. 750//day0. 750%/day0. 750%/day0.750%/day1. 361-0. 861%/day1.370-0.870%/day0.770 sq in
include penalties for nonstandard'lignments and water levelchanges of 0.036%/day.
A summary of the test events and test rhronology are presented inSection 2.0, Test Synopsis. Plant information, technical data, testresults, and measurement system information are presented in Section3.0, Test Data Summary. Test, results are compared to the AcceptanceCriteria in Section 4.0, Analysis and Interpretation. Referenceddocuments are list in Section 5.0, References.
2. 0 TEST SYNOPSIS
The containment was isolated by aligning systems in the specifiedpostaccident modes; e><cept as noted in Section 3.C. 13. Prior topressurization the drywell sump water levels were measured.Containment pressurization started at 0136 on November 1, 1%83.During pressurization the containment ventilation fans were running.Cooling water to containment coolers was not necessary duringpressuization or during the ILRT to maintain containment temperaturestability. At 10 psig, all evternal penetration areas were checkedfor leakage. Leakage was observed at a swagelok fitting on the TIPinstrument line, penetration X-35A, and was ~topped by tightening thefitting. Test pressure <46.5 psig) was reached at 0930 on November 1 ~
The pressuri'ation line was isolated from containmant and vented. Thecontainment ventilation fans were stopped and the the stabilizationperiod started.The temperature stabilization criteria of References 5 and 6 weresatisfied during the four hour period from 0930 to 1330 on November1.
At the request of SSES, a full twenty-four hours of data wererecorded in order to demonstrate that diurnal effects were notsignificant and that 8 hours of data was sufficient to accuratelycalculate the containment leakage rate. The last eight hours of thisdata was used for the ILRT.
The ILRT test period began at 0530 on November 2. Initial testpressure was 46.3 psig. Containment pressure and temperature weremeasured at 15 minute intervals using precision devices. Reactorvessel, supression pool, and drywell equipment drain tank waterlevels, and CRD leakage rates were measures at one hour intervals.The ILRT was terminated at 1330 on November 2, after eight hours ofdata had satisfied all leakage rate acceptance criteria.The verification test was initiated by continuously venting 9.2 SCFMof air from the containment through a flow meter, 'and allowing testconditions to stabilize for one hour. The new leakage rate calculatedusing 4 hours of data from 1500 to 1900 on November 2, had verifiedthe per Formance of the instrumentation system.
The drywell was depressurized to Drywell Bypass Test pressure (4.5psig) ~ After isolating the drywell, the supression pool wasdepressurized to 0 psig and isolated. Following a one hourstabilation period the Drywell Bypass Test period began at 1300 onNovember 3. The test: was terminated at 1700 on November 3 after 4houl 5 of data demonstrated an acceptable bypass area.
3.0 TEST DATA SUMMARY
A. Pl ant Informati on
OwnersPlant!LocationsContainment TypesNSSS Supplier, Type!Date Test Completed!
B. Technical Data
Pennsylvania Power and LightSusquehanna Steam Electric StationBerwick, PennsylvaniaMark IlGeneral Electric, BWRNovember 3, 1983
1 ~ Drywell Net Free Air Volume2. Supression Pool Net Free Air Volume
Design Pressure4. Peak Accident Pressure, Pa5. Containment ILRT Average Temperature Limits
239,600 cu ft171,539 cu ft+53 psig45 psig60 — 120 F
+ Free air volume corresponding to a supression pool water level of20'".C. Test Results — Type A Test
1. Test Method Absolute
2. Data Anal ysi s Techni que
3. Test Pressure
4. Maximum Allowable Leakage Rate, La
5. 75/ of La
6. Integrated Leakage Rate Test Results
Mass Point perANSI/ANS 56.8-1981,andTotal Time per BN-TOP-1
, 46. 3 psi g
1.00//day
Oe75//day
Leakage RateMass Point Analysis 0.331//dayTotal Time Analysis 0.339%/day
+ UCL ~95% Upper Confidence Level
7. CRD Leakage
UCL+0.334//day0.396//day
CRD leakage varied between 1.57 and 1.24 gal/min at 1330 onNovember 1 and 1330 on November 2 respectively. The CRD leakageis included in the calculated leakage rates.
8. Imposed VerificationLeakage Rate
4
0. 770//day (9. 20 SCFM)
9. Veri fcation Test Results
Leakage RateMass Point Analysis 1.093//dayTotal Time Analysis 1.080//day
10. Verification Test LimitsUpper+
Mass Point Analysis 1.361%/dayTotal Time Analysis 1.370//day
+ Upper Limit ~ Lo + Lam + 0.25LaLower Limit ~ Lo + Lam — 0.25La
Lower+0. 861%/day0. 870%/day
11 'eport Printouts
The report printouts and data plots for the ILRT and verificationtest calculations are provided in Appendices B-F.
12. Containment Water Level Changes
a. Supression Pool
Start 0530 level ~ 20' 15/16"End 1330 level ~ 20'"
b. Equipment Drain Tank
Start 0530 level ~ 45/End 1330 level ~ 55/
c. Drywell SumpA
Start 0530 level ~ 0"End 1330 l'evel ~ 0"
BQ II
Q II
13. Penetrations not in post-LOCA Alignment During ILRT
PenetrationX53X54X61A
SystemRBCW SupplyRBCW ReturnILRT Verification Flaw
Leakage Rate540.5 SCCM
1699.0 SCCM6.65 SCCM
D. Test Results — Drywel 1 Bypass Test
1. Test Method
2. Data Analysis Technique
Test. PressureDrywel 1
Supression Pool
Absolute
Total Time perProcedure P259.2A
4.5 psig0.0 psig
4. Maximum Allowable Bypass Area
5. Calculated Bypass Area
6. Repor t. Pr in tout s
0. 770 sq in
0. 002 aq in
The report printuuts fur the Drywell Bypass Area Teat are providedin Appendix H.
E. Teat Results — Type B and C
A summary fo preuperatiunal local leakage rate test results isprovided in Appendix I.
F. Integrated Leakage Rate Measurement System
Instrument Description(no. of sensors)
1. AbsolutePressure(2)
Mensor QuartzMunometerModel Nu. CEC402
Range:Accuracy:Bensi tivi tysRepeatabilitysCalibration Dates
0-100 psia0.020 psia0. 001 psi a0. 001 psi a10-24-83
'.
Drybul bTemperature(24)
~'usemont RTDModel Nn. 78-65-17
Range<Accuracy:Sensitivity:RepeatibilitysCalibration Dates
60-120 F0.1 F0.1 F0. 01~F9-11-83
DewpointTemperature(9) %
EGhGModel No. 660-S2
Range:Accuracy!BensitivitysRepeatibilityiCalibration Dates
32-120 F0.54 F0.54 F0'1~F9-20-83
4. Flow Meter(1)
KurzModel No. 500-9
RangerAccuracycSensitivitysRepeatibilitysCalibration Datet
0-10 acfm0.1 scfm0 ~ 04 scf m
O. 01 scf m10-16-83
+ One drybulb and two dewcell sensors mal functioned during theILRT and were not used in the leakage rate calculations. Theirvolume fractions were redistributed to adjacent sensors.
Drybulb and dewpoint temperature sensor locations and volumefractions are provided in Table 1.
4.0 ANALYSIS AND INTERPRETATION
4. 1 ILRT Test
During the ILRT, three penetrations were not in post-LOCA alignment.The penetrations together'ith their Type C leakage rates are givenbe 1 ow!
Penetration
X53X54X61A
RBCN SupplyRBCN ReturnILRT Verification Flow
Leakage Rate
540. 5 SCCA1699. 0 SCCN
6. 65 SCCN
2246 15 SCCM<0.0067%/day)
The following containment water level changes were measured at thestart and end of the ILRTs
1. Supression Pool
Start 0530 level ~ 20' 15/16"End 1330 level ~ 20'"
Difference ~ 1/16"
~ Volume decrease <439. 75 cu ft/in) ~ 27. 5 cu ft(.020//day)
2. Equipment Drain Tank
Start 0530 level ~ 45%End 1330 level ~ 55%
Volume decrease (1.2 cu ft//)
Drywell Sump
Difference ~ 10/
12.0 cu ft.<.009%/day)
No volume decrease, therefore no correction.The total leakage rate correction for penetrations not in post-LOCAalignment and water level changes is 0.036//day.
1
The calculated leakage rates during the ILRT were 0.331%/day (m'asspoint) and 0.339%/day (total time). The calculated 95/ upperconfidence levels were 0.334//day (mass point) and 0.396//day (totaltime>. Adding the total leakage rate corrections for penetrations notin past-LOCA alignment and containment ~ater level changes yields thecorrected leakage rates as follows:
CalculatedCorrectionsCorrected
Leakage Rates,Nass Point
Leakage Rate UCL0.33l 0.3340 036 O. 0360. 367 0. 370
//dayTotal Time
Leakage Rate UCL0.339 0. 3960. 036 0. 0360. 375 0 ~ 432
Since the corrected 95/ upper confidence levels for both mass pointand total time are less than .75La (0.75//day), the test resultsdemonstrate the leakage through the primary containment and systemsand components penetrating primary containment, do not exceed theallowable leakage rates specifies in the Susquehanna Steam Electric,Unit 2 FSAR and Technical Specifications.
4. 2 ISB CALCULATION
A. Test Parameters
La ~ 1. 00//dayP ~ 60. 5 psi aT a 547uRTdp ~ 73 Ft > 8e0 Hro
Allowable Leakage RatePressureDrybulb TemperatureDewpoint TemperatureTest Duration
B. Instrument Parameters
Total Absolute Pressure
No. oW sensors tSensitivity (Ep) c
Repeatability (Ep) s
1
0. 001 psi a0. 001 psi a
ep ~ ( (0. 001=+0. 00 1 ~) /1) ~ ~~ ~ 0. 001414
2. Mater Vapor Pressure
No, of sensorssSensitivity (Epv)cRepeatability (Epv)cVapor pressure change 8 73~F
70 54 F0.01 F0. 01373 psi a/ F
epv > 0 ~ 01373 ( <0. 54~+0. 01~) /7) ~ ~~ < 0. 002803
3. Temperature
No. oW sensor s!Sensitivity (ET):Repeatabi 1 ity (fT)
2301F0.01 F
eT a « 0 1 'p0 Of ) /23) *<~ = 0. 02096
C. ISB
ISB ~ (2400/8) <2( <0.001414/60 5) =+ (0. 002803/60.5) =+
(Oe 02096/547) ~) ) i~= ~ 0. 027 //DAY
4.3 TNENTY-FOUR HOUR DATA
A full twenty-four hours of data was taken in order to demonstratethat diurnal effects were not significant and that eight hours ofdata was sufficient to accurately measure the containment leakagerate. The twenty-four houl s of data and calculated ~ leakage rates arepresented in Appendix B.
The temperature and air mass vs. time plots clearly demonstrate thatno diurnal effects existed. During the twenty-four hour period, thecontainment temperature decreased 1 F, the rate of changedecreasing with time, and the air mass decreased linearly> indicatinga constant leakage rate.The absence of diurnal effects is attributed to the presence of asecondary containment and to not using cooling water. These twoconditions effectively isolate the containment from any externalenvironment changes and yield very stable test conditions.
The mass point leakage rate plot shows that the leakage rate remainedessentially constant for the entire test period data and thereforedemonstrates that eight hours of data is sufficient to accuratelycalculate the leakage rate.
5.0 REFERENCES
f. Susquehanna Steam Electric Station, FSAR.
2. Susquehanna Steam Electric Station, Technical Specifications.3. Susquehanna Steam Electric Station Procedure P25'7.2A, Containment
Integrated Leakage Rate Test.
4. Code of Federal Regulations, Title l0, Part 50, Appendix J,Primary Reactor Containment Leakage Rate Testing d'or WaterCooled'owerReactors.
5. ANSI/ANS 56. B-i'PBi, Containment System Leakage TestingRequirements.
Ih. Bechtel Topical Report BN-TOP-I„Testing Criteria d'or IntegratedLeakage Rate Testing o$ Primary Containment Structures forNuclear Power Plants, Revision i „ i972 ~
-10-
TABLE 1
DRYBULB AND DEWPOINT TENPERATURE SENSOR LOCATIONS
SensorNo.
VolumeEl evati on Az imut h Distance From Fractions
(ft) 'degrees) Center (ft) (Procedure)
DRYBULB
Volume++Fractions
( ILRT)
1
23
67
10ii12131415161718192021222324
boo67569067567569070971171371271272572772872774774674877577578478579'P798
260
120180250300
85180290
090
350170280
20105250210
10100270
90270
322832
5323229'2
3130
22526252624272217 ~ 5182020
88
0,0740.0740. 074Oo 0220. 0740.0740.0470.0470. 0470. 0470. 0220. 0420. 0410. 0410 ~ 0420. 0340. 034O. 0340. 0340. 0340. 014O. 0150. 0160. 017
'.0990. 0000. 0990. 0240. 0990. 0990. 0450 ~ 0450. 0450. 0450. 0210.040Oo 0390. 0400. 0320 ~ 0320. 0330. 033Oo 0330. 0330. 0130. 014'.0150. 016
23
5678
65'06'PO69069071272874875679'P
60240120300290350250180
'PO
DEWPOINT
32323232302622198
0. 0980. 0980. 098O. 099O. 2100. 1660. 0990. 09'20. 033
0. 0000. 140O. 1400. 1400. 2080. 1670 1030.102O.OOO
Malfunctioning sensors — not used for leakage rate calculations.++ Volume fractions reflect the suppression pool free air volume
during the ILRT (171530 cu ft) and the redistribution of volumefraction for the malfunctioning sensors.
-11-
APPENDIX A
DESCRIPTION OF BECHTEL ILRT COMPUTER PROGRAM
A. Pro ram and Pe ort Descriotion
The Bechtel ILRT computer program is used to determine the inte-grated leakage rate of a nuclear primary containment structure.The program is used to compute leakage rate based on input valuesof time, free air volume, containment atmosphere total pressure,drybulb temperature, and dewpoint temperature (water vapor pressure).Leakage rate is computed using the Absolute Method as defined inANSI/ANS 56.8-1981, "Containment System Leakage Testing Requirements"and BN-TOP-1, Rev 1, ~ "Testing Criteria for Integrated Leakage RateTesting of Primary Containment Structures for Nuclear Power Plants".The program is designed to allow the user to evaluate containmentleakage rate test results at the jobsite during containment leakagetesting. Current leakage rate values may be obtained at any timeduring the testing period using one of two computational methods,yielding three difrerent report printouts.
2 ~ In the first printout, the Total Time Report, leakage rate is com-puted from initial values of free air volume, containment atmospheredrybulb temperature and partial pressure of dry air, the latestvalues of the same parameters, and elapsed time. These individuallycomputed leakage rates are statistically averaged using linear re-gression by the method of least squares. The Total Time Method isthe computational technique upon which 'the short duration testcriteria of BN-TOP-l, Rev', "Testing Criteria for IntegratedLeakage Rate Testirg of Primary Containment Structures for NuclearPower Plant," are based.
3 0
4 ~
The second printout is the Mass Point Report and is based on theMass Point Analysis Technique described in ANSI/ANS 56.8-1981,
Containment'System Leakage Testing Requirements." The mass of dryair in the containment is computed at each data point (time) usingthe Equation of State, from current values of containment atmospheredrybulb temperature and partial pressure of dry air. Contained massis "plotted" versus time and a regression line is fit to the datausing the method of least squares. Leakage rate is determined fromthe statistically derived slope and intercept of the regression 1ine.
The third printout, the Trend Report, is a summary of leakage ratevalues based on Total time and Mass Point computations presentedas a function of number of data points and elapsed time (test dura-tion). The Trend Report provides all leakage rate values requiredfor comparision to the acceptance criteria of BN-TOP-1 for conductof a short duration test.
SU&43 A-1
5. The program generates a predictor report based on Reference 7. The"predictor" is an estimate of the upper bound on the change in masspoint calculated leakage rate which will occur during the next fourhours. The "estimate is based on the mass point calculated leakagerates and 95X UCLs during the previous four hours.
6. The program is written in a high level language (FORTRAN) and isdesigned for use on a micro-computer with direct data input fromthe data acquisition system. Brief descriptions of program use,formulae used for leakage rate computations, and program logic areprovided, in the following paragraphs.
B. E lanation of Pro ram
1. The Bechtel ILRT computer program is written, for use by experi-enced ILRT personnel, to determine containment integrated leakagerates based on the Absolute Method described in ANSI/ANS 56.8-1981 and BN-TOP-l.
2. Information loaded into the program prior to or at the start of thetest:
a. Number of containment. atmosphere drybulb temperature sensors,dewpoint temperature (water vapor pressure) sensors and pressuregages to be used in leakage rate computations for the specifictest
b. Volume fractions assigned to each of the above sensors
c. Calibration data for above sensors
d. Tes t titlee. Test pressure
f. Maximum allowable leakage rate at test pressure
3. Data received from the data acquistion system during the test, andused to compute leakage rates:
a. Time anddate'.
Containment atmosphere drybulb temperatures
c. Containment atmosphere pressure(s)
d. Containment atmosphere dewpoint temperatures
e. Containment free air volume.
4 ~ After all data at a given time are received , a Summary of MeasuredData report (refer to "Program Logic," Paragraph D, "Data" optioncommand) is printed.
SU&43 A-2
5. If drybulb and dewpoint temperature sensors should fail during thetest, the data from the sensor(s) are not used. The volume frac-tions for the remaining sensors are recomputed and reloaded intothe program for use in ensuing leakage rate computations.
C. Leaka e Rate Formulae
1. Computation Using the Total Time Method:
a. Measured 'leakage rate from data:
P1V1 ~ W1RT1
Pivi WiRTi
2400 (Wl - Wi)Li
b,ti Wl
(2)
(3)
Solving for Wl and Wi and substituting equations (1) and(2) into (3) yields:
2400 T1PiViLL —1 ——
Iti TiP1V1(4)
where
Wl, Wi = Weight of contained mass of dry air at times tl andr.i, res pe ct ive ly, 1 bm.
Tl, Ti ~ Containment atmosphere drybulb temperature at timestl and ti, respectively, 'R.
Pl, Pi Partial pressure of the dry air component of the con-tainment atmosphere at times tl and ti, respectively,psia.
Vl, Vi ~ Containment free air volume at times tl and ti, respec-tively (constant or variable during the test), ft3.
tl, ti ~ Time at 1 and i data points respectively, hr.st th
gati Elapsed time from tl to ti, hr.
R ~ Specific gas constant for air ~ 53.35 ft.lbf/ibm.'R.
Li ~ Measured leakage rate computed during time intervaltl to ti, wt.l/day.
To reduce truncation error, the computer program usesthe following equivalent formulation:
2400 bWi
SU&43
where
5Wi
Wl
Wi — Wl
Wl
SVi ap~ViT
Pl Vl P1V1 Tl
QTil+Ti
gPi Pi — PlgVi ~ Vi — VlQTi Ti T]
b. Calculated leakage rate from regression analysis:
L a+ bbtN
where
L ~ Calculated leakage rate, wt.//day, as determined from the regressionline.
a (gLi — b~ ti)/N
N(gL~ ti) — (gLi)(Q, ti)b
N(~ ti ) — (~ ti)N ~ Number of data points
N
E Zi lc. 95% upper confidence limit on the calculated leakage rate:
UCL = a+ bgtN+ S
L'here
UCL ~ 95% upper confidence limit wt.%/day, at elapsed time gtN.
SU&43 A-4
For gtN ( 24
S t0.025;N-2 [(gLi — agLi — bgLigti)/(N-2)] ' [1 + 1 + (gtN-gt) / (9a)1!2 2
L N
(~ti — (~ti) /N)]
where t0.025;N-2 = 1.95996 + 2.37226 + 2.82250N-2 ~(H-2)
For AtN > 24
S t0 025'N 2 [(<Li a<Li b<Lg,ti)/(N 2)] x [1 +(gtN At) /2 1/2 2
L N
(~ ti2 (~ ti)2/N) ]1/2
(9b)
where t0.025;N-2 ~1.6449(N-2)2 ~ 3.5283(N-2) + 0.85602
(N-2)2 + 1.2209(N-2) — 1.5162
Li Calculated leakage rate computed using equation (5) at total elapsedtime <ti, %/day.
AtN
2. Computation using the Mass Point Method
a. Contained mass of dry air from data:
Wi = 144 P ~ V.RTi
where
All symbols as previously defined.
b. Calculated leakage rate from regression analysis, W a + b At
(10)
bL M -2400—
a
where
L Calculated leakage rate, wt.%/day, as determined from theregression line.
SU-043 A-5
a (EW~-be tx)
N(EWig ti) — (EWi)(e ti)b
N(e ti ) — (E| ti)~ti ~ Total elapsed time at time of i data point, hr
N ~ Number of data points
Wi ~ Contained mass of dry air at i data point, ibm, as computed fromequation (10).
N
E Ei 1
To reduce truncation error,'he computer program uses the followingequivalent formulation:
bwi ba Wl .1 + (E ———E gati)/N
Wl Wl
b~,wi
b,Wg,,b WiN (E b,ti) — E —E gati
Wi'iN(e ti ) — (Qh,ti)
gwiwhere is as previously defined.
Wl
c. 95% upper confidence limit.-2400
UCL (b — Sb)a
where
, UCL ~ 95% upper confidence limit, wt.%/day.
SU&43 A-6
1/2SN
Sb t0 ~ 025 N 2 [NZd ti (EA ti) ] (17)
where t0.025;N-2 1.6449(N-2) + 3.5283 (N-2) + 0.85602
(N-2)2 + 1.2209 (N-2) — 1.5162
$ aE[Wi — (a + b b',tj)]
N-2
1/2
1~ Wl —E(AWi/W1) [E(b W./W1)] /N-
N-2
EQWi Wl Ati — EQ Wi Wl 2 ti /Nj2 1/2
E(Ati ) — (E Ati) /N
d. Predictor:2[(UCL-L) + 4 ((A) + 2 SA)j
Predictor100 La
(18)
where
UCL ~ 95X upper confidence limit of mass point calculated leakage rateat end of test
Lm mass point calculated leakage rate at end of test
A ~ value of linear regression analysis slope of mass point calculatedleakage rate vs. time for last 4 hours of test data
SA = linear regression analysis standard deviation of slope
La ~ allowable leakage rate
In terms of clasped time, A t and mass point calculated leakage rateLmi calculated at the end of it" time interval.
SU-043 A-7
1 E Lmi — B E b,tiM 4 hr 4 hr
H E Lmig ti -E Lmi E Ati
4 hr 4 hr 4 hr
M E Ati2 E gati2
4 hr 4 hr
SA
Lmi - A E Lmi - B E Lmi g ti4 hr 4 hr 4 hr
[M-2j [M E 'ti (E gati) )4 hr 4 hr
Lmi ~ mass point calculated leakage rate evaluated using data up totime gati..
E4 hr summation over last 4 hours of test data.
N
EN-M+1
M ~ number of data points for last 4 hours of test.
SU&43 A-8
1. The Bechtel ILRT computer program logic flow is controlled by a setof user options. The user options and a brief description of theirassociated function are presented below.
OPTIONCOMMVH) FUNCTION
After starting the program execution, the user eitherenters the name of the file containing previouslyentered data or initfalizes a new data file.
DATA Enables user to enter raw data. When the systemrequests values of time, volume, temperature, pressureand vapor pressure, the user enters the appropriatedata. After completing the data entry, a summary isprinted out. The user then verifies that the datawere entered correctly. If errors are detected, theuser will then be given the opportunity to correct theerrors. After the user verifies that the data wereentered correctly, a Corrected Data Summary Report oftime, data, average temperature, partial pressure ofdry air, and water vapor pressure is printed.
TREND
TOTAL
MASS
A Trend Report is printed.
A Total Time Report is printed.
A Mass Point Report is printed.TERM Enables user to sign-off temporarily or permanently.All data is saved on a f'le for restarting.CORR Enables user to correct previously entered data.
LIST A Summary Data Report is printed.
Enable the computer to receive the next set of datafrom the data acquisition system directly.
PLOT Enables user to plot summary data, individual sensordata or air mass, versus time.
DELETE
INSERT
Enables user to delete a data point.
Enables user to reinstate a previously deleted datapoint.
VOLFRA
PRED
Enable user to change volume fractions.A pred'ctor report is printed.
SU-043 A-9
OPTIONCOMMAND FUNCTION
TIME - Enable the user to specify the time interval for a .
report or plot.
VERF Enable the user to input imposed leakage rate andcalcaluted ILPT lea~~e rates at start of verificationtes t.
E. COMPUTER REPORT AND DATA PRINTOUT
MASS POINT REPORT-
The Mass Point Report presents leakage rate data (wtX/day) as deter-mined by the Mass Point Method. The "Calculated Leakage Rate" is thevalue determined from the regression analysis. The "Containment Air
ss" values are the masses, of dry air in the containment (ibm).These air masses, determined from the Equation of State, are used inthe regression analysis.
TOTAL TIME REPORT
The Total Time Report presents data leakage rate (wt%/day) as deter-mined by the Total Time Method. The "Calculated Leakage Rate" is thevalue determined from the regression analysis. The "Measured LeakageRates" are the leakage rate values determined using Total Ti|n calcu"lations. These values of leakage rate are used in the regressionanalysis.
TREND REPORT
The Trend Report presents leakage rates as determined by the MassPoint and Total Time methods in percent of the initial contained massof dry air per day (wt%/day), versus elapsed time (hours) and numberof data points.
PREDICTOR REPORT'I
The predictor reports presents a predicted upper bound on the changein calculated mass point leakage rate over the next four hours.
SUMMARY DATA REPORT
The Summary Data report presents the actual data used to calculateleakage rates by the various methods described in the "Computer Program"section of this report. The six column headings are TL~K, DATE, TEMP,PRESSURE, VPRS, and VOLUME and contain data defined as follows:
SU"043 A-10
1. TIME:
2. DATE:
Time in 24-hour notations (hours and minutes).
Calendar date (month and day).
3. TEHP: Containment weighted-average drybulb temperature inabsolute units, degrees Rankine ('R).
4. PRESSURE: Partial pressure of the dry air component of the con-tainment atmosphere in absolute units (psia).
5 ~ VPRS: Partial pressure of water vapor of the containmentatmosphere in absolute units (psia).
6. VOLUME: Containment free air volume (cu. ft.).
F. SUMMARY OF MEASURED DATA AND SUMMARY OF CORRECTED DATA
The Summary of Measured Data presents the individual containnentatmosphere drybulb temperatures, dewpoint temperatures, absolutetotal pressure and free air volume measured at the time and date.
1. TEMP 1 through TEMP .N are the drybulb temperatures, whereN No. of RTD's. The values in the right-hand column aretemperatures ('F), multiplied by 100, as read from the dataacquisition system (DAS). The values in the left-hand columnare the corrected temperatures expressed in absolute units('R) .
2. PRES 1 through PRES N are the "otal pressures, absolute, were N = No.of pressure s'ensors. The right-hand value, in parentheses, is anumber in counts as read from the DAS. This count value is convertedto a value in psia by the computer via the insgrument's calibrationtable, counts versus psia. The left-hand column is the absolutetotal pressure, psia.
3. VPRS 1 through VPRS N are the dewpoint temperatures (watervapor pressures), where N = No. of dewpoint ~ sensors. Thevalues in the right-hand column are temperatures ('F), multi-plied by 100 as read from the DAS. The values in the left-hand column are the water vapor pressures (psia) from thesteam tables for saturated steam corresponding to the dewpoint(saturation) temperatures in the center column.
The Summary of Corrected Data presents corrected temperature andpressure values and calculated air mass determined as follows:
1. TEMPERATURE ('R) is the volume weighted average containmentatmosphere drybulb temperature derived from TEMP 1 throughTEMP N.
DH-165 A-11.
2. CORRECTED PRESSURE (psia) is the partial pressure of the dry aircomponent of the containment atmosphere, absolute. The volumeweighted average containment atmosphere water vapor pressure issubtracted from the volume weighted average total pressure, yieldingthe partial pressure of the dry air.
3 ~ VAPOR PRESSURE (psia) is the volume weighted average contain-ment atmosphere water vapor pressure, absolute derived frauVPRS 1 through VPRS N.
4. VOLUME (cu. ft.) is the containment free air volume.
5. CONTAINMENT AIR MASS (ibm) is the calculated mass of dry airin the containment. The mass of dry air is calculated usingthe containment free air volume and the above TEMPERATURE andCORRRECTED PRESSURE of the dry air.
SU-043 A-12
APPENDIX 'B
SUSQUEHANNA UNIT 2 ILRTTEMPERATURE STABILIZATION
FROM A STARTINB TIME AND DATE OF: 930 1101 1983
TIME TEMP ANSI BN-TOP-1(HOURS) ( R) AVE T AVE T DIFF AVE T
(4HRS) (1HR) (2HRS)
.00~ 2550
.751 ~ 001. 251. 501 ~ 752. 002 ~ 252. 502. 753 ~ 003. 25
03 ~ 754. 00
INDICATES
550. 56549. 85549. 51549.33549 '0549 '9.549.00548.91548. 84548.78548. 73548.68548.63548. 58548. 54548 '1548 '7TEMPERA
—.524 —.160 —~ 36~
TURE STABILIZATION HAS
—.862+—.531+—.390+—.328+—.287+—
~ 256+—,"228~—.203+—.093+
BEEN SATISFIED
APPENDIX C
SUSQUEHANNA UNIT 2SUMMARY DATA
ILRT
ALMAX = i. 000VRATET = 1. 110
VOLUME = 41 1 130.VRATEN =l. 101
TINE530545
630
700715730745800815830845900915930945
10}5103010451,100ll}511301145120012151230}245130013151330
DATE110211021102i}021102110211021102}102}1021102i}02i}021102110211021102l}0211021102110211021102i}021102110211021102}1021}021102l}021102
TENP547.603547.595547.590547.582547:576547.572547.574547 '64547.558547.549547 ~ 545547 ~ 547547. 539547. 536547.531547.521547 '19547.520547 ~ 517547.508547.510547.506'547 '04547 F 496547.494547.492547.487547.483547.478547.470547.472547.464547.460
PRESSURE60 '82460. 380460. 377360 ~ 374160. 371360. 367860.366160.362960.360660.35746o.355660.352660.350260.347}60.344860. 343260. 340060.337960.335960.332960 '30460.328360 '25560 '23460.320260.318660. 315060. 312960. 310060. 307760. 304660 '02560 '005
VPRS.4031.4031.4033.4034.4033.4038.4036'. 4038. 4040. 4043. 4041. 4041. 4046. 4047. 4050. 4046. 4048. 4050. 4050. 4050.4055.40 7.4055.4056.4058.4055F 4061.4062.4061.4064~ 4065.4067~ 4067
VOLUNE41}130.411}30.411130.4}1130 ~
411130.411130.4}}13o.4}i}30.411130.4}1130.411130.411130.411130.4 11130.411130.411130.4}}}30.411130.411130.4}l}30.411130.411130.411130.41}130.411130.4}i}30.411130.411130.411130.411130.4}l}30
'11}30.
411130.
APPENDIX D
SUSQUEHANNA UNIT 2 ILRTLEAKAGE RATE (WEIGHT PERCENT/DAY)
MASS POINT ANALYSIS
TIME AND DATE AT START OF TEST:TEST DURATION: 8. 00
530 1102 1983HOURS
TIME TEMP PRESSURE CTMT. AIR NABS LOSS AVERAGE MASS
(R) (PSIA), MASS (LBM) (LBM) LOSS (LBM/HR)
530545600615630645700715730745800815830845900915930945
100010151030104511001115113011451'200121512301245130013151330
547. 603547. 595547. 590547. 582547. 576547. 572547. 574547 ~ 564547. 558547. 549547. 545547 ~ 537547 ~ 539547.. 536547.531547. 521547. 519547 ~ 520547. 517547 ~ 508547. 510547. 506547. 504547. 496547.494547. 492547. 487547. 483547. 478547. 470547.472547.464547.460
60.382460.380460. 377360. 374160. 371360 ~ 367860. 366160.362960.360660.357460.355660.352660.350260.347160.344860.3432*0. 340060 ~ 337960. 335960. 332960.330460.328360.325560. 323460. 320260. 318660 '15060. 312960.310060. 307760.304660.302560.3005
122364 ~
122361.122356.122352 ~
122347'22341.
122337.122333.122330.122325 ~
f22322'22318.
122313.122307.122304.122302.f22297„
122289.122285.122279.f22276122270.f22268
'22262.
f222591 22253 ~
f 2224)122245.f22242
'22235.
122233.122230
2 0 55. 1
4.74 ~ 46 ~ 24.04 ~ 2
-3.14.62.84 ~ 25e35 ~ 63a 51.25 ~ 94.6
3.85.5
5.42 ~ 46.03.06 ~ 23.34 ~ 7
6.52 ~ 53.3
15 ~ 216 ~ 3lb. 718. 317. 917. 817. 1
17. 3lb. 616. 617. 017. 417. 21 b. 4lb. 816. 9lb. 7lb. 616. 9lb. 817. 0lb. 717. 016. 817. 1
lb. 917. 0lb. 817. 1
16. 916. 8
FREE AIR VOLUME USED (CU. FT. )
REGRESSION LINEINTERCEPT (LBM)SLOPE (LBM/HR)
MAXIMUM ALLOWABLE LEAKAGE RATE75% OF MAXIMUM ALI OWABLE LEAKAGE RATETHE UPPER 95/ CONFIDENCE LIMITTHE CALCULATED LEAKAGE RATE
411130.
122364.-16. '9
1. 000~ 750.334.331
APPENDIX D
SUSQUEHANNA UNIT 2 ILRTLEAKAGE RATE (WEIGHT PERCENT/DAY)
TOTAL TIME ANALYSIS
TIME AND DATE AT START OF TEST: 530 1102 1983TEST DURATION: 8. 00 HOURS
TIME TEMP PRESSURE MEASURED(R) (PS IA) LEAKAGE RATE
5305456006156306457V071573074580081583V845900915930945
100010151O30104511001115113011451200121512301245130013151330
547. 603547. 595547. 590547. 582547 ~ 576547.572547.574547 '64547.558547.549'47.545
547.537547.539547 ~ 536547. 531547 ~ 521S47. 519547.520547.517547 '08547 '10547.506547.504547.496547.494S47. 492547. 487547. 483547.478547.470547.472547.464547.460
60. 382460. 380460. 377360. 374160 '71360.367860. 366160. 362960. 360660. 357460. 355660. 352660. 350260 ~ 347160.3448-60.343260.340060. 337960. 335960.332960. 330460. 328360.325560.323460.320260. 318660. 315060.312960. 310060. 307760. 304660. 302560. 3005
. 193
. 297~ 321. 328. 359. 351. 349. 336. 339.326.326.334~ 342~ 337.321.330.331.328.326.332.329~ 333~ 327
. 329~ 335.332.333.330.336~ 331.329
MEAN QF THE MEASURED LEAKAGE RATESMAXIMUM ALLOWABLE LEAKAGE RATE75/ OF MAXIMUM ALLOWABLE LEAKAGE RATETHE UPPER 95/ CONFIDENCE LIMITTHE CALCULATED LEAKAGE RATE
.328l. 000.750.396.339
D-2
I "~
APPENDIX D
SUSQUEHANNA UNIT 2 ILRTTREND REPORT
TIME AND DATE AT START OF TEST: 530 1102 1983
NO. END TOTAL TIME ANALYSISPTS TIME MEAS ~ CALCULATED UCL
NABS POINT ANALYSISCALCULATED UCL
4 6155 6306 6457 7008 715
73010 745ii 80012 81513 83014 84515 90016 91517 93018 94519 100020 101521 103022 104523 iioo24 111525 113026 114527 120028 121529 123030 1245
13OO32 1315
1330
~ 321.328.359.351.349.336
.326
. 326
. 334
. 342~ 337. 321~ 330.331.328.326~ 332.329~ 333~ 427~ 333.329~ 335.332~ 333~ Q40.336.331.329
334'72
378380374371364359357357357352350348347345344
34334234134134134134134034034y
.655~ 529.494.492F 489~ 485.478.470.462.455.450.445.439.434~ 430~ 425.421.418.415.413.410.408~ 406.404.403.401.. 400
. 397
. 396
. 329
. 363~ 366 '
364.356~ 352. 343~ 338. 337~ 340~ 340.334~ 333~ DQ~~ 331.330.330.330.330~ 329.330.330.331. 331~ 331~ 331~ 332
~ 331
.424,. 385. 403
.384~ 373. 366. 358~ 351.348.349.348.343.341.340~ 338.336.336.335335
.334
.334~ 333.334. 334.334.334~ M&5. 334.334
APPENDIX E
SUSQUEHANNA UNIT 2 ILRTSUMMARY DATA
ALMAX = 1. 000VRATET = i. 110
VOLUME = 411130.VRATEM =1. 101
TIME1400}4}5}43014451500151515&015451600161516301645170017151730174518001815183018451900
DATE1}021102110211021102110211021102l}02110211021102110211021}021102110211021}0211021}02
TEMP547.456547.450547.452547. 448547. 443547 ~ 437547. 429547. 434547. 427547.419547.422547.424547.424547.416547.400547.398547.404547.398547.394547.398547.396
PRESSURE60.29}360 '84160.277160. 269160. 262160. 254160. 246960. 240060 ~ 233860. 226860 ~ 219660. 212660. 204760.197760. }90760.182760 '76660.169560.}60560.153360.1464
VPRS.407v.4073.4073.4074.4075.4076~ 4078.4078.4080.4081.4v83.4084.4084.4085.4085.4086.4087.4089.4090F 4093~ 4o92
VOLUME411,130.411130.411130.411130.411130.411130.4}}}30.411130.41 }}30.41 1 130.41,1}30.4}i}30.41}}30.411130.411130.411130.4}}130.411130.41 1130.411130
'11130.
APPENDIX E
SUSQUEHANNA UNIT 2 ILRTLEAKAGE RATE (WEIGHT PERCENT/DAY)
NABS POINT ANALYSIS
TIME AND DATE AT START OF TEST: 1500 }102 1983TEST DURATION: 4.00 HOURS
TIME TEMP PRESSURE CTMT. AIR MASS LOSS AVERAGE MASS(R) (PSIA) NABS (LBM) (LBM) LOSS (LBM/HR)
1500151515301545}60016}5163016451700}7}51,73017451800}8}5183018451900
547. 443547. 437547. 429547. 434547. 427547. 419547.422547.424547 '24547.416547.400547.398547.404547.398547.394547.398547.396
60 ~ 262}60. 254160.246960.240060.233860.2268'0.2196
60.2}2660.204760.197760.190760. 182760.176660.169560.160560 '53360. 1464
122155.122141 ~
}22}28.1221}3.}22}02.122089 ~
122074.122060.122043.122031.}22020 ~
122005.121991.121978 ~
121961.121945.121931.
14. 9}2. 615. 310. 912. 6}
C'14.5
~ 16.2}2. 410 ~ 615. 813. 713. 1
17. 315. 413. 7
59 ~ 555. 057. 053. 653. 054. 254. 856. 1
55. 354. 054. 854. 854. 755 ~ 756. 1
56. 0
FREE AIR VOLUME USED (CU. FT. )
REGRESSION LINEINTERCEPT (LBM)SLOPE (LBM/HR)
VERIFICATION TEST LEAKAGE RATEVERIFICATION TEST LEAKAGE RATETHE CALCULATED LEAKAGE RATE
UPPER LIMITLOWER LIMIT
41 1 130.
122}56.-55. 6
1. 351. 851
1. 093
E-2
APPENDIX E
SUSQUEHANNA UNIT 2 ILRTLEAKAGE RATE (WEIGHT PERCENT/DAY)
TOTAL TIME ANALYSIS
TIME AND DATE AT START OF TEST: 1500 1102 1983TEST DURATION: 4.00 HOURS
TIME TEMP PRESSURE MEASURED(R) (PSIA) LEAKAGE RATE
~ 15001515153015451600161516301645170017151730174518001815183018451900
547. 443547. 437547. 429547. 434547. 427547.419547 '22547.424547.424547.416547.400547.398547.404547.398547.394
,547.398547. 396
60.262160.254160. 246960. 240060. 233860. 226860. 219660. 212660. 204760. 197760. 190760. 182760 ~ 176660. 169560.160560.153360 '464
i. 1681. 0801. 1201. 0541. 0411. 0661. 0761. 1011. 0871. 0611. 0781. 0781. 0741. 0941. 1021 ~ 101
MEAN OF THE MEASURED LEAKAGE RATESVERIFICATION TEST LEAKAGE RATE UPPER LIMITVERIFICATION TEST LEAKAGE RATE LONER LIMITTHE CALCULATED LEAKAGE RATE
1. 0861. 360
. 8601. 080
E-3
APPENDIX F
SUSQUEHANNA UNIT 2 ILRTTEMPERATURE DEGREES F
t
F-1
87.720 87.738 87.757 87.775 87 ~ 793 87.812 87.830 87.848 87 '67 87.88S 87.903 87.922 87.940t
530 s t545 s
600 s
6!5 sl
630 s
645 s
7QQ s
715., s
730 1
745 s
Bhp s
8!5 s
830 1
845 s
900 s
915 s
930 s
945 s
1000 s
1015 s
1030 s
1045 l
1100 l
1115 s
1130 s
145 s
1200 s
1215 1
1230 s
1245 s
!:00 s
1315 s
!33Q s
1345 1
1400 s
141S l
f
1445 s
f500 s
15!S s
1530 s
1545 s
1600 s
fb'cS s t~ 6'tp s
16-".5 s
1700 s
17f5 s
1730 l
1?45 s
"'.184'900
. 87.720 87.738 87,757 87.775 87.793 87.812 87.830 87.848 87.867 87.885 87.903 87.922 87.940
APPENDIX F
SUSQUEHANNA UNIT 2 ILRTPRESSURE PSIA
60 ~ 100
53Q a
545 a
600 s
615 a
630 s
645 a
700 s
715 s
730 s
745 1
800 s
'8}S a
830 l
845 s
900 1
915 a
930 a
945 a
1000 l
1015 s
f030 s
1045 s
1100 l
1115 1
145 s
!200 s
1215 s
1230 s
1245 s
1300 1
1315 s
1330 1
1345 1
1'400 1
14}5 s
1430 l
1445 a
1500 s
1515 s
}530 a
1545 1
1600 s
1615 s
!630 s
1645 a
}700 s
1715'730
'745
s
1800 s
}8}5 a
1830 s
1845 s
1900 s
60.!CQ
60.125 60.150 60.175 60.200 60 '25 60.250 60.275 60.300 60 '25 60.350 60.375 60,400
F-2
60.1?5 60 ~ 150 60. 17S 60.?00 60. 225 60. 250 60. 275 60. 300 '60. 325 60 ~ 350 60. 375 60. 400
APPENDIX F
SUSQUEHANNA UNIT 2 ILRTVAPOR PRESSURE PSIA
"-530 ,'f
03 .403 .404 .405 .405 .405 .406 .407 .407 .407 .408 .409 . .409
54c e
600 a
615 I
630 a
645 a
700 e
715 I
730 s~
745 I
800 s
815 s
830 s
845 I
900 s
915 s
930 s
945 a
1000 s
,.1015 a
1030 1
1045 I
1100 1
11!5 l
~1130 s.~ 1145 l
1200 a
1215 1
1230 1
a
1300 s
1315 s
1330 s
1345 s
1400 1
415
1430 a
1445 s
1500 1
151'5 s
e 5'70 e
1545 s
1600 1
1615 I
1630,1
1645 s
170C a
1715 a
1730 a
1745 s
1800. a
1815 s
1830 s
1845 s
1900 a
F-3
03 .403 .404 .405 .405 .405 .406 .407 .407 a407 .408 e0h
(
.409
}21
53D
545
600
615
630
645
7OD
715
730
745
800
815
830
845
900
915
930
945
1000
. }0)51030
1045
1)oe
1115
130
1145
Boo1215
1230
1245
1300
1315
1330
1345
!400
1415
1430
1445
1500
1515
1530
1545
1600
1615
)630
1645
)700
}715
1730
1745
1800
1815
1830
1845
1900
. 800 121.850 )21.900 121.950t
APPENDIX F
SUSQUEHANNA UNIT 2 ILRlAIRNASS LBH X 1000
122.000 122.050 122,100 122,150 122.200 122.250
F 4
122.300 }22.350 122.400
t
12},800 121 ~ 850 121.900 121.'950 122,000 122.050 122 F 100 122.150 122.200 122.250 . 122.300 1 2.3'.0 }22.4G(
530
545
600
615
630
645
700
715
730
745
800
815
830
845
900
915
930
945
1000
1015
1030
1045
1100
1115
1130
1145
1200
'12151230
1245
1300
1315
1330
.000
APPENDIX F
SUSQUEHANNA UNIT 2 ILRTMASS POINT LEAKAGE RATE(+> AND UCL(/>
.900 1.000
trtr
tr
r
. 100 .200 .300 .400 .500 .600 .700 .800t
1,100 1.200t
.000 .100 - .200 .300 .400 .500 .600 ~ 700 .800 .900 1.000 1.100 1.200
F-5
APPENDIX F
SUSQUEHANNA UNIT 2 ILRTTOTAL TINE LEAKAGE RATE(+> AND UCL(%)
.300 .400 .500 .60b .700 .800 .900t
1.000 1.100 1.200
530 X
545 X
600 X
615 s
630 s
645 1
700'15
I X
730
745 l
800 s X
815 s X
830 I X
845 s X
900 s X
915 s X
930 l X
945 s X
1000 sX
1015 s
1030 s X
1045 l X
1100 s X
1115 s X
1130 s'X
1145 s X
1200 s X
1215 l
1230 s+ X
1245 s
1300 s + X/
1315 s
1330 I
t t t.OOO .1OO .2OO .3OO .4OO .5OO .6OO .7OO .8OO .9OO 1.OOO 1.1OO 1.2OO
F-6
5
APPENDIX G
SUSQUEHANNA UNIT 2SUMMARY DATA
ILRT
ALMAX = 1. 000VRATET = }.110
VOLUME = 411130.VRATEM =1. 101
TIME930945
1000}O}5103010451100}l}5113011451200121512301245130013}5133013451400141514301445}5001515}5&v1545}6001615}63016451700171517301745}800181518301845}9001915}93019452000201520302045210021152130
DATEi}01110}1101110111011101}101l}0}11011101i}01}10111011}01110}iioi1101l}0111011101iioiiioi11011101}10111011101110111011101ilvi1101}1011101110}11011}01110111011101}10}1101llvi1101l}011101}1011101}101
TEMP550 ~ 565549. 845549. 510549. 332549.201549 ~ 093548. 99$54S. 91454S. 840548. 783548. 729548. 675548.627548.5$ 2548.542548.508548.467548 '30548.395548.371548.338548.313548.2$ 254S. 25854$ . 233548. 07548. 189548.161548. }38548. 120548.}vO548.0S6548.070548.050548.034548. 019547.99$547. 983547. 963547. 957547. 948547.929547.924547.897547.886547. 879547. 86$547.864547.856
PRESSURE60.845860.784860.758260.740660 '25960.713960.702160. 692560. 682460. 673060. 665160. 655960. 649460. 641760. 633660. 627660. 621360 ~ 614060. 608}60. 602160. 597360. 591460. 586360 '80660.575360.570460.566360.561560.557560. 552760. '4$ 660. 544560. 539560. 534460. 531560. 526760.522660 '19260.5}5360. 511360. 507260. 504160. 500060. 497360. 493560. 489260. 486160. 484060. 4801
VPRS~ 4025.4030.4009. 4006'4005
. 3996
. 3995
. 3992
. 3994
.3988
.3988a399}.3987.3985.3987.3987.3981.3984.3983.3984.3983.3982.3984.3982.3985.3984.3985~ 3984.3985.3982.3985.3985.3986.3987.3987.3985.3987. 399}.3990.3990.3992.3993.3995.3992.3990~ 3994~ 3995.3996
>995'OLUME
411130.4}i}30.411130.411}30.411130.4}1130.411130.41}130.411130.411130.411130.4}i}30.411130.411130.4}}}30.411130.411130.411130.4}1}30.411130.411130.411130.41}130.411130.411}30.411130.4}i}3v.411130.4}i}30.411130.411130
'411130.
41}130.411130.41}130.411130.411130.411130.41}130.411}30.411}30.411130.41}}30.411130.411130.411130.
, 411}30.411130.4}1130.
G-I
APPENDIX G
SUSQUEHANNA UNIT 2SUMMARY DATA
ILRT
ALMAX = 1. 000VRATET = }. }}0
VOLUME = 411}30.VRATEM =1. 101
TIME2}45220022f5223022452300231523302345
0153045
100i}51301452002}523024530031533034540C>41543044550051553v54560061563064570071573074580081583v845
915
DATE110111011}0111011}011101110}11011}0}1}02}1021102fiv21102fio21102i}021102}10211021}o2}102110211021102l}0211021}02f1021}02110211021102l}021102l}02lfo21 }021102l}0211021}021102ilv21102}}021102
TEMP547.846547. 835547. 824547. 819547 ~ 802547. 792547. 785547 ~ 779547 ~ 765547 ~ 755547. 743547. 739547. 729547. 720547. 713547. 701547. 695547.696547 '85547.680547. 669547. 669547. 656547. 656547. 637547 ~ 627547. 623547 ~ 622547.6}6547. 616547.608547 '03547.595547. 590547. 582547. 576547.572547. 574547. 564547 ~ 558547. 549547.545547.537547.539547.536547.531547 5>}
PRESSURE60. 477160. 472860.468960.465860 '62460.458860.455660. 452660. 449}60 ~ 446460 ~ 443460 ~ 440360.437060.433860 '30960.427860. 424760. 421960. 418460 ~ 415360.413360. 4}0260'. 4071bt3. 404360 '01160.398060. 395760.392860.390660.387760 '85660.382460. 380460. 377360. 374160. 371360. 367860. 366160 ~ 362960.360660.357460 ~ 355660 '52660. 350260. 347160.344860.3432
VPRS.3996
.3998~ 4000.4004. 4000. 4002. 4003. 4008.4005.>006.4007.4010.4012.4012. 4013. 40}4. 4013.4017~ 4019. 4019. 4020~ 4022.4020~ 4022~ 4024.4027.4026.4028.4028.4029.4031.4031.4033.4034.4033
..4038. 4036. 4038~ 4040.4043~ 4041~ 4041. 4046. 4047~ 4050.4046
VOLUME411130.411130.411130
'11130.
411}30.411130
'11130.
411130.411130.411130.411130.411130.4}1130.411130.4}i}30.411130.411}30..411130.4}1130.411130
'11130.
41}130.411},30.411130.411130.411130.411130.411}30.4}i}30.411}30.411130.4}l}30.411130.4}l}30.4}}}30.411130.411130.411130.411130.411130.411130.411130.411130.4} 1 }3v.411 130.411130.411}30.
G-2
APPENDIX G
SUSQUEHANNA UNIT 2SUMMARY DATA
ILRT\
ALMAX = 1.000VRATET = 1. 110
VOLUME = 411130.VRATEM =1. 101
T IME930945
100010}51030
~ 10451100li}511301145120012}512301245}30013151330134514001415143014451500151515.)0154516001615}6301645}700171517301745}BvO18151830184519001915
DATE11021102i}021102110211021102i}021102}1021102l}021102i}02110211021102}10i}02l}02i}021102110211021102}102iiv211021}02}102i}02110211021102i}021}v21}02110211021102
TEMP547.519547.520547e 517547.508547. 510547. 506547. 504547. 496547. 494547. 492547 '87547.483547.478547.47o547 '72547.464547.460547 '60547.456547.450547.452547.448547.443547 '37547.429547.434547 '27547.419547. 422547. 424547.424547.4}6547.40v547.398547.404547.398547.394547.3'98547 '96547.385
PRESSURE60.340060.337960. 335960. 332960. 330460. 328360.325560 '23460. 320260.318660.315060.3}2960.310060 '07760 '04660 F 302560.300560.292460.291360.284160. 277160. 269160. 262160.254160. 246960 ~ 240060. 233860. 226860. 219660. 212660. 204760. 197760. }90760.182760. }76660 '69560. 160560. }53360. }46460. 1386
VPRS.4048.4050. 4050.4050.4055.4057.4055.4056.4058.4055.4061.4062. 4061. 4064. 4065. 4067. 4067. 4068. 4070. 4073. 4073. 4074. 4075~ 4076. 4078. 4078. 4080~ 4081~ 4083.4084.4084.4085'. 4085. 4086~ 4087.4089.4090.4093.4092~ 4091
VOLUME4}}}30.41}130.411130.411130.411130.4}1130.411130.411130.411130.411130
'1}13v.
4}1130.411130.41}130.4}1130.4}i}30.411130.411130.411130.4}i}30.41}130.411130.41}130 ~
4}i}30.411130.411130.411130.411130.4}1130.411130.411130
'}1130.
411130.4}1130.411130.411130.411130.41}130.4}1130.4}1130.
G-3
APPENDIX GSUSCUEHANNA UNIT 'ILRT
LEAKAGE RATE ()(EIGHT PERCENT/DAY), t(ASS POINT ANAL,YSIS
Tlt(E AND DATE AT STAR'I DF TKGT: I 0 1101 I985TEST DURATION: 4 '0 HOURS
T It(E TE((P(R)
PRESSURE CT)(T, AIR t(ASS LOSS AVERAGE BASS(PSIA) t(ASS (LetU (LBN) LOSS (LSN/HR)
15«0I 451400141'514501445 ~
60 660,614060,608160.6060,597560 591460.«86560 5806do60.5704
SO 486
60 «««9«r
60 5544
60 --6
60 «1160,507260. 04160,500060,497«60,492560,489260.486160,484060,480160,477160.47 860,468960,465860.46 460 458860,4 «660,452660 449160,446460,4460.440560 4«7060 4« 8doe 4 O'9
boe4 7860,4 4760 421960 418460,415«60 4160. 410260. 407160.404560.401160,«98060.«957( o. =Pce60 ')Od60 «87760,«85«b60 8 460 «80460, 7760,574'I60. «71«60.«67860. 66160, 6960, 606
60 55 6
60.55060. «47160 448
60. 400
60 5960 960 «0460 8
do « «4
SO Ied60 I 060«I 960. I(to60 07760 Oid
1500I15451600161516«01645170017151 75017451800181518«018451900191«19 019452000
0150 00451 00115
0
OO
00
450
15«045
IOO
l«O14500
04«
« Ir«
4«40041«4«044««Ao
15««0545600bl«6 06457007157«07458008158«084590091«9 0945
10001015IOA10451100111IIA1145
0015
I «045
IAOI «15l«0
548, 467
548.«95
548. 82
54S, 07548 189548 1 6
1'48,18548. I 0548. 100548 086-ie.oTo548,0«0548 0«4
48,01947. P9847.9e5
547,965
547.948547,9 'I547. 9547, 897547 ~ SGS547,879547,868547.064547 856547,846547.8«5
547. 8 1 'I547.802547.792
., 547.785547 779547,765
547 74«47 759
547 7547,7 0547 715547, 701547+695547,6PS517. SS5«47,680«47 SSP««47 SSP«47,65S547,656«47,6 7547 627
547,616«47,616517.(oe547 605
547,590«47 res
547.564547. «8«1'7, 549
«47,5 6
547, IP
547. AS547 510
«47e«0454'/,496«47, 4P4547. 494/ ~ 48747.48-
«47.478547,470
47,47547,464547 ido
I 6«4,648
I 644
I 6 8
I 619,I 2614.
609.I 605,
60I «99.I «95I «89
842577,
I
I ««7,
IIe.
«01 ~
I 4'95,I 4BP
484,~ Gl4'Tdo
I 471 ~
I 456'51
446,144+
I 4«4 ~
12241e.
I 41 e
I 405.
'94
Gd.
71.
I 6461 ~
I47
I 41
I 0
II IQ.
04~ I \«
I 767068,
49
I0
« ~ 96,9
0«de«Gad
44,«
45o Ide4r 8
6 ~ 76. I
7,0,4
57.1
8
6 «
054 ~ 84ee
««0 ~
54,14o54 ~ «
5+I«84,75,0I 76,4
dao\ 4
I'.7
4,4
4.04
~ I4 6
4
~ 4
6 0
4 ~ 7
19m 60 7
19 ~ 70,4
19 919 719. IIe. 5IS 818. 6IS. 7
19.19 4IS. 8
19 0IG T18. 518 ~ 919. I18 ~ 7
te. «18 ~ 4
Ie. 6IS.+Ie. 7Ie. 6IS 718 8le.p18. 7lee 718 8Ie.e18. 718 6
Ies5ISIS+5Ies 4Ie ~ 4IS 5Ieo5IB 5le.518. 4le. 418 4Ie.=18
18IS18 01818IB. I1'eo I18. IIe 0le. oIT. 9I ~
IB 018. 0Ie 017+ 8ITa9ITe 917 817 817 '9
(To S1717+ 817 817. 817 ~ 817 ~ 8I ~ ~ 8IT~ 717 817. 717 7
f«(TC
FREE AIR VOLUt(K U KD (CU FTREGRESSIDN LINK
INIKRCCFT iLStl)Q(.OCE (L&H/HR)
HAXI)tut( ALLOWA>LC LCA>AGC rATK7 .. Of t(AXIHU(( AL( C(4AILE Lc (4 AGCTHE tlFFFR 9 .. CotlFI 8 tlCC LI."(ITTHE CALCL ATED Lch)4(GK RATE
4111 0
'122S48,I~ 6
COO~ P g
.546« ~ 545
G-4
APPENDIX G
SUSCUKHANN4 UNIT 21 10T420'e014SS I SeN X 1000
llnl)0 12).200 )21.000 1)l.t00 122.000 I'2.100 In.nA In.AI 122.1)0 ln. N In.IIO In.)00 I'.llD
In)'l)I
1100 I1115 I11)0 I)II) :ISN I1)15 IIS)0 Il)l) IIDIO:lll)
'QO:
IHS'NOI
015'nlI
l)IS IIIN:Ill) I
ll)0 Iill) IIND IIUS
'l)0IIIIS In)0 I2el) ~
2e)0 I201) I2100 I211) I21)0 I2ll5
')0I
nl) In)01nl5
'00I2)15 In)0 I2)15 I
Oe15 I)0
'SI100 I)15 ee
I)0 Ill) I20) I215
')0I21) I)00 I)l) I))0 I)IS:100 III5 e
1)0 I015
'COI51):5ASl) ~
100 Iil)
'l)01
IIS I200 I)IS IBO III)
'00IIl) I0)0 IIl) I100 I115 Ino
'l)I1000
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III)'100
'115IIIAIll) I1200 e
121) IIno
'21):
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121.100 )21.)00 )2).000 111.000 llh08 112.100 In D 122 )A: .110 12.'Al) I,. IOD
G-5
APPENDIX G
SUSDUEHAIINA UNIT D ILRTTE!fleERATVRE DEGREES F
IL700 07.171 Ile'15$ N.II2 ILI:5 N.2N IL21$ N.$77 ILIil $1.515 tt 020 N.tll Na'1'll
ISSO INIS I1000 I111$ IIISO I11151f500 I1515 I1570
'51$
'000IIN5:IQO:1115:1700 ~
171S e
1750 ~
171$ <
INO I1015 a
IISO Illil
'tflI1115 III$0 a
111$
'0)S:
2050 ~
20IS:2100 I2115:21N
'115
'IO
'275:
22N:221$ '2500 I2$ 1S:IPA
'515:
Ol1$ I
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115 I1$0 e
11$ I2N
'15:
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1100 II Ill I1150:111$
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07.700 07.071 If.IN It.fll 0$ .125 N.20f tt.2fl tt.$77 N.lll t!.515 fLI.f tt.tll N.lft
G-6
, ~
APPENDIX G
SVSCVSH4XX4 VNIT )LRT10488 POINT L840 488 44)80~I 4XD VCL(XI
000 .IOO )<I ~ )00,000 ~ $00 000,)00 .000 .'I".I I.Oio I~ I:I l.'::I)00 'I
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1000 I1015 IIo)o I100$
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o
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G-7
APPENDIX H
SUSQUEHANNA UNIT 2 DRYWELL BYPASS TESTSUMMARY DATA
ALMAX = .770 VOLUME = 159309 ' COD = ~ 600
TIME1145120012151230.1245130013151330134514001415143014451500151515301545160016151630
e 1645. 1700
1715
DATE1 1031103110311031103110311031103}10311031103110311031103110311031103110311031103110311Q31103
DRYTMP549. 333549. 364549. 393549. 408549. 430549. 453549. 471549. 494549. 514549 541549.56554'9. 587549. 603549 ~ 625549. 637549. 647549. 668549. 681549. 697549. 709549. 717549. 734549.741
DRYPRS18. 90918.91018.91218.91418.91618.9181$ . 92118. 92318. 9241'8. 92618. 92718. 92918. 93118 '3318.93418 '3518.93718. 93818. 94018. 94118. 94118. 94318. 945
DRYVAP.197~ 198.199.200.201~ 2Q2. 203. 204. 205. 206. 207. 209. 209. 211. 211~ 212. 213
214. 215~ 216. 217. 218. 219
SP TMP542.128542.401542 '69542. 79S542. S71542. 939542. 996543.052543.089543. 129543. 171543. 198543. 228543. 263543. 287543. 315
. 543 ~ 340543 ~ 354543. 379543. 405543 ~ 419543. 429543. 456
SP PRS SP14.41514.36914.37914.38514 '8314.39514. 39914. 40314. 40514.40914.40314. 413,14. 41514 ~ 41714 F 41314. 42214 ~ 42414. 42614. 42814. 42814. 42214 ~ 43214 ~ 434
VAP.526.531~ 535. 539542
~ 544. 545~ 548.549.551.551.553.554~ 555.555~ 556~ 556~ 557. 558~ 558~ 559~ 559. 559
VOL.159309.0159309.0159309.0159309.0159309. 0159309.0159309.0159309.0159309.0159309.0159309.0159309.0159309.0159309.0159309.0159309.0159309.0159309 '159309.0159309.0159309. 0159309.0159309.0
APPENDIX H
SUSQUEHANNA UNIT 2 DRYNELL BYPASS TESTBYPASS AREA (SQUARE INCHES)
TOTAL TIME ANALYSIS
TIME AND DATE AT START OF TEST: 1300 1103 1983TEST DURATION: 4.00 HOURS
TIME DRYTMP DRYPRS DRYVAP SP TMP SP PRB SP VAP
130013151330134514001415143014451500151515301545f6001615163016451700
54'9. 453549.471549.494549.514549. 541549. 565549. 587549. 603549. 625549. 637549.647549.668549. 681549. 697549. 709549. 717549. 734
1 8. 91818.92118. 92318. 924f8. 92618.92718. 92918. 93118.93318. 93418. 93518. 93718. 93818. 94018. 941.18. 94118. 943
s 202~ 203. 204. 205. 206. 207. 209. 209~ 211. 211~Of')
. 213
. 214
.215
. 216
. 217~ 2fB
542. 939542.996543.052543 089543.129
. 543. 171543. 198543. 228543. 263543. 287543. 315
~ 543. 340543. 354543 379543; 405543. 419543.429
14.39514.39914.40314 ~ 40514.40914.40314.41314.41514.41714. 41314. 42214. 42414. 42614.42814. 42814. 42214.432
.544
.545
.548
.549
. 551~ 851~ 553~ 554.555~ 555. 556. 556. 557.558. 558~ 559.559
.00455
.00331
.00159~ 00262
—.00504.00186.00178.00156
—.00131.00268.00291. 00304.00298.00232. 00013.00287
4 S. P. FREE AIR VOLUME (CU. FT. )COEFFICIENT OF DISCHARGE
159309. 0. 600
MEAN 'OF THE'EASURED BYPASS AREASMAXIMUM ALLOllABLE BYPASS AREATHE LONER 95/ CONFIDENCE LIMITTHE UPPER 95/ CONFIDENCE LIMITTHE CALCULATED BYPASS AREA
. 002
.770
.000
.004
.002
APPENDIX I
Type B and C Leakage Rate Test Results
Local Leakage Rate Type "B" Tests
Penetration / Description Leakage RatePneumatic Hydraulic
(sccm) (cc/min)
X-1 Equip. access hatch
Equip. access hatch withpersonnel lock
3.25 +/- 16
1.5 +/- 16 N/A
X-2
X-2
X-4
Personnel lock barr el lPersonnel lock inner door
Personnel lock outer dool
Drywell head access manhole
Drywell head
CRD removal hatch
X-35A+ Tl'P driveX-35C+ TIP driveX-35D+ TIP driveX-35E+ TIP driveX-35F+ TIP driveX-100A Neut. monitoring(3+)
X-100B Neut. monitoring(5+)
X-100C Neut. monitoring(5+)
X-10OD Neut. monitoring(5+)
623.0 +/- 160
14.1 +/- 16
10.1 +/- lb
3.58 +/- 16
10.48 +/- 16
N/A
N/A
N/A
N/A
N/A
53. 15 +/- 16
26.68 +/- 16 N/A
N/A
N/A
0.575 +/- 16 N/A
5.63 +/- 22.63 N/A
7. 11 +/- 22.63 N/A
3. 30 +/- 22. b3 N/A
3. 90 +/- 22. 63 N/A
3.25 +/- 22.63 N/A
+ Penetration requires bath type B and C tests. Leakage ratelisted is, total penetration path leakage.
Local Leak Rate Type "8" Tests (Cont'd)
Penetration / DescriptionLeakage Rate
Pneumatic Hydraulic(sccm) (cc/min)
X-101A N. V. power <4+)
X-1018 M. V. power <2+)
X-101C'. V. power (4+ >
X-101D N. V. power (2+)
X-101E N. V. power(4+)
X-101F N. V. power (2+)
X-102A Low level si gnal /temp. (4+)
X-1028 Low level signal/temp. (2+)
X-103A Low level signal/temp. <3+>
X-1038 Low level signal/temp.(5+)
X-104A RP IS (3+)
X-1048 RPZS (5+)
6. 13 +/- 16 N/A
N/A
N/A
N/A
N/A
N/A
N/A
54. 53 +/- 16 N/A
X-104C
X-104D
RP IS (3+)
RP IS (5+)
X-105A Low voltage power (4+)
X 1058 Low 'voltage power (2+)
X-105C Low voltage power (4+)
X-105D Low voltage power (2+)
X-106A Low voltage control (4+)
X-1068 Low voltage control (2+)
X-106C Low voltage control (4+)
N/A
N/A
N/A
N/A
N/A
Local Leakage Rate Type "B" Tests <cont'd)Leakage Rate
Penetration / Description Pneumatic Hydraulic(sccm) <cc/min)
X-106D Low voltage control (2+).
X-107 Low voltage power (2+)
X-108 Low voltage power (4+)
X-200A Access hatch
X-200B Access hatch
X-300 Low voltage control (5+)
1.90 +/- 16
4.05 +/- 16
N/A
N/A
N/A
N/A
N/A
N/A
X-301 Low voltage control (4+)
X-330 El ectri cal penetrati on (4+)
Total Type "B" Leakage Rate 836. 215+/-177. 4502 (sccm)
(2+) Leakage assigned to penetration X-1018 i s the sum ofpenetrati ons X-101B, X-101D, X101F, X-105B, X-105D, X-106B,X-106D,X-107,andX-102B. These penetrations were alltested simultaniously.
(3+)
(5+)
Leakage assigned to penetration X-100A is the sum ofpenetrat ions X-100A, X-100C, X-103A, X-104A, X-104C, andX-301. These penetrations were. tested simultaniously.
Leakage assigned. to penetration X-101A is the sum ofpenetr at ions X-101A, X-101C, X-101E, X-102A, X-10SA, X-105C,X-106A,X-106C,and X-108. These penetrations were alltested simultanious'ly.
Leakage assigned to penetration X-100B is the sum ofpenetrations X-100B,X-100D,X-103B,X-104B,X-104D,X-300.These penetrations were all tested simutaniously.
X-7A Hain steam
X-7B Hain steam
X-7C Nain steam
X-7D Main steam
X-8
X-9A
X-9B
X-10
X-11
Nain steam line drain
Feedwater .
Feedwater
RCIC Turbine steam
HPIC Turbine steam
X-12 , RHR shutdown supply
X-13A RHR shutdown return
X-13R RHR shutdown return
Local Leak Rate Type "C" Tests
Penetration / DescriptionLea Vage Rat
e'neumatic Hydraulic(sccm) (cc/min)
3937. 50 +/- 1600. 08 N/A
3354.70 +/- 1600.08 N/A
1815. 85 +/- 160. 80 N/A
3241.28 +/- 1600.08 N/A
20.48 +/- 16 N/A
1314. 05 +/- 162. 38 N/A
7. 65 +/- 22. 63 N/A
160. 415+/- 16. 08 N/A
48. 20 +/- 22. 63 N/A
275. 50 +/- 160 N/A
N/A
X-14 RWCU supply N/A 133.33 +/- 2.67
X-16A Core spray
X-16B Cor e spray
X-17 RPV head spray
X-19 Instrument gas
X-21 Instrument gas
13390 +/- 1600 N/A
501. 50 +/- 160 N/A
255. 60 +/- 160 N/A
109. 5 +/- 22. 63 N/A
21. 85 +/- 16 N/A"
X-23 Closed cooling water supply 10.75 +/- 16 N/A
X-24 Closed coiling water return 142.20 +/- 16 N/A
Retesting %or some penetrations currently in progress. Whentesting is complete, Winal results may be obtained +rom SSES DocumentControl Center.
Local Leakage Rate Type "C" Tests
Penetration / Description
X-25 8c
X-201 A
X-26
Purge supply
Purge exhaust
X-41
X-42
X-53
X-54
X-55
X-56
Instrument gas
Standby liquid control
Chilled water supply
Chilled water return
Chilled water supply
Chilled water return
X-31B Nini purge to recir.pump B
X-394 Containment spray
X-MB Containment spray
N/4 10.67 +/- 2.67
540 '0 +/- 160
169'P.OO +/- 160
73.85 +/- 16
6.67 +/- 16
N/A
N/4
Leakage RatePneumatic Hydraulic
(sccm) (cc/min >
1660. 0 +/- 160 ~ 8 N/A
107.90 +/- 22.63 N/A
23.82 +/- 22.63 N/A
312.70 +/- 160.8 N/A
186. 33 +/- 22.63 N/A
3. 6 +I- 22. 63 N/4
X-6OA Oxygen sample
X-BBB Oxygen sample
X-60A Oxygen sample
X-60A Mini purge to recir.pump A
X-60B Reactor water samlpe
X-61A, Demi n. water
X-72A Liquid radwaste
X-72B Liquid radwaste
3.68 +/- ib N/A
2. 63 +/- 16 N/A
1. 33 +/- 16 N/A
2. 71 +I- 22. 63 N/A
2. 40 +/- 16 N/A
12.50 +/- 16 N/A
1164.00 +/- 160 N/4
6250. 00 +/- 1600 N/A
X-61A
X-SOC
ILRT Leak verificationOxzgen analyzer
6 ~ 65 +/- 16
2.72 +/- 16
N/A
N/A
X-SOC Oxzgen analyzer 3.10 +/- 16 N/A
Local Leakage Rate Type "C" Tests (cont'd)
Penetration / DescriptionLeakage Rate
Pneumatic Hydraulic
X-BOC Gxzgen analyzer/nitrogen supply 2.25 +/- 16
X-85A
X-85B
X-86A
Chilled water torecirc. pumps
Chilled water torecira. pumps
Chilled water torecirc. pumps
32.475+/- 16
895.75 +/- 160
78.25 +/- 16
N/A
N/A
N/A
X-86B
X-87
X-93
Chilled water toI ecir cr pumps
Instrument gas
TIP instrument gas
19.90 +/- 16 N/A
35.10 +/- 16 N/A
23.75 +/- 22.63 N/A
X-202 Purge exhaust
X-203A RHR pump suction
X-203B RHR pump suction
X-203C RHR pump suction
X-203D RHA pump suction
X-204A RHR pump test lineX-204B RHR pump test. lineX-205A Containment spray+
X-205B Containment spray++
543.'75 +/- 160.8 N/A
N/A
N/A
N/A
688. 00 +/- 2. 7
346.67 +/- 2.67
90.67 +/- 2.67
37. 33 +/- 2. 7
N/A
214. 08 +/- 160. 8 N/A
'156.77 +/- 22.63 N/A
X-206A Core spray pump suction
Leakage included with X-204A.Leakage included with X-204B.
N/A 10.70 +/- 2.7
'
, ~ ~
Local Leak Rate Type "C" Tests (cont'd)
Penetration / DescriptionLeakage Rate
Pneumatic Hydraulic(sccm) (cc/min')
X-206B Core spray pump suction
X-207A Core spray pump testX-207B Core spray pump test
AX-20BA Core spray pump recirc.X-208B Core spray. pump recirc.X-209 WPCI pump suction
X-210 HPCI turbine exhaust
X-211 HPCI pump recirc.X-214 RCIC pump suction
X-215 RCIC turbine exhaust
X-216 RC IC pump recirc.X-217 RCIC vacuum pump discharge
X-218 Instrument gas
X-221A Oxzgen analyzer
X/221B Oxzgen analyzer
X-226A RHR recirc.X-226B RHR recirc.
N/4
N/A
N/A
N/A
6.0 +/- 2.0
16. 0 +/- 2. 67
19.2 +/- 1.6
0.0 +/- 1 ~ 6
0.0 +/- 1 ~ 6
N/A 258.67 +/- 2.67
N/A
N/A
5.33 +/- 3.78
8.00 +/- 3.78
224.00 +/- 2.67
64.00 +/- 3.78
0.0 +/- 3.78
90 67 +/- 3.78
N/A 122.67 +/- 2 '7
8.36 +/- 22.63 N/A
28.83 +/-. 22.63 N/A
9.2 +/- 22.63 N/A
N/4 213.33 +/- 2.67
X-238A
X-238B
X-243
Oxzgen anal'yzer
Oxzgen anal yzer/nitrogen supply
Supply pool cleanupand drain
9. 95 +/- 22. 63 N/A
15. 05 +/- 22. 63 'N/A
24.0 +/- 2.828
Local Leakage Rate Type "C" Tests (cont'd)
Penetration / DescriptionLeakage Rate
Pneumatic Hydraulic(sccm) (cc/min)
X-244 HPCI vacuum breaker
X-245 RCIC vacuum breaker
X-24&A RHR relief valve discharge
X-2468 RHR relief valve discharge
75. 575+/- 22. 63 N/A
42. 88 +/- 22. 63 N/A
12.32 +/- 27.71 N/A
135. 60 +/- 32
Total Type "C" Pneumatic Leakage
Total Type "C" Hydraulic Leakage 2369.24 +/- i3.3 cc/min
Retesting for some penetrations, currently in progress. Nhentesting is complete, final results may be obtained from SSES Documen'tControl Center. „
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