Reactor Containment Bldg 1993 Integrated Leakage Rate Test.

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Issue date:	11/30/1993
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T GRAND GULF NUCLEAR STATION REACTOR CONTAINMENT BUILDING 1993 INTEGRATED LEAKAGE RATE TEST FINAL REPORT November,1993 9405090153 940428 PDR P

ADOCK 05000416 PDR

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i TABLE OF CONTENTS SECTION TITLE PAGE 1 Introduction 3 2 Summary 4 3 Methodology 6 4 Procedures 9 5 Results 15 1

6 References 24 7 Tables and Figures 25 1

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Appendix ! Containment Desenption i

! Appendix il Computer Program Discussion l

Appendix ill Test Data j l Appendix IV Local Leakage Rate (Type B & C)

Test Result Tabulation Appendix V Summary Report of Type A, B, and C Tests Which Failed to Meet Acceptance Critena of 10CFR50,

Appendix J N

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1. Introduction The containment integrated leakage rate test (ILRT)is performed as required by 10CFR50, Appendix J (Reference 1) to demonstrate that leakage across the containment boundary at design basis accident pressure does not exceed the Technical Specification limit. Test methods and procedures are specified in ANSI N45.4-1972 (Reference 2) which is cited by Appendix J, and in BN-TOP-1 (Reference

3) which defines an altemative methodology acceptable to the Nuclear Regulatory Commission. The conduct of the ILRT follows a plant surveillance procedure (Reference 4) which contains detailed instructions for all test phases.

References 1 and 3 provide two different options for the calculation of leakage rate. If the test has a duration of at least 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />, Reference 1 allows leakage rate calculations to be performed using the mass point method defined in ANSI /ANS 56.8 (Reference 5). If test duration is less than 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />, leakage rate calculations must be performed using the total time method desenbed in Reference 3. The 95% upper confidence limit (UCL) calculation denved in Reference 3 provides a very conservative

• upper bound on leakage rate. Since the test reported herein had a duration of less than 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />, total time alculations were used to determine leakage rate and UCL.

The ILRT is desenbed in detailin the following sections of this report. Section 2, Summary, gives a synopsis of test activities and results. Section 3, Methodology, discusses measurements and calculations. Section 4, Procedures, desenbes how the test was conducted. Section 5, Results, presents the parameters calculated during the ILRT and the ascociated acceptance criteria. Section 6 lists references and Section 7 includes all tables and figures cited in the text. The Appendices contain a description of the containment, a discussion of the computer program used to calculate leakage rate, a listing of all containment atmospheric condition data recorded dunng the test, and a tabulation of all Type B and C localleakage rate testing results obtained since the previous ILRT. Appendix V is a summary report on test results which do not meet Reference 1 acceptance enteria.

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2. Summary The ILRT was conducted on November 20 and 21,1993. Pressunzation commenced at 9:37 AM on November 20 following the completion of all prerequisite activities, and the containment was isolated at an intemal pressure of 12.0 psig at 2:20 PM on the same day. Numencal temperature stabilization entena were met by 6:30 PM. However, the stabilization period was continued for another hour and a quarter to ensure a reasonably stable air mass trend.

By 7:45 PM, the containment air mass plot was indicating a smooth decreasing trend.

The calculated leakage rate was well below the acceptance limit and decreasing.

Therefore, the Type A test was commenced at this time. As the test progressed, the suppression poollevel was noted to be nsing. However, due to the coarse resolution of the level instrumentation, the rate of level increase could not be determined until well into the test penod.

When the rate of suppression pool level was determined, converted to a leakage rate equivalent in %/ day, and added to the calculated leakage rate, the resulting corrected

• leakage rate was wellin excess of La (although it was still decreasing as the test continued). A preliminary evaluation of the leakage rate trend indicated that the UCL for a test started at 7:45 PM would not reach an acceptable value for a long time, possibly several days.

The leakage rate trend evaluation also included the effect of a potentially significant leak, which was discovered in the fission product monitor (FPM) sample panel dunng pressurization. After careful consideration of the overall situation, it was decided to isolate the FPM, restart the Type A test, correct the FPM panel leakage after the ILRT and adjust the Type A test UCL as required after completing repairs.

Between 3:30 and 3:45 AM on November 21, penetrations 109A and 1098 isolation valves were closed to isolate the FPM and the post accident sample system (PASS).

The Type A test was restarted at 3:45 AM and was successfully completed without incident six hours later, at 9:45 AM.

The venfication test imposed feak was initiated just after 9:45 AM, and a successful venfication test was conducted between 11:00 AM (following the i hour stabilization penod mandated by Reference 3) and 2:00 PM. Depressurization commenced just after 2:00 PM and was complete at about 8:00 PM. Test results are listed below:

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d Grand Gulf Containment Building 1993 ILRT Final Report 95% UCL on total time leakage rate plus corrections 0.210%/ day Acceptance limit (0.75 La) 0.328%/ day Extrapolated total time calculated rate 0.321%/ day Acceptance limit 0.328%/ day 0.118%/ day Mean of the total time measured rates Acceptance limit (1.0 La) 0.437%/ day Venfication test upper acceptance limit 0.302%/ day Venfication test total time calculated leakage rate 0.155%/ day Venfication test lower acceptance limit 0.084%/ day The venfication test calculated leakage rate does not include the corrections discussed in the f wing paragraphs.

The "as-left" leakage rate is 0.210%/ day. This is the sum of the -0.155%/ day total time '

UCL calculated after closing the penetration 109A and 1098 isolation valves and corrections of 0.311%/ day for suppression poollevelincrease,0.002%/ day for penetrations not isolated by normal means, and 0.052 %/ day for the as-left leakage rate through penetrations 109A and 1098.

This report presents two methods by which the "as-found" leakage rate was calculated.

By the first method, the "as-found" leakage rate was computed using a conservative estimate for the final trended slope of the air mass plot. The computation used air masses adjusted for suppression poollevel increase, isolation of penetrations 109A and 109B and the venfication test imposed leak. The "as-found" leakage rate, corrected for minimum pathway improvements and penetrations not isolated by normal  !

post-accident means, is 0.391 %/ day. This is less than the maximum allowable leakage rate, La (0.437 %/ day), which demonstrates that the containment maintained acceptable leaktight integrity at the end of the operating cycle.

By the second method, the "as-found" leakage rate was computed from "as-left" leakage rate, with minimum pathway improvements added. The leakage through the FPM panel and PASS piping was not added to this result based on the results of an ,

evaluation. The evaluation concluded that the penetration 109A and 1098 isolation (

valves which isolate the FPM and PASS should be closed dunng a design basis accident and, therefore, should not have been open during the ILRT. The "as-found" leakage rate by this method, corrected for minimum pathway improvements and penetrations not isolated by normal post-accident means, is 0.312 %/ day. This is less than the maximum allowable leakage rate, La (0.437 %/ day).

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1 3. Methodology i

3.1 Leakage Rate Calculation i

! Integrated leakage rate is determined by pressurizing the containment to design I basis accident pressure and calculating the average rate of loss of dry air from i

the structure over a specified time period. The quantity of dry air in the containment is computed using the ideal gas law and measurements of drybulb l

tempercture, dewpoint temperature and absolute pressure. A single average drybulb temperature, T, is calculated as the sum of the products of 24 measured -

j temperatures and their associated weighting factors (discussed below).

j Individual dewpoint temperatures (6) are converted to vapor pressures using the ASME Steam Tables saturation line algorithm. A single average vapor pressure is calculated in the same manner as is average temperature. Dry air partial pressure, P, is measured total pressure less average vapor pressure. The 3

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quantity of air in the containment is:

M = PV/RT

where M is quantity in mass units, V is containment free air volume, R is the gas

! constant for air and P and T are defined above. Containment free air volume used for ILRT calculations is 1,670,000 cubic feet. R, in English units, is 53.35 -

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pounds force-feet / pounds mass-degree Rankine. The partial pressure of dry air I is used in the computation so that pressure changes resulting from evaporation

! of liquid water and condensation of vapor do not affect calculated leakage rate, r

j Leakage rate is calculated using the total time method developed in Reference i 3. The following computations are performed to determine the total time j leakage rate:

- " Measured" leakage rate is computed for each data set except the first.

i " Measured" leakage rate is the difference between initial air mass and I current air mass divided by the time elapsed between the initial and

] current data sets.

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!' - The slope and intercept of a line fitted to the " measured" leakage

rate / time data sets are computed using the method of least squares.

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- " Calculated" leakage rate is computed as the end of test ordinate of the fitted line.-

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Grand Gulf Containment Building 1993 ILRT Final Report A statistical upper bound on leakage rate at the end of the test is also

- computed. This bound is identified in Reference 3, and throughout this report, as the 95% upper confidence limit (UCL) on calculated leakage rate. However, the expressions presented in Reference 3 are those which define the much more conservative upper side of the 95% confidence band on measured rate.

The UCL on the leakage rate, plus adjustments for leakage through penetrations not isolated by normal means and changes in containment water inventory, must not exceed 75% of La. La (0.437 %/ day)is the maximum allowable leakage rate defined in the Technical Specifications. When leakage rate is determined using total time calculations, test duration may be as short as 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> (per Reference 3).

Following the determination of a leakage rate from test measurements, the calculational method is venfied by imposing an additional leak on the containment and determining the new rate. The new rate must equal the previously calculated rate plus the imposed rate plus or minus a tolerance of La/4. The imposed leak, vented from the containment through a flow meter, is

• approximately equal to La. This supplemental, or verification, test also provides a rough check on pressure measurement since a significant error in the measurement of pressure change will result in a calculated leakage rate which is outside the acceptance band.

3.2 Test Measurements Leakage rate calculations are based on data taken from drybulb and dewpoint temperature sensors located inside the containment and drywell, as well as l absolute pressure transducers ported to the containment and drywell through (

I piping penetrations. Twenty four drybulb temperature sensors and 6 dewpoint temperature sensors were installed. Of these,6 drybulb and 2 dewpoint sensors were located in the drywell. One drywell drybulb sensor was placed in the head space. One containment drybulb sensor was placed in the steam tunnel. Temperature sensors were wired to the data acquisition system (see below) through containment electncal penetrations.

1 As-installed sensor locations and weighting factors (volume fractions) are listed in Table 1. Due to erratic data, the temperature at drywell dewpoint sensor M21 could not be used in the leakage rate calculation. This sensor was declared inoperable and its weighting factor was reassigned to the other drywell dewpoint

- sensor, M22.

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• Grand Gulf Containment Building 1993 ILRT Final Report Sensor locations and weighting factors were established by considenng the spatial pattern of temperature changes determined during past tests. Since temperature changes tend to vary pnncipally with elevation, sensors were set at approximately equally spaced elevations and the volume associated with each sensor (except that in the steam tunnel) was taken as a horizontal slice through the containment or drywell, as applicable. The steam tunnel temperature sensor was assigned the combined volumes of the steam tunnel and the RWCU heat exchanger compartment.

Each sensor was positioned close to the vertical centroid of its assigned volume. While there is no evidence that containment atmospheric conditions vary significantly with plan location at a fixed elevation, the possibility of an unusual in-plane temperature distribution was provided for by honzontally offsetting each sensor from its vertically adjacent neighbors. Development of sensor locations, associated volumes and weighting factors is desenbed in detailin Reference 6. Containment geometry is described in Appendix 1.

Drybulb temperatures were measured using 100 Ohm platinum resistance temperature detectors (RTDs). Dewpoint temperatures were measured by chilled mirror dew cells. These devices use a thermoelectric junction to cool a small mirror. A light-emitting diode (LED) focuses a beam on the mirror which reflects the beam to a photo detector. The intensity of the reflected light changes when the mirror cools to the dewpoint and collects condensation. A small RTD senses mirror temperature which is controlled at the dewpoint by the photodetector circuit. The dewpoint temperature sensors are completely self contained units requiring 24 V DC input power. The RTD sensing mirror temperature provides the output (a resistance).

1 The RTDs and dew cells were connected to the data acquisition system and 24 V power supply through containment electrical penetrations.

Absolute pressure was measured by 2 vibrating cylinder manometers, one sensing containment pressure and the other, drywell pressure (essentially the same pressures since both drywell airiock doors were open). This type of manometer uses an electronic circuit to determine a modal frequency of a cylinder subjected to vacuum on one side and test pressure on the opposite side. The detected frequency varies approximately linearly with pressure. An intemal microprocessor is programmed during calibration to convert frequency to true absolute pressure in engineering units. The manometer has a resolution i of 0.0001 psi and a stability of 0.001 psi. The stability figure is based on recorded deviations between the indications of 2 manometers over the test duration.

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d Grand Gulf Containment Building 1993 ILRT Final Report A digital data acquisition system was used to collect drybulb and dewpoint temperature data and transfer that data to the ILRT computer over an IEEE-488 (parallel bit transmission) bus. The data system included the conditioning circuitry for the RTDs used to sense drybuib and dewpoint temperatures. RTD resistance was converted to temperature with a 0.006 deg C resolution. The manometers were connected to the same IEEE-488 bus as the data acquisition system and provided output directly to the computer. Timing was controlled by the data acquisition system, which was set to scan the drybulb and dewpoint temperature inputs and send a service request signal out on the bus at 15 minute intervals. The service request signal triggered the ILRT software to read the data acquisition system output (time, date, temperature data and various headings and labels) and poll the manometers for pressure data. The computer used was a small IBM compatible running a compiled BASIC program. The program is described in Appendix II.

Other temporary instrumentation included a vanable area flowmeter (connected to a containment piping penetration) used to measure imposed leakage during the venfication test and two analog indicators used to measure containment and drywell gage pressures. All temporary instrumentation was calibrated to the requirements of Reference 4 prior to the ILRT and, with the exception of dewpoint sensor M21, performed well during the test.

A figure of ment (also called instrumentation selection guide figure, or ISG) was determined for instrument repeatabilities using the procedure developed in Reference 3. The figure of ment is 0.078 %/ day.

Permanent plant instrumentation was used to measure reactor vessel and suppression pool water levels. The water level data were used to correct calculated leakage rate for changes in containment water inventory.

4. Procedures 4.1 Plant Status Plant systems were aligned for the ILRT as specified in Reference 4 which incorporates both FSAR (Final Safety Analysis Report) and operational requirements. Isolation valves were set in post accident positions except where the opposite positions were required to maintain the reactor in a safe shutdown condition or to satisfy operational readiness needs. Piping was vented and drained to expose valve seats to containment and outside atmospheres per FSAR requirements. All compressed gas sources were either vented or removed from the containment. All Type B and C localleakage rate tests, except for the post-restoration tests on the ILRT penetrations, were completed prior to the start of pressunzation.

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& Grand Gulf Containment Building 1993 ILRT Final Report Containment sumps were pumped down before the pump discharge penetrations were isolated and drained. All containment fans and lighting were shut off poor to the start of pressunzation. One loop of shutdown cooling was in operation throughout the test to remove core decay heat and the second was maintained in standby. The official copy of the test data package, performed per Reference 4, documents plant status including all exceptions to specified conditions.

4.2 Prerequisite Activities System lineups, equipment protection (against test pressure) work, containment cleanup and ILRT instrument installation were performed over a period of several days prior to the start of pressunzation. After instruments were connected in the containment, these were checked to verify correct response.

The drybulb temperature sensors were placed, one at a time, in an ice bath and a data system response of 32 deg F (+/- a tolerance of 1 deg F) was venfied.

Dewpoint temperature sensor performance was evaluated using an independent instrument which measured ambient drybulb temperature and - ,

relative humidity. Temperature and humidity were converted to dewpoint which was compared to the chilled mirror device indications. Agreement to within 5 deg F was verified.

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The containment examination specified in Reference 1 was completed prior to the start of pressurization. No adverse indications were found.

Both drywell airlock doors were blocked open prior to containment closure.  !

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The completion of all prerequisite activities is documented in the official copy of the test data package, performed per Reference 4.

4.3 Pressurization The containment was pressunzed using diesel dnven, oil free compressors having an aggregate capacity of 4,800 SCFM. The compressors discharged through a skid mounted aftercooler/ refrigerated air dryer train. The skid was equipped with a blowdown silencer and all valving required to pressurize, depressurize and isolate the containment. Skid air discharge was routed through separate penetrations to the containment and drywell. Cooling water to the aftercooler and air dner was provided through temporary lines connected to plant service water headers.

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l Pressurization commenced at 9:37 AM on November 20 and was stopped at l 2:20 PM on the same day when pressure reached 12.0 psig. The rate of i

] pressure increase was reasonably uniform as shown in Figure 1, which is a plot j of containment pressure vs. time. The containment was isolated by closing

valves at the skid. Skid piping was vented to ensure atmospheric pressure

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outboard of these valves. During pressurization, piping vents and outside l containment pressure boundarias were examined for evidence of isolation valve 3 or other boundary leakage. A significant leak was detected inside the fission product monitor cabinet. This leak was noted but not isolated until quantified j during the initial Type A test.

i 4.4 Stabilization l The stabilization period mandated by Reference 3 commenced at 2:30 PM on i

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November 20 and all numerical stabilization criteria specified in Reference 4 were met within 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> (minimum stabilization period duration). However, a  ;

preliminary calculation showed the leakage rate to be quite large during the l l initial part of the stabilization period The large leakage was traced to a drain on

} the high pressure core spray (HPCS) test retum line. This drain had been opened for valve work and allowed water to drain from the suppression pool to i the liquid redweste system. Additionally, water was observed to be leaking from

! the Reactor Core isolation Cooling (RCIC) turbine seals. The leakage path from l the containment was through an isolation valve which had been left open. The position of this valve, which should have been closed during the ILRT, was not

specified as closed in Reference 4.

The HPCS test retum line drain was isolated and the open RCIC isolation valve

! was closed at about 4:15 PM. The stabilization period was continued for 3 l hours and 15 minutes after the HPCS and RCIC water leaks (discussed above) j were isolated until a new trend was evident on the air mass time plot. At the l end of this period (7:45 PM), the calculated mass point leakage rate was 0.19

%/ day and the UCL was 0.22 %/ day. Both values were trending down. Since l containment conditions were stable and the leakage rate was well below the acceptance limit, a Type A test wac started at 7;45 PM.. (The term Type A test

, is used to distinguish the test which determines as-is leakage rate from the i verification test which determines the combined as-is and imposed leakage

! rates.) Stabilization period duration was 5.25 hours2.893519e-4 days <br />0.00694 hours <br />4.133598e-5 weeks <br />9.5125e-6 months <br />.

l Temperature variation over the stabilization period is illustrated in Figure 2.

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The calculated mass of air in the containment is plotted in Figure 3. The initial l rise shown on the plot results from the error in calculated mecn temperature j caused by the unsteady and non-uniform conditions prevalent in the i containment dunng the penod immediately following the termination of pressurization. The change in the slope of the plot at about 4:15 PM (when the HPCS test line leak was isolated) is evident. The increase in air mass between

- 6:45 and 7:15 PM is probably due to a change in suppression poollevel.

1 Table 2 is a stabilization report. This table lists the mean temperatures,

temperature changes and related numbers required to demonstrate stability as

defined by the numencal cnteria outlined in References 3 and 5. These enteria are listed below

4 - The rate of change of. temperature averaged over the last four hours, less the rate of change of temperature averaged over the last hour, does not exceed 0.5 deg F/hr. (Refererce 5) l

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- The rate of change of temperature averaged over the last two hours I does not exceed 1 deg F/hr. (Reference 3) i

- The rate of change of temperature change averaged over the last two hours does not exceed 0.5 deg F/hr2 (Reference 3) i 4.5 Type A Test t

The Type A test was started at 7:45 PM on November 20,1993. The calculated

leakage rate continued its downward trend, begun during stabilization after the HPCS and RCIC leaks were isolated, and the total time UCL dropped below the j 0.328 %/ day acceptance limit at 10

30 PM, just 2.75 hours8.680556e-4 days <br />0.0208 hours <br />1.240079e-4 weeks <br />2.85375e-5 months <br /> into the test. ,

i However, at the test progressed, an upward trend in the hourly suppression pool l level data was observed. Since the resolution of the levelinstrumentation is J rather coarse, the trend was not obvious until long after the HPCS and RCIC i leaks were isolated. Several hours into the Type A test it became apparent that j the total time leakage rate, corrected for suppression pool level increase, was

well above the acceptance limit. After 4.25 hours2.893519e-4 days <br />0.00694 hours <br />4.133598e-5 weeks <br />9.5125e-6 months <br /> of stabilization and 7.75 hours8.680556e-4 days <br />0.0208 hours <br />1.240079e-4 weeks <br />2.85375e-5 months <br /> j of taking data, the calculated leakage rate at 3

30 AM on November 21,1993, 2 was approximately 0.484 %/ day, after correction for rising water level in the 4 suppression pool. The upper confidence limit (UCL), after correction for rising water level in the suppression pool, was 0.529 %/ day. Both quantities were decreasing. The measured leakage rate had decreased approximately i

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@ Grand Gulf Containment Building 1993 ILRT Final Report 0.01 %/ day during the previous hour and the UCL had decreased approximately 0.0135 %/ day during the previous hour. It was recognized that the UCL might stabilize below the acceptance limit eventually, but it appeared that it would not do so within a total test duration of twenty-four hours. It did not seem that the test started at 7:45 PM would yield an acceptable UCL for a long time, possibly several days.

A decreasing trend in leakage rate is expected because a part of the calculated loss of contained air is accounted for by migration of air into penetration piping, concrete voids and other large volumes with minute openings. The plot of contained air vs. time typically starts with a steep slope and slowly trends to a smaller final slope as pressures in these volumes approach equilibrium. A type A test should never be started until the calculated leakage rate, which is affected by the initial steeper slope of the air mass / time plot, is below the acceptance limit. The mass / time plot trend is also evaluated before a test start is declared. This is done to ensure a successful venfication test.

This Type A test had been started after the rate and trend criteria appeared to

• have been met. There was no evidence at the time of the test start that suppression poollevel was rising. When sufficient data became available to estimate the correction for pool rise, it became obvious that a test restart would be necessary.

Significant but unquantified leaks had been discovered in the fission product monitor (FPM) sample panel, which is isolable from containment by closing Containment penetrations 109A and 109B. During the evaluation of the suppression poollevel data, it became obvious that the FPM panelleakage was more serious than was initially thought.

Faced with the probability of waiting more than twenty-four more hours for the UCL to meet the acceptance enterion and the possibility that it would not meet the acceptance entenon, even after a penod of several days, a decision was made to stop the test, isolate the FPM panel by closing the penetration 109A and 1098 isolation valves (valves 1D23-F591, -F592, -F593 and -F594), and restart the Type A test. This decision was made primarily to save entical-path

outage time.

The penetration 109A and 109B isolation valves were closed between 3:30 and 3:45 AM on November 21. The Type A test was restarted at 3:45 AM and successfully completed without incident in 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> (the minimum duration specified in Reference 3).

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• Grand Gulf Containment Building 1993 ILRT Final Report Containment atmosphenc condition data were recorded at 15 minute intervals during the Type A test as well as during stabilization and the verification test.

Suppression pool and reactor vessel levels were recorded hourly to provide the data needed to establish containment water inventory. An increasing inventory is equivalent to a negative leakage and requires a correction to the calculated rate and UCL. Suppression poollevelincreased at an essentially steady rate throughout the Type A test. The rate of increase in water inventory was equivalent to a negative leakage rate of 0.311 %/ day. Reactor vessellevel changes were negligible.

4.6 Verification Test The leakage rate calculated for the Type A test (Lam) is verified by venting air from the containment at a measured rate, Lo, approximately equal to La. The calculated composite leakage rate must equal the sum of Lam and Lo plus or minus a tolerance of 0.25 La. The induced leak, Lo, is measured by venting the air through a flowmeter. A variable area flow meter was used. An induced. leak*

of 8.96 SCFM (equivalent to 0.431 %/ day) was initiated just after 9:45 AM on November 21 and the venfication test was commenced at 11:00 AM following the one hour stabilization period mandated by Reference 3. The verification test 4

was successfully completed in the required minimum time of 3 hours3.472222e-5 days <br />8.333333e-4 hours <br />4.960317e-6 weeks <br />1.1415e-6 months <br /> (half the duration of the Type A test as specified in Reference 3).

4.7 Depressurization and Restoration Depressurization commenced just after 2:00 PM on November 21 and was complete at about 8:00 PM on the same day. The containment was depressurized by venting directly to the outside atmosphere through a silencer.

Discharge air was monitored to ensure against the release of radioactive material.

The containment and the vanous systems and components modified for ILRT performance were restored to normal operational configurations following the completion of depressurization.

4.8 Local Leak Rate Testing of Fission Product Monitor Sample Panel and Post Accident Sample System Piping Following the successful completion of an ILRT with the FPM sample panel isolated and after the containment had been depressurized, the FPM sample panel was local leak rate tested. Leakage from the panel, which includes inlet and return piping within the Auxiliary Building leading to and from the post-accident sample system (PASS), was measured as 157,175 SCCM (approximately 0.271 %/ day).

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& Grand Gulf Containment Building 1993 ILRT Final Report The PASS inlet was then isolated from the FPM sample panel by disconnecting

and capping the tubing branching off from the FPM. This reduced the leakage within the resulting closed system to the FPM sample panel to 30,387 SCCM (approximately 0.052 %/ day),

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5. Results J

5.1 Corrections to As-Left Leakage Rate 4 .

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The as-left leakage rate is the sum of the calculated UCL, the correction for  !

containment water inventory change and the correction for penetrations not l isolated by the normal post-accident means. Corrections are calculated below.

As previously noted, suppression poollevel rose throughout the Type A test period. The resolution of the level instrumentation is between 0.05 and 0.1 ft.

This results in a stepped plot of pool surface elevation vs. time as is illustrated in Figure 4. The mean rate of surface elevation increase with time is defined as the slope of a line fitted to the elevation / time data sets recorded hourly between, 5:00 PM on November 20 and 2:00 PM on the following day. The initial data set l was recorded after isolation of the leaks through the HPCS test retum line drain j and RCIC turbine seals. The final data set was recorded just prior to the start of depressurization. As noted on the figure, the mean rate of pool surface

' elevation increase is equivalent to a negative leakage rate of 0.311 %/ day. This

- number is added to calculated UCL to establish leakage rate corrected for containment water inventory change.

i Several of the containment penetrations were not isolated for the test by the

! normal post-accident means. Reference 1 requires a correction to account for

the possibility that containment leakage could be greater if the normal post- ,

! accident means were used. The correction is the sum of the minimum pathway

leakages through these penetrations. The following table lists the penetrations i not isolated by normal means, the minimum pathway leakages and the net l l correction. Only penetrations with non-zero minimum pathway leakages are l listed.

2 Penetration Minimum Pathway Leakage i

1 151 SCCM j 9 40 19 40 21 874 29 161 Sum 1,266 SCCM i

15 J

c. s BCP Technical Services, Inc.

S' Grand Gulf Containment Building 1993 ILRT Final Report At the start of the Type A test, contenment absolute pressure and mean temperature were 26.592 psia and 535.06 deg R, respectively. Containment volume used for ILRT calculations is 1,670,000 cubic feet. Standard conditions (for defining SCCM) are 14.696 psia and 529.67 deg R. Using these values, a leakage rate of 1,266 SCCM is converted to 0.002 %/ day.

Prior to restart of the Type A test, penetrations 109A and 109B were isolated to

- eliminate leakage through the fission product monitor (FPM) sample panel and the associated post accident sampling system'(PASS). After depressunzation from the ILRT, the leakage at the fission product monitor was measured using local leak testing methods. The measured leakage, which was combined leakage through the FPM and the PASS, was 157,175 SCCM, which is equivalent to 0.268 %/ day.

Due to concern about the size of the leak, the condition of the FPM and PASS system piping, the need for time to analyze the isolation provisions for the FPM and PASS, and the determination that the PASS was not essential to plant.

operation, the PASS inlet was isolated by disconnecting and capping the tubing' branching off from the FPM panel. This temporary modification reduced the leakage in the resulting closed system to 30,387 SCCM, as measured during a post-modification local leak rate test. This leakage, wnich is equivalent to 0.052

%/ day, is a correction to the calculated UCL on leakage rate.

Corrections to the Type A test UCL to determine as-left leakage rate are summarized below:

Water inventory change 0.311 %/ day Penetrations not isolated by normal post-accident means 0.002 Fission product monitor leakage (after isolation of 0.052 post-accident sampling system)

Net correction to Type A UCL for as-left 0.365 %/ day 5.2 As-Left Leakage Rate The results of the Type A test, conducted after isolation of penetrations 109A and 1098, are listed below:

95% UCL on total time leakage rate -0.155 %/ day Corrections per 5.1 0.365 %/ day Final as-left leakage rate (UCL) 0.210 %/ day Acceptance limit 0.328 %/ day 16

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M Grand Gulf Containment Building 1993 ILRT Final Report  ;

The acceptance limit is 75% of the maximum allowable leakage rate (La) of 0.437 %/ day set forth in the Technical Specifications.

Total time leakage rates and UCLs computed for successive hours of test ,

l duration are listed in Table 3 and the vanations in calculated rate and UCL are plotted in Figure 5. (It is to be noted that Figure 5, as well as all other plots presented in this report, is a representation of discrete,15 minuto interval data sets. The straight lines connecting data points are generated by the plotting software and do not represent actual variations in the plotted parameters.)

The total time calculated leakage rate listed in Table 3 and plotted in Figure 5 follows a generally increasing trend over the last 5 hours5.787037e-5 days <br />0.00139 hours <br />8.267196e-6 weeks <br />1.9025e-6 months <br /> of the test. For this reason, it is necessary to extrapolate the calculated rate to a 24 hour2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> test duration as specified in Reference 3. A conservative estimate of the actual extrapolated rate is obtained by basing the increase over time on the change between 5:00 and 9:00 AM. The rate of increase between these two times is (0.285 - 0.242)/4 = 0.0108 %/ day per hour. The increase over 18 hours2.083333e-4 days <br />0.005 hours <br />2.97619e-5 weeks <br />6.849e-6 months <br /> is -

0.0108 x 18 = 0.194 %/ day. The corrected, extrapolated rate at 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> is

-0.238 + 0.194 + 0.365 = 0.321 %/ day. This is less than the 0.328 %/ day (0.75 La) acceptance limit on extrapolated calculated leakage rate.

The two times used for the extrapolation were selected based on visual examination of a leakage rate vs. time plot. The 5:00 AM and 9:00 AM values yield an extrapolated leakage rate which is observably much larger than that estimated by fairing a line through the full five hours of data. The technically correct rate of increase determined by fitting a line to the full five hours of data by the method of least squares (Reference 3 specifies linear extrapolation) is 0.0067 %/ day / hour. This number, which is closely approximated by the slope of ,

a faired line, is considerably less than the 0.108 %/ day / hour used to determine l the extrapolated leakage rate. )

The mean of the measured leakage rates over the last 5 hours5.787037e-5 days <br />0.00139 hours <br />8.267196e-6 weeks <br />1.9025e-6 months <br /> of the test is

-0.247 %/ day. The corrected mean is -0.247 + 0.365 = 0.118 %/ day, which is below the 0.437 %/ day (La) acceptance limit.

Containment conditions dunng the Type A test were reasonably typical. Air i

mass, mean temperature, total pressure and mean vapor pressure are plotted on Figures 6,7,8 and 9, respectively. The air mass shows a generally linear trend with a positive slope. The positive slope results from the increase in water inventory. In other respects, the air mass data is quite reasonable.

Containment mean temperature (Figure 7) was almost unchanged over the course of the test. The temperature / time profile is reasonably smooth.

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' 1993 ILRT Final Report i

J Vapor pressure, which is plotted in Figure 8, varied almost linearly with time and increased 0.005 psi over the course of the test. This increase is reasonable for a Mark Ill BWR containment which has large open water surfaces and the potential for significant evaporation.

< 5.3 Verification Test 1

The venfication test induced leak was imposed after the completion of the final 1

Type A test and adjusted to a flowmeter indication of 9.0 SCFM. Actual flow corrected for flowmeter discharge conditions was 8.96 SCFM. At the pressure and temperature conditions listed for the end of the Type A test (26.615 psia and 535.13 deg R), this is equivalent to a leakage rate of 0.431 %/ day. Test duration was three hours, which is the minimum required by Referance 3.

Results are detailed in Table 5 and summarized below.

Upper limit on total time calculated leakage rate 0.302 %/ day 4 Total time calculated leakage rate 0.155 %/ day

! Lower limit on total time calculated leakage rate 0.084 %/ day i

The calculated leakage rate is within the acceptance band which is the sum of Type A test total time leakage rate and the induced leakage rate, plus or minus j 0.25 La. Figure 10 illustrates the verification test results graphically.

5.4 Mass Point Results The ANSI /ANS 56.8 (Reference 5) mass point method was used, in addition to the total time method, to calculate leakage rate during the Type A test. The mass point leakage rates are shown for information in Table 5. The mass point calculated leakage rate, -0.228 %/ day, is quite close to the total time rate of 4 0.238 %/ day, as expected. The mass point UCL, -0.217 %/ day, is quite close to the mass point calculated rate, also as expected. The total time UCL,

-0.155 %/ day, is considerably greater than the mass point UCL and also considerably greater than the total time calculated rate. This is the result of the a

conservative method used to calculate the total time UCL. The calculation is discussed in Section 3.1.

i 5.5 As Found Leakage Rate including Fission Product Monitor (FPM) and Post Accident Sampling System (PASS) Leakage The leakage rate which would have been found if the test had been conducted

at the beginning of the outage, and prior to isolation valve repairs, is termed the as-found leakage rate. This leakage rate is calculated as described in the following paragraphs.

18 y .,s.

e e BCP Technical Services, Inc.

• Grand Gulf Containment Building 1993 ILRT Final Report The containment was at pressure, with conditions considered stable, for 18

' hours and 15 minutes, from 7:45 PM on November 20 until 2:00 PM on the following day. During this time the outleakage of air was changed twice. The first change resulted from closing the Penetration 109A and 1098 isolation valves, thereby isolating the leakage from the fission product monitor (FPM) panel and post-accident sampling system (PASS). The second change resulted from the venfication test imposed leak.

After the conclusion of the ILRT, the leakage at the fission product monitor (FPM) was measured using localleak rate testing methods. The as found measured leakage, which was combined leakage through the FPM and PASS

' before the PASS tubing was capped, was 157,175 SCCM. This is equivalent to an air flow of 24.94 lbm per hour. The leak was isolated between 3:30 and 3:45 AM on November 21.

The venfication test imposed leak, per 5.3 above, was 8.96 SCFM. This is equivalent to an air flow of 40.25 lbm per hour. The leakage was imposed between 9:45 and 10:00 AM on November 21.

The rate of rise in the suppression pool level was equivalent to a leakage rate of

-0.311 %/ day. At the midpoint of the test period, at 5:00 AM on November 21, the calculated quantity of air in the containment was 221,017 lbm. The inleakage equivalent to the pool rise, based on the midpoint air mass, is 28.64 lbm/hr.

Adjusting the containment air mass calculated at each 15 minute interval over the 18.25 hours2.893519e-4 days <br />0.00694 hours <br />4.133598e-5 weeks <br />9.5125e-6 months <br /> during which the mass was essentially stable yielded a table of air masses which can be plotted against time to estimate the actual containment leakage rate over the 18.7.5 hour5.787037e-5 days <br />0.00139 hours <br />8.267196e-6 weeks <br />1.9025e-6 months <br /> period. Each air mass was adjusted, as appropriate, for the effects of isolating FPM/ PASS leakage, rising suppression l I

pool level and imposing the vanfication test leak. Each air mass was adjusted as follows:

- The cumulative inleakage equivalent to suppression pool rise throughout the test period was subtracted from the air mass. For purposes of this  !

calculation, cumulative inleakage was figured from the start of the test period,7:45 PM on November 20.

- The leakage which would have passed through Penetrations 109A and 1098 if the isolation valves had not been closed was subtracted.. For purposes of this calculation, the penetrations were considered isolated at '

3:37.5 AM on November 21.

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• Grand Gulf Containment Building 1993 ILRT Final Report

. The venfication test leakage was added back to the air mass. For purposes of this calculation, the venfication test leak was considered imposed at 9:52.5 AM on November 21.

The adjusted air masses are listed in Table 6 and are plotted vs. elapsed time on Figure 11. The calculations are summanzed on the table. The plotted mass l decreases reasonably smoothly over the test period. The slope of the plot decreases with time.

The best estimate of the as found leakage rate is the asymptotic limit of the slope of the plot. Since the slope is decreasing with time (see discussion in Section 4.5), a conservative estimate is the mean slope of a final segment of the plot. The variation in the mean slope of the plot was determined for an 8 hour9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> moving segment passed through all of the adjusted mass data. The variation in the mean slope is ploded in Figure 12.

The ordinate of the initial point is the slope of a line fitted to the first E hours of adjusted mass data beginning with the 7:45 PM mass. The ordinate of the next*

}

point is the slope of a line fitted to 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> of adjusted mass data beginning with the 8:00 PM mass. The ordinates of the other points are calculated similarly, with the ordinate of the final point being the slope of a line fitted to the final 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> of adjusted mass data. The trend of the slope is negative, as expected based ori the appearance of the mass plot in Figure.11.

Table 7 lists the calculated slopes. The final listed slope is -31.0 lbm per hour.

This is the leakage rate (in mass per unit time terms) which would have been determined for the final 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> of the test (6:00 AM to 2:00 PM on November 21)if suppression pool level had been constant, Penetrations 109A and 1098 had not been isolated, and verification flow had not been imposed. The adjusted air mass at the center of this 8 hour9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> period is 220,548 lbm, as taken from the 10.00 AM entry on Table 6. The equivalent leakage rate in %/ day is As found leakage rate = 31.0 x 24 x 100 / 220,548 = 0.337 %/ day The above leakage rata must be corrected for penetrations not in post accident alignment (except for penetrations 109A and 109B, which are accounted for in the leakage rate calculated above) and minimum pathway leakage improvements made during the Type B and C testing program. The correction for penetrations not in post accident alignment is 0.002 %/ day, as shown in Section 5.1.

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• Grand Gulf Containment Building 4 1993 ILRT Final Report i

Isolation valve rework performed dunng the outage and prior to the (LRT reduced the minimum pathway leakage through several penetrations. The as-found leakage rate is calculated by adding the net minimum pathway leakage improvement to the sum of the initial Type A test UCL, the water inventory correction and the correction for penetrations not isolated by normal means.

. The following table lists minimum pathway improvements.

Penetration Minimum Pathway Leakage Improvement 6 1,263 SCCM

] 7 25,128 29 3,221 41 182

. 768 40 Sum 29,834 SCCM For a contained air mass of 220,548 lbm, the net minimum pathway improvement of 29,834 SCCM is equivalent to a leakage rate of 0.052 %/ day.

(NOTE: It is coincidental that the 0.052 %/ day minimum pathway leakage improvements figure is the same as the 0.052 %/ day calculated for as-left leakage through penetrations 109A and 109B in Section 5.1.)

4 Corrections to the Type A test UCL to determine as-found leakage rate are summarized below:

Penetrations not isolated by normal post accident means 0.002 %/ day Minimum pathway leakage rate improvements 0.052 %/ day The corrected as found leakage rate is Corrected as found leakage rate = 0.337 + 0.052 + 0.002 = 0.391 %/ day i

The calculations above demonstrate that the actual containment leakage rate at

', the end of the operating cycle was well below the maximum allowable leakage rate of La = 0.437 %/ day.

5.6 Evaluation of Fission Product Monitor Sample Panel and Post Accident Sample System Piping Design Prior to RF06, an analysis was performed to determine the applicability of Type C local leak rate testing (LLRT) defined in 10CFR Part 50, Appendix J, to cer.ain containment isolation valves. The analysis concluded that the requirement to l

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• Grand Gulf Containment Building 1993 ILRT Final Report s

perform Type C testing did not apply to several remote manual containment isolation valves that are designed and analyzed to remain open after a design basis accident (DBA). The analysis included the containment isolation valves associated with penetrations 109A and 1098, which protect sampling and return lines for the fission product monitor (FPM) sample panel and the post-accident j sampling system (PASS). On the basis of this analysis, a decision was made to remove these valves from the LLRT program and to perform Type A tests with l these valves open. This is the normal position of the valves and appeared to be i

consistent with the current licensing basis for GGNS as described in the i UFSAR.

. Dunng stabilization for and performance of the Type A test it appeared that the measured leakage rate and the UCL on leakage rate might exceed the i acceptance limit of 10CFR50, Appendix J. Leakage in the FPM sample panel' j and the PASS were discovered, and the decision was made to isolate the FPM

panel and PASS by closing the penetration 109A and 109B isolation valves.

A review of the assumptions used to remove these valves from the LLRT -

[ program indicated that, although the test configuration did appear to reflect the i current licensing basis as desenbed in the UFSAR, it did not reflect the correct design conditions. Further, there is no specific consideration of these leakage paths in the design basis accident (DBA) dose analysis. This path cannot be considered as part of the overall containment leakage. As a result, the accident analysis does not support the UFSAR description and, therefore, the correct test configuration for these valves during the ILRT should be closed.

l The containment isolation valves in penetrations 109A and 1098 are fully l qualified and are capable of closure from the control room. The FPM panelis not designed to remain operable following the onset of the DBA and is not j safety-related. The PASS, on the other hand, is designed to be operable following the DBA, but the piping connecting it to the containment penetration is 4

not designed as safety-related or seismic. Since neither the FPM panel nor the ]

j PASS is designed to withstand a DBA, the penetration 109A and 109B

containment isolation valves must not remain open during the accident, although they may be opened intermittently for post accident sampling following the accident. For this reason the valves should not have been removed from the LLRT program and should have been in their required closed positions i during the Type A test.

i Type C testing requirements are applicable to these valves. These valves should have been closed dunng the ILRT. These valves were previously included in the LLRT program, were local leak rate tested during RF06, and will continue to be Type C tested in the future. Consequently these valves will be

closed during any future ILRT.

f

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BCP Technical Services, Inc.

& Grand Gulf Containment Building 1993 ILRT Final Report Had the penetration 109A and 1098 isolation vaives been closed dunng this ILRT, the as-found Type A test would have been performed using the data collected dunng the six-hour penod immediately following stabilization. The Type A test was declared started at 7:45 PM on November 20 and would have been successfully completed at some time prior to 3:30 AM on November 21, when the initial Type A test was stopped to isolate penetrations 109A and 1098.

The end-of-test total time UCL was 0.218 %/ day at 3:30 AM on November 21, as can be seen on Table 4. Both the total time leakage rate and the UCL had been trending steadily downward almost without exception since 9:45 PM on November 20.

The leakage through the FPM and PASS was measured after the ILRT as 157,175 SCCM, which is approximately 0.271 %/ day, as discussed in Section 4.8. Had that FPM/ PASS leakage been subtracted from the UCL, the leakage rate UCL would be expected to have been 95% UCL on total time leakage rate 0.218 %/ day Subtract FPM/ PASS penetration leakage 0.271 Expected UCL on total time leakage -0.053 %/ day Add to the expected Type A test UCL to determine as-found leakage rate:

Expected Type A test total time UCL -0.053 %/ day Water inventory change (from Section 5.1) 0.311 Penetrations not isolated by normal post-accident means (from Section 5.1) 0.002 Minimum pathway leakage rate improvements (from Section 5.5) 0.052 Expected as-found leakage rate 0.312 %/ day Acceptance limit (0.75 La) 0.328 %/ day A Material Nonconformance Report (MNCR) was issued to document the excessive leakage condition and to document all action that will be taken to resolve this issue. In order to ensure that containment leakage is properly accounted for in the accident analysis a further evaluation of potential containment post accident bypass leakage paths will be done to determine the appropnate analytical requirements for all bypass leakage. In the intenm.

Standing Orders have been issued to Operations Shift Superintendents to close I the containment isolation valves in penetrations 109A and 109B upon receipt of any indication of a loss of coolant accident.

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• Grand Gulf Containment Building 1993 ILRT Final Report I

4

6. References 1

1. Code of Federal Regulations, Title 10, Part 50, Appendix J, Reactor

Containment Leakage Testing for Water Cooled Power Reactors.

2. ANSI N45.4-1972, Leakage Rate Testing of Containment Structures for Nuclear Reactors.

J

3. Bechtel Topical Report BN-TOP-1, Testing Cntena for Integrated Leakage Rate Testing of Primary Containinent Structures for Nuclear Power Plants, Revision 1,1972.

1 4 4. GGNS Surveillance Test Procedure 06-ME-1M10-0-0002, Containment

^

Integrated Leak Rate Test, Rev. 24 with TCNs 22 28. (The record copy of the test data package performed per this procedure is archived under Work Order No.106542.)

i 5. ANS!/ANS 56:8-1987, Containment System Leakage Testing  ?

Requirements.

6. Entergy Operations, Inc., Grand Gulf Nuclear Station, Containment integrated Leakage Rate Test, Test Instrumentation Relocation Study:

• Prepared by BCP Technical Services, October 1993.

i 4

4 1

)

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1993 ILRT Final Report l t

! 7. Figures and Tables Figures and tables referenced in the text and listed below follow on subsequent pages.

I Figure / Table Page Figure 1 Pressure vs. Time - Pressunzation 26 Figure 2 Temperature vs. Time - Stabilization 27 Figure 3 Air Mass vs Time - Stabilization 28 i

Figure 4 Suppression Pool Level vs. Time 29 Figure 5 Total Time Leakage Rate and UCL - Final Type A Test 30 f

! Figure 6 Air Mass vs. Time -- Final Type A Test 31

- Figure 7 Mean Temperature vs. Time - Final Type A Test 32 Figure 8 Pressure vs. Time - Final Type A Test 33 l

Figure 9 Vapor Pressure vs. Time - Final Type A Test 34 l.

Figure 10 Air Mass vs. Time - Venfication Test 35 4 Figure 11 Adjusted Air Mass vs. Duration 36 i

i Figure 12 Leakage Rate vs. Time -Rate Plotted For Midpoint of 8 Hour Moving Window 37

. Table 1 Sensor Locations and Weighting Factors 38

Table 2 Temperature Stabilization Report 39 i

j Table 3 Total Time Leakage Rate Report- Type A Test 40 1 Table 4 Total Time Leakage Rate Report - Verification Test 41 I Table 5 Mass Point Leakage Rate Report - Type A Test 42 Table 6 Adjusted Air Mass For As Found Leakage Rate Computation 43

?

Table 7 Calculated Leakage Vanation - Moving 8 Hour Window 45 25 I

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• Figure 4 Suppression Pool Level vs. Time 18.9 1600 2dOO 00'00 04b0 08b0 12b0 16bo 20Nov c

! 21Nov Figure 4 Suppression Pool Level vs. Time 29

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__ . = _ . _-__-__

BCP Technical Services, Inc.

Grand Gulf Containment Building 1993 ILRT Final Report Table 1 Sensor Locations and Weighting Factors Sensor Elevation, ft. Radius. Ft. Beanng,deg Weighting Factor Containment RTD's T01 283 12 34 0.058 T02 268 23 129 0.074 T03 255 44 244 0.082 T04 243 44 129 0.081 TOS 232 42 272 0.064 T06 224 41 35 0.056 T07 216 32 99 0.056 T08 208 50 223 0.037 T09 200 49 310 0.030 T10 192 55 49 0.030 T11 183 50 139 0.023 T12 175 52 233 0.025 T13 165 53 315 0.025-T14 160 50 17 0.018 T15 154 55 143 0.038 -

T16 142 52 213 0.039 T17 130 50 307 0.045 T18 118 49 60 0.048 Drywell RTD's T21 192 13 270 0.000 (1)

T2.2 173 26 0 0.042 T23 157 24 130 0.033 T24 141 27 211 0.033 T25 125 25 280 0.034 T26 110 25 166 0.029 Containment Dew Cells M01 268 23 129 0.241 M02 222 50 223 0.286 M03 176 53 315 0.145 M04 130 53 45 0.157 Drywell Dew Cells M21 160 24 130 0.000 (2)

M22 125 25 280 0.171 (2)

Elevations are referenced to mean sea level. Beanngs are referenced to containment 0 (main steam pipe centerline which runs essentially due east).

Notes: 1. Drywell RTD T21 monitors head space temperature for information 4 only. This RTD is assigned a zero weighting factor pending j evaluation of head space temperature changes. 1

2. Drywell dew cell M21 exhibited erratic behavior during the test l and was deleted from the calculations. The M21 weighting factor  !

of 0.088 was reallocated to M22 (original factor of 0.083).  !

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- Table 2 Temperature Stabilization Report i l  !

" Start Time = 2:30 PM on 28 Nov.

• = stabilization enterion satisfied

- ANSI - - BN-TOP elapsed temperature dT1 dT4 dT1-dT4 dT or d(dT) data time, hr T, deg F avg dT avg dT avg avg set (1 hr) (4 hr) (2 hr) (2 hr) 01 0.00 77.297 02 0.25 76.604 03 0.50 76.246 04 0.75 76.036 05 1.00 75.904 -1.393 06 1.25 75.820 -0.784

• 07 1.50 75.742 -0.504 08 1.75 75.694 -0.342 09 2.00 75.638 -0.266 -0.829* 1.273 10 2.25 75.610 -0.209 -0.497* 0.661 11 2.50 75.573 -0.169 -0.336' O.346*

12 2.75 75.537 -0.157 -0.250* 0.191*

13 3.00 75.484 -0.154 -0.210* 0.064*

14 3.25 75.453 -0.157 -0.183* 0.092*

15 3.50 75.424 -0.150 -0.159* 0.038*

16 3.75 75.412 -0.125 -0.141* 0.088*

17 4.05 75.391 -0.087 -0.442 0.355* -0.121* 0.021*

18 4.25 75.384 -0.069 -0.305 0.236* -0.113* 0.055*

19 4.50 75.365 -0.059 -0.220 0.161* -0.104* 0.035*

20 4.75 75.344 -0.068 -0.173 0.105* -0.096* 0.064*

21 5.00 75.351 -0.044 -0.138 0.094* -0.067* 0.076*

22 5.25 75.341 -0.043 -0.120 0.076* -0.056* 0.037*

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• Grand Gulf Containment Building 1993 ILRT Final Report Table 3 j Total Time Leakage Rate Report - Type A test i

i data time date elapsed dry air measured leakage uci set time mass rate rate rate (hrs) (Ibm) (%/ day) (%/ day) (%/ day) i 01 345 1121 0.00 220981.56 0.000 0.000 0.000 1 02 400 1121 0.25 20987.40 -0.254 -0.254 -0.254 1 03 415 1121 0.50 220986.01 -0.097 -0.097 -0.097 1

04 430 1121 0.75 220998.21 -0.241 -0.191 1.000 05 445 1121 1.00 221005.32 -0.258 -0.236 0.224

06 500 1121 1.25 221016.94 -0.307 -0.285 0.015

.' 07 515 1121 1.50 221015.08 -0.243 -0.276 -0.036 08 530 1121 1.75 221024.90 -0.269 -0.282 -0.084 09 545 1121 2.00 221026.88 -0.246 -0.275 -0.100

, 10 600 1121 2.25 221035.15 -0.259 -0.275 .-0.119

.' 11 615 1121 2.50 221037.81 -0.244 -0.270 -0.126 i 12 630 1121 2.75 221041,01 -0.235 -0.263 -0.127 -

i 13 645 1121 3.00 221051.41 -0.253 -0.263 -0.137

14 700 1121 3.25 221059.69 -0.261 -0.266 -0.147 i 15 715 1121 3.50 221067.70 -0.267 -0.269 -0.158 16 730 1121 3.75 221070.69 -0.258 -0.269 -0.163 17 745 1121 4.00 221075.76 -0.256 -0.268 -0.168 l

18 800 1121 4.25 221075.04 -0.239 -0.264 -0.166 19 815 1121 4.50 221073.98 -0.223 -0.258 -0.161 20 830 1121 4.75 221075.85 -0.216 -0.251 -0.155 21 845 1121 5.00 221081.61 -0.217 -0.245 -0.152 22 900 1121 5.25 221091.22 -0.227 -0.242 -0.151 23 915 1121 5.50 221100.23 -0.234 -0.241 -0.153 24 930 1121 5.75 221103.39 -0.230 -0.239 -0.154 l 25 945 1121 6.00 221111.83 -0.236 -0.238 -0.155 1

Allowable leakage rate, La = 0.437 %/ day 75% La = 0.328 %/ day Total time leakage rate = -0.238 %/ day Total time UCL = -0.155 %/ day 1

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l Table 4 Total Time Leakage Rate Report - Venfication Test i

data time date elapsed dry air measured leakage set time mass rate rate (hrs) (Ibm) (%/ day) (%/ day) 01 1100 1121 0.00 221095.24 0.000 0.000 02 1115 1121 0.25 221089.57 0.246- 0.246 03 1130 1121 0.50 221085.11 0.220 0.220

} 21089.25 0.087 0.104 i 04 1145 1121 .75 05 1200 1121 1.00 221078.34 0.183 0.136 06 1215 1121 1.25 221072.58 0.197 0.159

}

07 1230 1121 1.50 221076.41 0.136 0.141 1 08 1245 1121 1.75 221072.50 0.141 0.133 09 1300 1121 2.00 221064.68 0.166 0.139

! 10 1315 1121 2.25 221061.01 0.165 0.143 1 11 1330 1121 2.50 221058.20 0.161 0.144

$ 12 1345 1121 2.75 221054.59 0.160 0.146 13 1400 1121 3.00 221043.40 0.188 0.155 Upper limit on leakage rate = 0.302 %/ day Total time leakage rate = 0.155 %/ day

. Lower limit on leakage rate = 0.084 %/ day i

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I Grand Gulf Containment Building 1993 ILRT Final Report Table 5 Mass Point Leakage Rate Report - Type A Test time date elapsed dry air leakage uci data time mass rate rate set (hrs) (Ibm) (%/ day) (%/ day) 01 345 1121 0.00 220981.56 0.000 0.000 02 400 1121 0.25 220987.40 -0.254 -0.254 03 415 1121 0.50 220986.01 -0.097 0.678 04 430 1121 0.75 220998.21 -0.211 0.017 05 445 1121 1.00 221005.32 -0.253 -0.133 06 500 1121 1.25 221016.94 -0.301 -0.209 07 515 1121 1.50 221015.08 -0.278 -0.210 08 530 1121 1.75 221024.90 -0.280 -0.231 09 545 1121 2.00 221026.88 -0.268 -0.229 10 600 1121 2.25 221035.15 -0.267 -0.237 11 615 1121 2.50 221037.81 -0.260 -0.234 12 630 1121 2.75 221041.01 -0.251 -0.228 13 645 1121 3.00 221051.41 -0.252 -0.233 14 700 1121 3.25 221059.69 -0.256 -0.239 15 715 1121 3.50 221067,70 -0.261 -0.245 16 730 1121 3.75 221070.69 -0.261 -0.248 17 745 1121 4.00 221075.76 -0.260 -0.249 18 800 1121 4.25 221075.04 -0.255 -0.243 l 19 815 1121 4.50 221073.98 -0.246 -0.233 20 830 1121 4.75 221075.85 -0.238 -0.222 21 845 1121 5.00 221081.61 -0.231 -0.216 22 900 1121 5.25 221091.22 -0.229 -0.215 23 915 1121 5.50 221100.23 -0.229 -0.216 24 930 1121 5.75 221103.39 -0.228 -0.216 25 945 1121 6.00 221111.83 -0.228 -0.217 Allowable leakage rate, La = 0.437 %/ day 75% La = 0.328 %/ day l

Mass point leakage rate = -0.228 %/ day Mass point UCL = -0.217 %/ day l

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1 Table 6 Adjusted Air Mass for As Found Leakage Rate Computation - l

Calculated and Adjusted Air Mass, Lbm l

time Mcalc A1 A2 A3 Madj  !

date 1120 1945 221117 0 0 0 221117 1120 2000 221110 7 0 0 221103 1120 2015 221101 14 0 0 221097 i 1120 2030 221097 21 0 0 221075 1120 2045 221093 29 0 0 221064 1120 2100 221092 36 0 0 221050

+

1120 2115 221084 43 0 0 221041 1120 2130 221073 50 0 0 221023 j 1120 2145 221063 57 0 0 221006

1120 2200 221066 64 0 0 221002 1120 2215 221062 72 0 0 220990 i 1120 2230 221055 79 0 0 220976 1120 2245 221050 86 0 0 220964 4 1120 2300 221049 93 0 0 220956 1120 2315 221036 100 0 0 220936 -

1120 2330 221038 107 0 0 220931 1120 2345 221041 115 0 0 220926 1 1121 0 221037 122 0 0 220915

1121 15 221026 129 0 0 220897-2 1121 30 221021 136 0 0 220885 1121 45 221021 143 0 0 220878 1121 100 221023 150 0 0 220873 1 1121 115 221007 158 0 0 220849

,' 1121 130 221008 165 0 0 220843 1121 145 221004 172 0 0 '220832 l

1 1121 200 221001 179 0 0 220822

1121 215 221004 186 0 0 220818 4- 1121 230 221000 193 0 0 220807 1121 245 220996 200 0 0 220796 l 1121 300 220993 208 0 0 220785 1121 315 220986 215 0 0 220771 l 1121 330 220986 222 0 0 220766 1 1121 345 220990 229 3 0 220748 1 1121 400 220986 236 9 0 220741

1121 415 220985 243 16 0 220728 Mcalc - air mass calculated using containment drybulb temperature, totalpressure

and dewpoint temperature

, A1 - adjustment for supression pool rise A2 - adjustment for reduction in leakage through the FPM and PASS A3 - adjustment for venfication testimposedleak Madj - adjusted airmass = Mcalc - A1 - A2 + A3

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Grand Gulf Containment Building 1993 ILRT Final Report Table 6 (continued) l (Notes on previous page apply) )

-1 Calculated and Adjusted Air Mass, Lbm Mcalc A1 A2 A3 Madj 2 date time 430 220997 251 22 0 220724 1121 445 221004 258 26 0 220718 1121 500 221016 265 34 0 220717 1121 515 221014 272 41 0 220701

1121 530 221024 279 47 0 220698 1121 545 221026 286 53 0 220687 1121 600 221034 294 59 0 220681 4 1121 615 221037 301 65 0 220671 1121 1121 630 221040 308 72 0 220660 1121 645 221050 315 78 0 220657 1121 700 221059 322 84 0 220653 1121 715 221067 329 90 0 220648 1121 730 221070 337 97 0 220636 1121 745 221075 344 103 0 220628 -

1121 800 221074 351 109 0 220614 1121 815 221073 358 115 0 220600 1121 830 221075 365 122 0 220588 1121 845 221080 372 128 0 220580 1121 900 221090 379 134 0 220577 1121 915 221099 387 140 0 220572 l 0 220561 1121 930 221102 394 147 1121 945 221111 401 153 0 220557 1121 1000 221110 408 159 5 220548 1121 1015 221105 415- 165 15 220540

, 1121 1030 221098 422 171 25 220530

, 1121 1045 221098 430 178 35 220525

1121 1100 221094 437 184 45 220518 l 1121 1115 221088 444 190 55 220509 1121 1130 221084 451 196 65 220502

, 1121 1145 221088 458 203 75 220502 1121 1200 221077 465 209 86 220489 s 1121 1215 221071 473 215 96 220479 1121 1230 221075 480 221 106 220480 1121 1245 221071 487 228 116 220472 1121 1300 221064 494 234 126 220462 240 136 220455 l 1121 1315 221060 501 1121 1330 221057 508 246 146 220449  ;

1121 1345 221053 516 253 156 220440  !

1121 1400 221042 523 259 166 220426 l

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& Grand Gulf Containment Building 1993 ILRT Final Report 4 Table 7 Calculated Leakage Vanation - Moving 8 Hour Window Time at Window Midpoint Slope, ibm /hr (0 at 7:45 PM,20 Nov) 4.00 -45.0 4.25 -44.6 4.50 -44.3 2

4.75 -44.0 5.00 -43.5 5.25 -42.8 1 5.50 -42.2 5.75 -41.6

- 6.00 -41.1 J 6.25 -40.7 6.50 -40.1 i 6.75 -39.6 7.00 -39.1 r 7.25 -38.5 7.50 -37.8 .

7.75 -37.3 i 8.00 -36.8 4 8.25 -36.2 8.50 -35.8 i 8.75 -35.5 9.00 -35.5 9.25 -35.2 9.50 -34.7 9.75 -34.5 10.00 -34.2 j 10.25 -34.0 10.50 -33.8 4

10.75 -33.5 11.00 -33.2 11.25 32.9 11.50 -32.7 11.75 -32.5 j 12.00 -32.2 12.25 -32.1 I

12.50 -32.1 2

12.75 -32.1 13.00 -31.9 13.25 -31.8 13.50 -31.5 13.75 -31.3 14.00 -31.1 4 14.25 -31.0 45

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APPENDIX l

! CONTAl' MENT DESCRIPTION i

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d Grand Gulf Containment Building 1993 ILRT Final Report APPENDIX l CONTAINMENT DESCRIPTION Grand Gulf has a Mark Ill containment system. This consists of an extemal containment structure and an intemal drywell which enciosas the reactor. The containment is a reinforced concrete cylinder with a hemispherical dome roof and a flat base stab. The entire intemal surface of the containment is lined with a 0.25 inch thick carbon steel plate which serves as a leaktight bamer. Principal containment dimensions and elevations are:

Cylinder height - 144.73 ft (top of base mat liner to spring line)

Cylinder / dome radius -- 62 ft (to inside of liner)

Cylinder wall thickness -- 3.5 ft Dome thickness - 2.5 ft Base mat thickness - 9.5 ft Top of base mat liner -- El. 93.02 ft Top of refueling floor- El. 208.83 ft Dome spnng line - El. 237.75 ft .

The drywell is a reinforced concrete cylinder with a flat slab roof. It is concentric with the containment and anchored to the containment base mat. The roof slab has a 16 ft radius opening over the reactor to provide access for refueling. During operation, the opening is capped with a dished steel head. Pnncipal drywell dimensions and elevations are:

~

Outside radius - 41.5 ft Outside height -- 91.48 ft (from top of base mat liner)

Wall thickness - 5 ft Roof slab thickness -- 4.33 ft Top of roof slab - El.184.5 ft Top of dished closure head - El. 200.6 (+/-) ft The bottom of the containment is water filled to a nominal depth of 20 ft. This suppression pool extends into the drywell through a number of horizontal openings in the lower drywell wall.

The water is retained in a 1.5 ft wide annulus in the drywell by a concrete weir wall.

The drywell supports the upper pool which has nominal plan dimensions (inclusive of walis) of 102 ft by 44 ft. This pool is flooded to a nominal depth (above the drywell roof) of 23 ft dunng plant operation. The nominal pool surface elevation is 208 ft. The drywell steel head is submerged below the pool surface.

The containment consists of an unobstructed open area above the refueling floor and, below this level, an annular region. Above El.136 ft, the annular region is divided into sectors by the upper pool walls and various closed compartments. The annular space is open around the full circumference of the structure between the top of the suppression pool (nominal El.113 ft) and El.136 ft.

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• Grand Gulf Containment Building 1993 ILRT Final Report APPENDIX l Containment Description (Cont.)

The reactor vesselis in the center of the drywell. Over most of its height it is surrounded by a concrete shield wall which has an outside radius of 16.33 ft. Outside of the shield wall the drywell consists principally of open space.

There are numerous penetrations through both the containment and drywell walls. These penetrations, which are sealed by isolation valves, gasketed covers and welded caps (spares),.

provide access for personnel and equipment as well as feedthrough for piping and electncal conductors. The drywell is sealed from the containment during plant operation (suppression pool water provides a seal for the openings in the lower drywell wall). During the ILRT, the drywell airlock doors are opened to provide a vent path to the containment.

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1 APPENDIX 11 COMPUTER PROGRAM DISCUSSION i

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& Grand Gulf Containment Building 1993 ILRT Final Report I

APPENDIX ll COMPUTER PROGRAM DISCUSSION i I

Leakage rate is calculated using the BCP BASIC program developed by Robert E. Blum. The program runs on an IBM PC or compatible computer which interfaces to the Data Acquisition System (DAS) via an RS 232C serial interface, or IEEE-488 Data Bus. BCP provides two computers with the second serving as a backup unit.

Both mass point (ANSI 56.8, as referenced in 10 CFR 50, Appendix J) and total time (BN-TOP-1) leakage rates are calculated. The more conservative BN-TOP-1 procedure is generally required by the NRC if test duration is less than the twenty-four hour minimum established in ANSI 45.4.

Raw data from the DAS is automatically recorded on disk storage. The ILRT program converts .

raw data to engineering units, calculates the volume weighted mean drybulb temperature, vapor pressures from individual dewpoint temperatures and volume weighted mean vapor pressure. It then computes containment air mass using these weighted mean atmospheric conditions. Air mass and time data are used as input to the routines which calculate mass point and total time leakage rates. The program also contains the ASME/ANS 56.8 algorithrn-for analyzing " outliers" as part of a data rejection routine. Manual data entry and correction options are included in the program so that failure of the DAS serial output will not delay the test. Job specific predata loaded into the program include pressure transducer calibration constants, sensor volume fractions and containment free air volume. The volume fraction and free air volume data can be changed dunng the course of the test to account for sensor failure and changes in containment water inventory.

Program output includes pnnted reports and plots. Printed reports listing raw data, engineering unit conversions, weighted mean conditions and air mass are generated for each data set immediately following data input. Various diagnostic reports and plots are generated on command during the test. These include listings of leakage rates and UCL's calculated for each incremental data set, plots of the same information, plots of weighted mean atmosphenc -

conditions and air mass, and plots of individual sensor data. These same lists and plots, when generated following completion of the test, provide final documentation of leakage rate.

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APPENDIX lli 1

TEST DATA ,

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data set 1 4

time = 1430 date = 1120 A sensor raw data value s'

j temperature 1( 80.680.) = 80.680 deg. F temperature 2 ( 80.780 ) = 80.780 deg. F ,

j temperature 3 ( 80.170 ) = 80.170 deg. F  ;

temperature 4 ( 80.010 ) = 80.010 deg. F 4

temperature 5( 78.980 )- = 78.980 deg. F i temperature 6( 78.870 ) = 78.870 deg. F temperature 7( 78.550 ) = '78.550 deg. F 1 temperature 8( 78.560 ) = 78.560 deg. F i temperature 9 ( 78.480 ) e 78.480 deg. F temperature _10 ( 76.900 ) = 76.900 deg. F i*

temperature 11 ( 78.530 ) = 78.530 deg. F '

j temperature'12 ( 78.240 ) = 78.240 deg. F I temperature 13 ( 78.800 ) = 78.800'deg. F

temperature 14 ( 63.200 ) = 63.200 deg. F

! temperature 15 ( 78.240 ) = 78.240 deg. F temperature 16 ( 74.820 ) = 74.820 deg. F 1 temperature 17 ( 74.880 ) = 74.880 deg. F  !'

. temperature'18 ( 74.230-) = 74.230 deg. F j temperature 21 ( 82.060 ) = 82.060 deg. F ,

temperature 22 ( 77.750 ) = 77.750 deg. F <

j temperature'23 ( 73.940 ) = 73.940 deg. F

! temperature 24 ( 70.670 ) = 70.670 deg. F

- temperature 25 ( 71.240 ) = 71.240 deg. F i temperature 26 ( 69.560 ) = 69.560 dag. F

' dewpoint 1 ( 71.060 ) = 71.060 deg. F, 0.3763 psia

dewpoint 2 ( 69.790 ) = 69.790.deg. F, 0.3603 psia i dewpoint 3 ( 71.680 ) = 71.680 deg. F , 0.3843 psia 1 dewpoint 4 ( 69.830 ) = 69.830 deg. F , 0.3608 psia i dewpoint 21 ( 58.560 ) = 58.560'deg. F, 0.2433 psia

! dewpoint 22 ( 57.650 ) = 57.650 deg. F , 0.2354 psia i

j pressure 1 ( 26.6957-) = 26.6957 psia

' pressure 2 ( 26.6990 )- = 26.6990 psia l l

I weighted averages, volume and air mass t

i temperature = 77.29659 deg. F

} pressure = 26.69626 psia

vapor pressure- = 0.34636 psia i volume = 1670000 cu. ft.

i dry air mass = 221195.51 lbm i

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- - - - - - _ - - - - - - - - - n n ~u- , r

-tr--

i e e data set 2 time = 1445 date = 1120 sensor raw data value temperature 1( 78.920 ) = 78.920 deg. F temperature 2 ( 79.050 ) = 79.050 deg. F temperature 3 ( 78.770 ) = 78.770 deg. F temperature 4 ( 78.790 ) = 78.790 deg. F temperature 5 ( 78.020 ) = 78.020 deg. F temperature 6 ( 78.130 ) = 78.130 deg. F temperature 7 ( 77.870 ) = 77.870 deg. F temperature 8 ( 78.000 ) = 78.000 deg. F temperature 9 ( 78.070 ) = 78.070 deg. F temperature 10 ( 76.690 ) = 76.690 dag. F temperature 11 ( 78.310 ) = 78.310 deg.-F temperature 12 ( 77.890 ) = 77.890 deg. F temperature 13 ( 78.600 ) = 78.600 deg. F temperature 14 ( 62.970 ) = 62.970 deg. F temperature 15 ( 78.080 ) = 78.080 dag. F temperature 16 ( 74.540 ) = 74.540 deg. F temperature 17 ( 74.620 ) = 74.620 dag. F temperature 18 ( 74.030 ) = 74.030 deg. F temperature 21 ( 82.030 ) = 82.030 deg. F 22 ( 77.600 )

temperature = 77.600 deg. F temperature 23 ( 73.880 ) = 73.880 deg. F temperature 24 ( 70.690 ) = 70.690 deg. F temperature 25 ( 71.130 ) = 71.130 deg. F temperature 26 ( 69.530 ) = 69.530 dag. F dewpoint 1 ( 70.800 ) = 70.800 deg. F , 0.3729 psia dewpoint 2 ( 70.350 ) = 70.350 deg. F , 0.3673 psia dewpoint 3 ( 71.450 ) = 71.450 deg. F , 0.3813 psia dewpoint 4 ( 69.930 ) = 69.930 deg. F, 0.3621 psia dewpoint 21 ( 58.860 ) = 58.860 deg. F , 0.2459 psia dewpoint 22 ( 57.830 ) = 57.830 deg. F , 0.2370 psia pressure 1 ( 26.6675 ) = 26.6675 psia pressure 2 ( 26.6706 ) = 26.6706 psia weighted averages, volume and air mass temperature = 76.60400 deg. F pressure = 26.66803 psia vapor pressure = 0.34757 psia volume = 1670000 cu. ft.

dry air mass = 221233.67 lba

i o o data set 3 i

time = 1500 date = 1120 t

! sensor raw data value i

j temperature 1 ( 78.020 ) = 78.020 deg. F temperature 2 ( 78.200 ) = 78.200 deg. F temperature 3 ( 78.130 ) = 78.130 deg. F l 78.210 deg. F temperature 4 ( 78.210 ) =

temperature 5 ( 77.410 ) = 77.410 deg. F i temperature 6 ( 77.530 ) = 77.530 deg. F

temperature 7 ( 77.430 ) = 77.430 deg. F i temperature 8 ( 77.780 ) = 77.780 deg. F temperature 9 ( 77.850 ) = 77.850 deg. F temperature 10 ( 76.550 ) = 76.550 deg. F l temperature 11 ( 78.220 ) = 78.220 dag. F

'comparature 12 ( 77.680 ) = 77.680 dag. F j temperature.13 ( 78.460 ) = 78.460 deg. F temperature 14 ( 62.870 ) = 62.870 deg. F temperature 15 ( 77.890 ) = 77.890 deg. F temperature 16-( 74.540 ) = 74.540 deg. F temperature 17 ( 74.550 ) = 74.550 deg. F

temperature 18 ( 73.920 ) = 73.920 deg. F

temperature 21 ( 82.090 ) = 82.090 dag. F ,

8 ' temperature 22 ( 77.580 ) = 77.580 deg. F 3 temperature 23 ( 73.920 ) = 73.920 deg. F temperature 24 ( 70.630 ) = 70.630 deg. F r

temperature 25 ( 71.130 ) = 71.130 deg. F temperature 26 ( 69.540 ) = 69.540 deg. F

! dewpoint 1 ( 70.660 )' = 70.660 dag. F , 0.3712 psia i dewpoint 2 ( 70.480 ) = 70.480 dag. F , 0.3689 psia i dewpoint 3 ( 71.260 ) = 71.260 dag. F, 0.3788 psia dewpoint 4 ( 69.940 ) = 69.940 deg. F , 0.3622 psia dewpoint 21 ( 59.070 ) = 59.070 deg. F, 0.2478 psia i dewpoint 22 ( 58.040 ) = 58.040 deg. F , 0.2388 psia i

j pressure 1 ( 26.6518 ) = 26.6518 psia

pressure 2 ( 26.6549 ) = 26.6549 psia l weighted averages, volume and air mass 1

temperature = 76.24580 deg. F i pressure = 26.65233 psia j vapor pressure = 0.34758 psia

volume- = 1670000 cu. ft.

l dry air mass = 221249.38 lba i

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time = 1515 date = 1120 J

sensor raw data value temperature 1( 77.660 ) = 77.660 deg. F temperature 2( 77.820 ) = 77.820 deg. F temperature 3( 77.720 ) = 77.720 deg. F temperature 4( 77.880 ) = 77.880 deg. F J

temperature 5 ( 77.040 ) = 77.040 deg. F temperature 6( 77.110 ) = 77.110 deg. F 4

temperature 7 ( 77.100 ) = 77.100 deg. F j temperature 8 ( 77.600 ) = 77.600 deg. F temperature 9 ( 77.700 ) = 77.700 deg..F temperature 10 ( 76.400 ) = 76.400 deg. F i temperature 11 ( 78.160 ) = 78.160 deg. F temperature 12 ( 77.500 ) = 77.500 deg. F temperature 13 ( 78.320 ) = 78.320 deg. F

> temperature 14 ( 62.840 ) = 62.840 dag. F temperature 15 ( 77.680 ) = 77.680 deg. F d

temperature 16 ( 74.470 ) = 74.470 deg. F temperature 17 ( 74.520 ) = 74.520 dag. F temperature 18 ( 73.840 ) = 73.840 deg. F temperature 21 ( 82.000 ) = 82.000 deg. F 1 temperature 22 ( 77.520 ) = 77.520 dag. F '

{ temperature 23 ( 73.970 ) = 73.970 deg. F

, temperature 24 ( 70.690 ) = 70.690 deg. F 71.230 )

temperature 25 ( = 71.230 deg. F temperature 26 ( 69.570 ) = 69.570 deg. F 4

l dewpoint 1 ( 70.680 ) = 70.680 deg. F , 0.3714 psia dewpoint 2 ( 70.510 ) = 70.510 deg. F , 0.3693 psia dewpoint 3 ( 71.210 ) = 71.210 deg. F , 0.3782 psia dewpoint 4 ( 69.970 ) = 69.970 dag. F , 0.3626 psia dewpoint 21 ( 59.240 ) = 59.240 dag. F, 0.2493 psia dewpoint 22 ( 58.300 ) = 58.300 deg. F , 0.2410 psia t

pressure 1 ( 26.6413 ) = 26.6413 psia

pressure 2 ( 26.6445 ) = 26.6445 psia weighted averages, volume and air mass temperature = 76.03598 deg. F

pressure = 26.64185 psia j vapor pressure = 0.34810 psia volume = 1670000 cu. ft.

dry air mass = 221243.51 lbm A

. .. . -- .. - - _ . . e .

o. o i

data set 5 l

time = 1530 date = 1120 sensor raw data value temperature 1( 77.430 ) = 77.430 deg. F temperature 2 ( 77.560 ) = 77.560 deg. F temperature 3( 77.500 ) = 77.500 deg. F temperature 4( 77.680 ) = 77.680 dag. F temperature 5( 76.810 ) = 76.810-deg. F temperature 6( 76.890 ) = 76.890 deg. F temperature 7 ( 76.880 ) = 76.880 deg. F t ' temperature 8( 77.460 ) = 77.460 deg. F l temperature 9( 77.560 ) = 77.560 dag. F  ;

temperature 10 ( 76.300 ) = 76.300 deg. F temperature 11 ( 78.120 ) = 78.120 deg. F temperature 12 ( 77.390') = 77.390 dag. F temperature 13 ( 78.220 ) = 78.220 dag. F temperature 14 ( 62.830 ) = 62.830 deg. F temperature 15 ( 77.450 ) = 77.450 deg. F-temperature 16 ( 74.470-) = 74.470 deg. F temperature 17 ( 74.490 ) = 74.490 deg. F temperature 18-( 73.770-) = _ 73.770 deg. F temperature 21 ( 82.050 ) = 82.050 deg. F ,

temperature 22 ( 77.510 ) = 77.510 deg. F temperature 23 ( 73.970 ,' = 73.970 dag. F temperatt.re 24.( 70.800 ) = 70.800 deg._F temperatare 25 ( 71.230 ) = 71.230 deg. F.

temperature 26 ( 69.640 ) = 69.640 deg. F dewpoint 1 ( 70.560 ) = 70.560 deg. F, 0.3699 psia '

dewpoint 2 ( 70.520 ) = 70.520 deg. F , 0.3694 psia i 71.130 ) F, 0.3772 psia dewpoint 3 ( = 71.130 deg. i dewpoint 4 ( 70.050 ) = 70.050 deg. F , 0.3635 psia dewpoint 21 ( 59.560 ) = 59.560;deg. F ,'0.2521 psia-dewpoint 22 ( 58.530 ) = 58.530 deg. F , 0.2430 psia pressure 1 ( 26.6337 ) = 26.6337 psia -

pressure 2 ( 26.6367 ) = 26.6367 psia weighted averages, volume and air taass temperature = 75.90371 deg. F pressure = 26.63421 psia .

vapor. pressure = 0.34812 psia l volume = 1670000 cu. ft.

dry air mass = 221233.72 lba P

-- ,, a e- , ,, ---v ,-m.,- p n , - en e 4 w ,-e .y e

e e data set 6 time = 1545 date = 1120 sensor raw data value temperature 1( 77.280 ) = 77.280 deg. F temperature 2( 77.410 ) = 77.410 deg. F temperature 3 ( 77.330 ) = 77.330 deg. F temperature 4 ( 77.520 ) = 77.520 deg. F temperature 5( 76.620 ) = 76.620 deg. F temperature 6( 76.730 ) = 76.730 deg. F temperature 7 ( 76.810 ) = 76.810 deg. F temperature 8 ( 77.380 ) = 77.380 deg. F temperature 9( 77.460 ) = 77.460 deg. F temperature 10 ( 76.170 ) = 76.170 deg. F temperature 11 ( 78.070 ) = 78.070 deg. F temperature 12 ( 77.290 ) = 77.290 deg. F temperature 13 ( 78.130 ) = 78.130 deg. F temperature 14 ( 62.800 ) = 62.800 deg. F temperature 15 ( 77.430 ) = 77.430 deg. F temperature 16 ( 74.470 ) = 74.470 deg. F temperature 17 ( 74.490 ) = 74.490 deg. F temperature 18 ( 73.740 ) = 73.740 deg. F temperature 21 ( 82.060 ) = 82.060 deg. F 77.530 )

temperature 22 ( = 77.530 deg. F temperature 23 ( 73.980 ) = 73.980 deg. F temperature 24 ( 70.790 ) = 70.790 deg. F temperature 25 ( 71.310 ) = 71.310 deg. F temperature 26 ( 69.710 ) = 69.710 deg. F dewpoint 1 ( 70.600 ) = 70.600 deg. F , 0.3704 psia dewpoint 2 ( 70.500 ) = 70.500 deg. F , 0.3692 psia dewpoint 3 ( 71.090 ) = 71.090 deg. F , 0.3766 psia dewpoint 4 ( 70.090 ) = 70.090 deg. F , 0.3640 psia dewpoint 21 ( 59.770 ) = 59.770 deg. F , 0.2540 psia devpoint 22 ( 58.800 ) = 58.800 deg. F, 0.2454 psia pressure 1 ( 26.6274 ) = 26.6274 psia pressure 2 ( 26.6305 ) = 26.6305 psia weighted averages, volume and air mass temperature = 75.81957 deg. F pressure = 26.62793 psia vapor pressure = 0.34;158 psia volume = 1670000 cu. ft.

dry air mass = 221211.75 lbm

i data set 7 time = 1600 date = 1120 sensor raw data value temperature 1( 77.150 ) = 77.150 deg. F temperature 2( 77.260 ) = 77.260 deg. F temperature 3( 77.170 ) = 77.170 deg. F temperature 4( 77.400 ) = 77.400 deg. F temperature 5( 76.470 ) = 76.470 deg. F temperature 6( 76.590 ) = 76.590 deg. F temperature 7 ( 76.670 ) = 76.670 deg. F temperature 8 ( 77.310 ) = 77.310 deg. F temperature 9 ( 77.370 ) = 77.370 deg. F temperature 10 ( 76.110 ) = 76.110 deg. F temperature 11 ( 77.990 ) = 77.990 deg. F temperature 12-( 77.210 ) = 77.210 deg. F temperature 13 ( 78.030 ) = 78.030 deg. F temperature it ( 62.820 ) = 62.820 deg. F-temperature 15 ( 77.350 ) = 77.350 deg. F temperature 16 ( 74.450 ) = 74.450 deg. F temperature 17 ( 74.450 ) = 74.450 deg. F temperature 18 ( 73.700 ) = 73.700 deg. F temperature 21 ( 82.080 ) = 82.080 deg. F .

temperature 22 ( 77.550 ) = 77.550 deg. F temperature 23 ( 74.040 ) = 74.040 deg. F temperature 24 ( 70.870 ) = 70.870 deg. F temperature 25 ( 71.370 ) = 71.370 deg. F temperature 26 ( 69.770 ) = 69.770 deg. F dewpoint 1 ( 70.640 ) = 70.640 deg. F, 0.3709 psia dewpoint 2 ( 70.510 ) = 70.510 deg. F , 0.3693 psia dewpoint 3 ( 71.040 ) = 71.040 deg. F , 0.3760 psia dewpoint 4 ( 70.110 ) = 70.110 deg. F , 0.3643 psia j 60.040 )

dewpoint 21 ( = 60.040 deg. F , 0.2565 psia dewpoint 22 ( 59.020 ) = 59.020 deg. F , 0.2473 psia i l

pressure 1 ( 26.6221 ) = 26.6221 psia '

pressure 2 ( 26.6253 ) = 26.6253 psia weighted averages, volume and air mass temperature = 75.74200 deg. F pressure = 26.62265 psia vapor pressure = 0.34901 psia volume = 1670000 cu. ft.

dry air mass = 221195.67 lbm l

1 1

data set 8 time = 1615 date = 1120 sensor raw data value temperature 1 ( 77.050 ) = -77.050 deg. F temperature 2 ( 77.150 ) = 77.150 deg. F temperature 3 ( 77.100 ) = 77.100 deg. F temperature 4 ( 77.280 ) = 77.280 deg. F temperature 5 ( 76.360.) = 76.360 deg. F temperature 6 ( 76.510 ) = 76.510 deg. F temperature 7 ( 76.520 ) = 76.520 dag. F temperature 8 ( 77.250 ) = 77.250 dag. F temperature 9 ( 77.280 ) = 77.280 deg. F temperature 10 ( 76.060 ) = 76.060 dag. F temperature'll ( 77.880 ) . = 77.880 deg. F temperature 12 ( 77.160 ) = 77.160 deg. F temperature 13 ( 77.950 ) = 77.950 deg. F temperature 14 ( 62.840 ) = 62.840 deg. F temperature 15 ( 77.250') = 77.250'deg. F temperature 16 ( 74.510 ) = 74.510 deg. F temperature 17 ( 74.430 ) = 74.430 deg. F temperature 18 ( 73.680 ) = 73.680 dag. F temperature 21 ( 82.180-) = 82.180 deg. F .

temperature 22 ( 77.580-) = 77.580 dag. F temperature 23 ( 74.100 ) = 74.100 deg. F .

temperature 24 ( 70.990 )- = 70.990 deg. F.

temperature 25 ( 71.540 ) = 71.540 dag.-F temperature 26 ( 69.870 ) = 69.870 deg. F dewpoint 1 ( 70.530 ) = 70.530 deg. F, 0.3695 psia dewpoint 2 ( 70.530 ) = 70.530 deg. F , 0.3695 psia dowpoint 3 ( 71.040 ) = 71.040 deg. F , 0.3760 psia dewpoint 4 ( 70.150 ) = 70.150 deg. F , 0.3648 psia dewpoint 21 ( 60.460 ) = 60.460 deg. F , 0.2603 psia dewpoint 22 ( 59.280 ) = 59.280 deg. F , 0.2496 psia '

pressure 1 ( 26.6184 ) = 26.6184 psia pressure 2 ( 26.6217 ) = 26.6217 psia weighted averages, volume and air. mass temperature = 75.69392 deg. F  !

pressure = 26.61897 psia j vapor pressure = 0.34922 psia l volume = '1670000 cu. ft.

dry air mass = 221182.75 lba l

- ,6 - - , - - - - - a

e e l i

data set 9 time = 1630 date = 1120 sensor raw data value temperature 1 ( 76.940 ) = 76.940 deg. F temperature 2 ( 77.050 ) = 77.050 deg. F temperature 3 ( 76.990 ) = 76.990 dag. F temperature 4 ( 77.230 ) =' 77.230 deg. F temperature 5 ( 76.290 ) = 76.290 deg. F temperature 6 ( 76.410 ) = 76.410 deg. F temperature 7 ( 76.370 ) = 76.370 deg. F temperature 8 ( 77.160 ) = 77.160 deg. F temperature 9 ( 77.180 ) = 77.180 deg. F temperature 10 ( 75.980 ) = 75.980 deg. F temperature.11 ( 77.820 ) = 77.820 deg. F temperature 12 ( 77.090 ) = 77.090 deg. F temperature 13 ( 77.880 ) = 77.880 deg. F temper,ature 14 ( 62.860 ) = 62.860 deg. F temperature 15 ( 77.130 ) = 77.130 dag. F temperature 16 ( 74.510 ) = 74.510 deg. F temperature 17 ( 74.410 ) = 74.410_deg. F temperature 18 ( 73.640 ) = 73.640 deg. F temperature 21 ( 82.240 ) = 82.240 deg. F .

temperature 22 ( 77.630 ) = 77.630 deg. F temperature 23 ( 74.140 ) = 74.140 deg. F temperature 24 ( 71.090 ) = 71.090 deg. F temperature 25 ( 71.560 ) = 71.560 deg. F temperature 26 ( 69.950 ) = 69.950 deg. F devpoint 1 ( 70.650 ) = 70.650 deg. F , 0.3710 psia dewpoint 2 ( 70.520 ) = 70.520 deg. F , 0.3694 psia dewpoint 3 ( 71.020-) = 71.020 deg. F , 0.3757 psia dewpoint 4 ( 70.160 ) = 70.160 deg. F , 0.3649 psia dewpoint 21 ( 60.370 ) = 60.370 deg. F , 0.2595 psia dewpoint 22 ( 59.490 ) = 59.490 deg. F , 0.2515 psia pressure 1 ( 26.6157 ) = 26.6157 psia pressure 2 ( 26.6190 ) = 26.6190 psia weighted averages, volume and air mass temperature = 75.63804 deg. F pressure = 26.61626 psia vapor pressure = 0.34986 psia volume = 1670000 cu. ft.

dry air mass = 221177.77 lbm

o o data set 10 time = 1645 date = 1120 sensor raw data value temperature 1( 76.860 ) = 76.860 deg. F temperature 2( 77.090 ) = 77.090 deg. F temperature 3( 77.020 ) = 77.020 deg. F temperature 4( 77.150 ) = 77.150 deg. F temperature 5( 76.210 ) = 76.210 deg. F temperature 6( 76.380 ) = 76.380 deg. F temperature 7( 76.300 ) = 76.300 deg. F 8( 77.080 )

temperature = 77.080 deg. F temperature 9 ( 77.100 ) = 77.100 deg. F temperature 10 ( 75.920 ) = 75.920 deg. F temperature 11 ( 77.410 ) = 77.410 deg. F temperature 12 ( 76.960 ) = 76.960 deg. F temperature 13 ( 77.800 ) = 77.800 deg. F temperature 14 ( 62.860 ) = 62.860 deg. F temperature 15 ( 77.240 ) = 77.240 deg. F temperature 16 ( 74.530 ) = 74.530 deg. F temperature 17 ( 74.410 ) = 74.410 deg. F temperature 18 ( 73.610 ) = 73.610 deg. F temperature 21 ( 82.230 ) = 82.230 deg. F ,

temperature 22 ( 77.700 ) = 77.700 deg. F temperature 23 ( 74.210 ) = 74.210 deg. F temperature 24 ( 71.050 ) = 71.050 deg. F temperature 25 ( 71.590 ) = 71.590 deg. F temperature 26 ( 70.010 ) = 70.010 deg. F dewpoint 1 ( 70.670 ) = 70.670 deg. F, 0.3713 psia dewpoint 2 ( 70.510 ) = 70.510 deg. F , 0.3693 psia dewpoint 3 ( 71.040 ) = 71.040 deg. F , 0.3760 psia dewpoint 4 ( 70.220 ) = 70.220 deg. F , 0.3657 psia dewpoint 21 ( 57.260 ) = 57.260 deg. F , 0.2322 psia dewpoint 22 ( 59.690 ) = 59.690 deg. F , 0.2533 psia pressure 1 ( 26.6137 ) = 26.6137 psia pressure 2 ( 26.6170 ) = 26.6170 psia weighted averages, volume and air mass temperature = 75.61021 deg. F pressure = 26.61427 psia vapor pressure = 0.35034 psia volume = 1670000 cu. ft.

dry air mass = 221168.33 lbm

^ e data set 11 .

I time = 1700 date = 1120 sensor raw data value i

j temperature 1( 76.800 ) -= 76.800 deg. F temperature 2( 77.030 ) = 77.030 deg. F

temperature 3( 77.000 ) = 77.000 deg. F

temperature 4( 77.140 ) = 77.140 deg. F temperature 5( 76.190 ) = 76.190 deg. F temperature 6( 76.370 ) = 76.370 deg. F j temperature 7( 76.340 ) = 76.340 deg. F i temperature 8( 76.900 ) = 76.900 deg. F l

temperature 9( 77.000 ) = 77.000 deg. F l

i temperature 10 ( 75.830 ) = 75.830 deg. F l temperature 11 ( 77.040 ) = 77.040 deg. F l j temperature 12 ( 76.810 ) = 76.810 deg. F i temperature 13 ( 77.740 ) = 77.740 deg. F 4 temperature 14 ( 62.900 ) = 62.900 deg. F temper 5ture 15 ( 77.040 ) = 77.040 deg. F temperature 16 ( 74.370 ) = 74.370 deg. F temperature 17 ( 74.400 ) = 74.400 deg. F y

temperature 18 ( 73.590 ) = 73.590 deg. F 82.260 ) 82.260 deg. F -

temperature 21 ( =

2 temperature 22 ( 77.760 ) = 77.760 deg. F temperature 23 ( 74.240 ) = 74.240 dag. F

temperature 24 ( 71.150 ) = 71.150 deg. F

, temperature 25 ( 71.720 ) = 71.720 deg. F temperature 26 ( 70.090 ) = 70.090 deg. F i

! dewpoint 1 ( 70.740 ) = 70.740 deg. F , 0.3722 psia

, dewpoint 2 ( 70.520 ) = 70.520 deg. F , 0.3694 psia dewpoint 3 ( 71.030 ) = 71.030 dag. F , 0.3759 psia dewpoint 4 ( 70.230 ) = 70.230 deg. F , 0.3658 psia i dewpoint 21 ( 60.770 ) = 60.770 dag. F , 0.2632 psia j dewpoint 22 ( 59.890 ) = 59.890 deg. F , 0.2551 psia i pressure 1 ( 26.6115 ) = 26.6115 psia ,

pressure 2 ( 26.6148 ) = 26.6148 psia i

4 j weighted averages, volume and air mass i

temperature = 75.57349 deg. F

, pressure = 26.61206 psia vapor pressure = 0.35090 psia volume = 1670000 cu. ft.

dry air mass = 221160.25 lba E

1

4 o data set 12 time = 1715 date = 1120 sensor raw data value temperature 1( 76.760 ) = 76.760 deg. F temperature 2( 76.960 ) = 76.960 deg. F temperature 3( 76.970 ) = 76.970 deg. F l temperature 4 ( 77.070 ) = 77.070 deg. F temperature 5( 76.150 ) = 76.150 deg. F temperature 6( 76.310 ) = 76.310 deg. F temperature 7 ( 76.250 ) = 76.250 deg. F temperature 8( 76.840 ) = 76.840 deg. F temperature 9( 76.900 ) = 76.900 deg. F temperature 10 ( 75.790 ) = 75.790 deg. F temperature 11 ( 77.000 ) = 77.000 deg. F temperature 12 ( 76.700 ) = 76.700 deg. F temperature 13 ( 77.640 ) = 77.640 deg. F temperature 14 ( 62.920 ) = 62.920 deg. F temperature 15 ( 77.030 ) = 77.030 deg. F temperature 16 ( 74.300 ) = 74.300 deg. F temperature 17 ( 74.330 ) = 74.330 deg. F temperature 18 ( 73.570 ) = 73.570 deg. F temperature 21 ( 82.270 ) = 82.270 deg. F ,

temperature 22 ( 77.800 ) = 77.800 deg. F temperature 23 ( 74.300 ) = 74.300 dag. F temperature 24 ( 71.240 ) = 71.240 deg. F temperature 25 ( 71.740 ) = 71.740 deg. F temperature 26 ( 70.150 ) = 70.150 deg. F dewpoint 1 ( 70.690 ) = 70.690 deg. F , 0.3716 psia dewpoint 2 ( 70.490 ) = 70.490 deg. F , 0.3690 psia dewpoint 3 ( 71.010 ) = 71.010 deg. F, 0.3756 psia dewpoint 4 ( 70.230 ) = 70.230 deg. F, 0.3658 psia dewpoint 21 ( 60.940 ) = 60.940 deg. F , 0.2648 psia dewpoint 22 ( 60.060 ) = 60.060 deg. F, 0.2567 psia pressure 1 ( 26.6085 ) = 26.6085 psia pressure 2 ( 26.6119 ) = 26.6119 psia weighted averages, volume and air mass temperature = 75.53678 deg. F pressure = 26.60908 psia vapor pressure = 0.35087 psia volume = 1670000 cu. ft.

dry air mass = 221150.57 lbm

data set 13 time = 1730 date = 1120 sensor raw data value temperature 1( 76.700 ) = 76.700 deg. F temperature 2( 76.900 ) = 76.900 deg. F temperature 3( 76.850 ) = 76.850 deg. F temperature 4( 77.050 ) = 77.050 deg. F temperature 5( 76.080 ) = 76.080 deg. F temperature 6( 76.250 ) = 76.250 deg. F temperature 7( 76.130 ) = 76.130 deg. F temperature 8( 76.770 ) = 76.770 deg. F temperature 9( 76.840 ) = 76.840 deg. F temperature 10 ( 75.740 ) = 75.740 deg. F temperature 11 ( 76.870 ) = 76.870 deg. F temperature 12 ( 76.670 ) = 76.670 deg. F temperature 13 ( 77.570 ) = 77.570 deg. F temperature 14 ( 62.940 ) = 62.940 deg. F temperature 15 ( 76.890 ) = 76.890 deg. F temperature 16 ( 74.310 ) = 74.310 deg. F temperature 17 ( 74.320 ) = 74.320 deg. F temperature 18 ( 73.530 ) = 73.530 deg. F temperature 21 ( 82.340 ) = 82.340 deg. F .

temperature 22 ( 77.780 ) = 77.780 deg. F temperature 23 ( 74.360 ) = 74.360 deg. F temperature 24 ( 71.300 ) = 71.300 deg. F iemperature 25 ( 71.680 ) = 71.680 deg. F temperature 26 ( 70.100 ) = 70.100 deg. F dewpoint 1 ( 70.630 ) = 70.630 deg. F, 0.3708 psia dewpoint 2 ( 70.530 ) = 70.530 deg. F , 0.3695 psia dewpoint 3 ( 71.010 ) = 71.010 deg. F , 0.3756 psia dewpoint 4 ( 70.230 ) = 70.230 deg. F, 0.3658 psia dewpoint 21 ( 61.300 ) = 61.300 deg. F, 0.2682 psia dewpoint 22 ( 60.260 ) = 60.260 deg. F, 0.2585 psia pressure 1 ( 26.6058 ) = 26.6058 psia pressure 2 ( 26.6090 ) = 26.6090 psia weighted averages, volume and air mass temperature = 75.48440 deg. F pressure = 26.60635 psia vapor pressure = 0.35115 psia volume = 1670000 cu. ft.

dry air mass = 221146.88 lbm

. . . . - ~ - . ._ . _ . _ - . _. . -,_ . _ - _ _ _ _ _

d -

data set 14 time = 1745 date = 1120 sensor raw data value temperature 1 (. 76.670 ) = 76.670 dag. F temperature 2 ( 76.850 ) = 76.850 dag. F temperature 3 ( 76.870 ) = 76.870 deg. F temperature -4 ( 76.990 ) = 76.990 dag. F temperature. 5 ( 76.030 ) = 76.030 deg. F temperature 6 ( 76.210 ) = 76.210 deg. F temperature 7 ( 76.120 ) = 76.120 deg. F temperature 8 ( 76.730 ) = 76.730 deg. F '

temperature 9 ( 76.750 ) = 76.750 deg. F temperature 10 ( 75.600 ) = 75.600 deg. F temperature 11 ( 76.750 ) = 76.750 deg. F temperature 12 ( 76.600 ) = 76.600 deg. F temperature 13 ( 77.510 ) = 77.510 deg. F temperature 14 ( 62.970 ) = 62.970 deg.-F temperature 15 ( 76.860 ) = 76.860 deg. F temperature 16 ( 74.310 ) = 74.310 deg. F temperature 17 ( 74.300 ) = 74.300 deg. F temperature 18 ( 73.530 ) = 73.530 dag. F temperature 21 ( 82.340 ) = 82.340 deg. F ,

temperature 22 ( 77.710 ) = 77.710 deg. F temperature 23 ( 74.370 ) = 74.370 deg. F temperature 24 ( 71.260 ) = 71.260 dag. F temperature 25 ( 71.760 ) = 71.760 deg. F temperature 26 ( 70.100 ) = 70.100 dag. F dewpoint 1 ( 70.710 ) = 70.710 deg. F , 0.3718 psia dewpoint 2 ( 70.480 ) = 70.480 deg. F , 0.3689. psia dewpoint 3 ( 70.990 ) = 70.990 deg. F , 0.3754 psia dewpoint 4 ( 70.270 ) = 70.270 deg. F, 0.3663 psia dewpoint 21 ( 61.310 ) = 61.310 deg. F , 0.2683 psia dewpoint 22 ( 60.440 ) = 60.440 deg. F , 0.2602 psia ,

pressure 1 ( 26.6038 ) = 26.6038 psia pressure 2 ( 26.6071 ) = 26.6071 psia weighted averages, volume and air mass temperature = 75.45283 deg. F pressure = 26.60436 psia vapor pressure = 0.35153 psia volume = 1670000 cu. ft, dry air mass = 221139.94 lba l

_. - - . ... . . . ~ . . -

,4 e i

3 data set 15

^

time u 1800 date = 1120 sensor raw data value l

I temperature 1( 76.620 ) = 76.620 deg. F temperature 2 ( 76.820 ). = 76.820 deg. F temperature 3( 76.800 ) = 76.800 deg. F.

lj temperature 4( 76.960 ) = 76.960 deg. F j temperature 5( 75.940 ) = 75.940 deg. F i temperature 6( 76.180 ) = 76.180.deg. F j temperature 7 ( 76.100 ) = 76.100 deg. F temperature 8( 76.690 ) = 76.690 deg. F

, temperature 9 ( 76.720 ) = 76.720 deg. F 1 temperature 10 ( 75.570 ) = 75.570 deg. F temperature 11 ( 76.770 ) = 76.770 deg. F

temperature 12 ( 76.580 ) = 76.580 deg. F i temperature 13 ( 77.440 ). = 77.440 deg. F temperature 14 ( 63.010 ) = 63.010 dag. F '

temper'ature 15 ( 76.870 ) = 76.870 dag. F

, temperature 16.( 74.250 ) = 74.250 deg. F temperature 17 ( 74.280 ) = 74.280 deg. F j temperature 18 ( 73.510 ) = 73.510 deg. F

temperature 21 ( 82.390 ) = 82.390 deg. F

• 77.690 ) 77.690 deg. F temperature 22 ( =

j temperature 23 ( 74.400 ) = 74.400 deg..F l temperature 24 ( 71.300 ) = 71.300 deg. F temperature 25 ( 71.720 ) = 71.720 deg. F temperature 26 ( 70.130 ) = 70.130 deg. F

• dewpoint 1 ( 70.680 ) = 70.680 deg. F , 0.3714 psia dewpoint 2 ( 70.470 ) = 70.470 deg. F , 0.3688 psia l dewpoint 3 ( 70.980 ) = 70.980 deg. F , 0.3752 psia i dewpoint 4 ( 70.270 ) = 70.270 deg. F , 0.3663 psia j dewpoint 21 ( 61.470 ) = 61.470 dag. F, 0.2698 psia dewpoint 22 ( 60.570 ) = 60.570 deg. F , 0.2614 psia i

pressure 1 ( 26.6022 ) = 26.6022 psia

pressure 2 ( 26.6055 ) = 26.6055 psia

! weighted averages, volume and air mass I

! temperature = 75.42389 deg. F pressure = 26.60276 psia j vapor pressure = 0.35159 psia 1 volume = 1670000 cu. ft.

j dry air mass = 221137.90 lba

- l d

l

o. c data set 16 time = 1815 date = 1120 sensor raw data value temperature 1( 76.600 ) = 76.600 deg. F temperature 2( 76.790 ) = 76.790 deg. F temperature 3( 76.820 ) = 76.820 deg. F temperature 4( 76.840 ) = 76.840 deg. F temperature 5( 75.980 ) = 75.980 deg. F temperature 6( 76.140 ) = 76.140 deg. F temperature 7( 76.060 ) = 76.060 deg. F temperature 8( 76.670 ) = 76.670 deg. F temperature 9 ( 76.650 ) = 76.650 deg. F temperature 10 ( 75.520 ) = 75.520 deg. F temperature 11 ( 76.780 ) = 76.780 deg. F temperature 12 ( 76.550 ) = 76.550 deg. F temperature 13 ( 77.390 ) = 77.390 deg. F temperature 14 ( 63.040 ) = 63.040 deg. F temperature 15 ( 76.810 ) = 76.810 deg. F temperature 16 ( 74.270 ) = 74.270 deg. F temperature 17 ( 74.260 ) = 74.260 deg. F temperature 18 ( 73.500 ) = 73.500 deg. F temperature 21 ( 82.360 ) = 82.360 deg. F

• temperature 22 ( 77.700 ) = 77.700 deg. F temperature 23 ( 74.480 ) = 74.480 dag. F temperature 24 ( 71.370 ) = 71.370 deg. F temperature 25 ( 71.790 ) = 71.790 deg. F temperature 26 ( 70.190 ) = 70.190 deg. F dewpoint 1 ( 70.640 ) = 70.640 deg. F , 0.3709 psia dewpoint 2 ( 70.450 ) = 70.450 deg. F , 0.3685 psia dewpoint 3 ( 70.980 ) = 70.980 deg. F , 0.3752 psia dewpoint 4 ( 70.270 ) = 70.270 deg. F , 0.3663 psia dewpoint 21 ( 61.600 ) = 61.600 deg. F , 0.2711 psia dewpoint 22 ( 60.770 ) = 60.770 deg. F , 0.2632 psia pressure 1 ( 26.6011 ) = 26.6011 psia pressure 2 ( 26.6044 ) = 26.6044 psia weighted averages, volume and air mass temperature = 75.41176 deg. F pressure = 26.60167 psia  !

vapor pressure = 0.35172 psia I volume = 1670000 cu. ft. l dry air mass = 221132.62 lbm

e c l

data set 17 l

time = 1833 date = 1120 sensor raw data value temperature 1( 76.540 ) = 76.540 deg. F l l

temperature 2( 76.770 ) = 76.770 deg. F temperature 3( 76.720 ) = 76.720 deg. F temperature 4( 76.830 ) = 76.830 deg. F temperature 5 ( 75.890 ) = 75.890 deg. F temperature 6 ( 76.090 ) = 76.090 deg. F temperature 7 ( 76.020 ) = 76.020 deg. F l

temperature 8 ( 76.590 ) = 76.590 deg. F temperature 9 ( 76.620 ) = 76.620 deg. F f temperature 10 ( 75.470 ) = 75.470 deg. F l temperature 11 ( 76.710 ) = 76.710 deg. F temperature 12 ( 76.530 ) = 76.530 deg. F temperature 13 ( 77.330 ) = 77.330 deg. F i temperature 14 ( 63.090 ) = 63.090 deg. F l temperature 15 ( 76.710 ) = 76.710 deg. F l temperature 16 ( 74.300 ) = 74.300 deg. F  ;

temperature 17 ( 74.260 ) = 74.260 deg. F l temperature 18 ( 73.500 ) = 73.500 deg. F j temperature 21 ( 82.450 ) = 82.450 deg. F

• temperature 22 ( 77.730 ) = 77.730 deg. F temperature 23 ( 74.550 ) = 74.550 deg. F temperature 24 ( 71.500 ) = 71.500 deg. F temperature 25 ( 71.890 ) = 71.890 deg. F temperature 26 ( 70.300 ) = 70.300 deg. F dewpoint 1 ( 70.630 ) = 70.630 deg. F , 0.3708 psia dewpoint 2 ( 70.470 ) = 70.470 deg. F , 0.3688 psia dewpoint 3 ( 70.930 ) = 70.930 deg. F , 0.3746 psia dewpoint 4 ( 70.310 ) = 70.310 deg. F, 0.3668 psia dewpoint 21 ( 60.230 ) = 60.230 deg. F , 0.2582 psia  !

dewpoint 22 ( 60.960 ) = 60.960 deg. F, 0.2650 psia i

pressure 1 ( 26.5998 ) = = 26.5998 psia  !

pressure 2 ( 26.6033 ) 26.6033 psia l 1

weighted averages, volume and air mass j temperature = 75.39116 deg. F pressure = 26.60040 psia l vapor pressure = 0.35205 psia j volume = 1670000 cu. ft.

dry air mass = 221127.65 lbm

• o data set 18 time = 1845 date = 1120 sensor raw data value temperature 1( 76.510 ) = 76.510 deg. F temperature 2( 76.710 ) = 76.710 deg. F temperature 3( 76.690 ) = 76.690 deg. F temperature 4( 76.830 ) = 76.830 deg. F temperature 5( 75.850 ) = 75.850 deg. F temperature 6( 76.050 ) = 76.050 deg. F temperature 7 ( 76.010 ) = 76.010 deg. F temperature 8 ( 76.610 ) = 76.610 deg. F temperature 9 ( 76.590 ) = 76.590 deg. F temperature 10 ( 75.460 ) = 75.460 deg. F temperature 11 ( 76.640 ) = 76.640 deg. F temperature 12 ( 76.450 ) = 76.450 deg. F temperature 13 ( 77.280 ) = 77.280 deg. F temperature 14 ( 63.120 ) = 63.120 deg. F temperature 15 ( 76.740 ) = 76.740 deg. F temperature 16 ( 74.320 ) = 74.320 deg. F temperature 17 ( 74.270 ) = 74.270 deg. F temperature 18 ( 73.480 ) = 73.480 deg. F temperature 21 ( 82.440 ) = 82.440 deg. F ,

temperature 22 ( 77.770 ) = 77.770 deg. F temperature 23 ( 74.630 ) = 74.630 deg. F temperature 24 ( 71.600 ) = 71.600 deg. F temperature 25 ( 71.890 ) = 71.890 deg. F temperature 26 ( 70.380 ) = 70.380 deg. F dewpoint 1 ( 70.710 ) = 70.710 deg. F , 0.3718 psia dewpoint 2 ( 70.460 ) = 70.460 deg. F, 0.3687 psia dewpoint 3 ( 70.920 ) = 70.920 deg. F , 0.3745 psia dewpoint _4 ( 70.320 ) = 70.320 deg. F , 0.3669 psia l dewpoint 21 ( 58.730 ) = 58.730 deg. F, 0.2448 psia l dewpoint 22 ( 61.060 ) = 61.060 deg. F , 0.2659 psia  !

pressure 1 ( 26.5991 ) = 26.5991 psia pressure 2 ( 26.6025 ) = 26.6025 psia weighted averages, volume and air mass i l

temperature = 75.38393 deg. F pressure = 26.59968 psia vapor pressure = 0.35242 psia  ;

volume = 1670000 cu. ft.

dry air mass = 221121.50 lbm l

l *

• e data set 19 time = 1900 date = 1120 e sensor raw data value temperature 1( 76.460 ) = 76.460 deg. F temperature 2. ( 76.620 ) = 76.620 deg. F temperature 3( 76.630 ) = 76.630 deg. F temperature 4' ( 76.820 ) = 76.820 deg. F temperature 5 ( 75.810 ) = 75.810 deg. F temperature 6( 76.020 ) = 76.020 deg. F temperature 7 ( 75.930 ) = 75.930 deg. F '

temperature 8( 76.550 ) = 76.550 deg. F temperature 9( 76.570 ) = 76.570 deg. F temperature 10 ( 75.410 ) _ = 75.410_dag. F temperature 11 ( 76.580 ) = 76.580 deg. F temperature 12 ( 76.460 ) = 76.460 deg. F temperature 13 ( 77.250 ) = 77.250 deg. F  !

temperature 14 ( 63.140 ) = 63.140 dag. F

. temperature 15 ( 76.730 ) = 76.730 deg. F temperature 16 ( 74.320 ) = 74.320 deg. F temperature 17 ( -74.260 ) = 74.260 deg. F temperature 18 ( 73.470 ) = 73.470 dog. F temperature 21 ( 82.450 ) = 82.450 deg. F ,

temperature 22 ( 77.840 ) = 77.840 deg. F temperature 23 ( 74.720 ) = 74.720 deg. F temperature 24 ( 71.580 ) = 71.580 deg. F temperature 25 ( 72.000 ) = 72.000 dag. F temperature 26 ( 70.480 ) = 70.480 deg. F dewpoint 1 ( 70.670 ) = 70.670 deg. F , 0.3713 psia dewpoint 2 ( 70.400 ) = 70.400 deg. F , 0.3679 psia dewpoint 3 ( 70.940 ) = 70.940 deg. F , 0.3747 psia dewpoint 4 ( 70.330 ) = 70.330 deg. F., 0.3670 psia dewpoint 21 ( 62.050 ) = 62.050 deg. F , 0.2754 psia dewpoint 22 ( 61.220 ) = 61.220 deg. F , 0.2675 psia pressure 1 ( 26.5985 ) == 26.5985 psia. l pressure 2 ( 26.6017 ) 26.6017 psia l l

veighted averages, volume and air mass temperature = 75.36480 dag. F pressure = 26.59905 psia vapor pressure = 0.35240 psia volume = 1670000 cu. ft.

dry air mass = 221124.23 lba

• a

' data set 20 i time = 1915 date = 1120 i

i sensor raw data value

) temperature- 1 ( 76.420 ) = 76.420 deg. F j temperature 2 ( 76.600 ) = 76.600 deg. F 4 temperature 3 ( 76.580 ) = 76.580 dag. F

! temperature 4 ( 76.760 ) = 76.760 deg. F i j temperature 5 ( 75.730 ) = 75.730 dag. F l j temperature 6 ( 75.980 ) = 75.980 deg. F j temperature 7 ( 75.870 ) = 75.870 deg. F temperature 8 ( 76.520 ) = 76.520 deg. F i temperature- 9 ( 76.480 ) = 76.480 deg. F temperature 10 ( 75.350 ) = 75.350 dag. F i

temperature 11 ( 76.580 ) = 76.580 deg. F

temperature 12 ( 76.420 ) = 76.420 deg. F

temperature 13 ( 77.220 ) = 77.220 deg..F temperature 14 ( 63.160 ) = 63.160 deg. F

-- temperature 15 ( 76.570 ) =- 76.570 deg. F

! _ temperature 16 ( 74.320 ) = 74.320 deg. F temperature 17 ( 74.270 ) = 74.270 deg. F temperature is ( 73.450 ) =. 73.450 deg. F 82.520 ) 82.520 deg. F

=

temperature 21 (

• temperature 22 ( 77.970 ) = 77.970 dag. F l temperature 23 ( 74.740 ) = 74.740 deg. F temperature 24 ( 71.660 ) = 71.660 deg. F temperature 25 ( 72.150 ) = 72.150.deg. F temperature 26 ( 70.560 ) = 70.560 deg. F dewpoint 1 ( 70.700 ) = 70.700 deg. F , 0.3717 psia

dewpoint 2' ( 70.450 ) = 70.450 dag. F , 0.3685 psia j dewpoint 3 ( 70.940 ) = 70.940 deg. F , 0.3747 psia 1 dewpoint 4 ( 70.330 ) =- 70.330 dag. F , 0.3670 psia i dewpoint 21 ( 62.120 ) = 62.120 deg. F , 0.2761 psia dewpoint 22 ( 61.380-) = 61.380 dag. F , 0.2690 psia i 26.5982 psia e pressure 1 ( 26.5982 ) =

a pressure 2 ( 26.6012 ) = 26.6012 psia I weighted averages, volume and air mass

~

temperature = 75.34417 deg. F pressure = 26.59871 psia 4

vapor pressure = 0.35293 psia volume = 1670000 cu. ft.

dry air mass = 221125.48 lba l I

J l 4 I i_.._________.__ _. . __ _ . _ _ ,_. _ _ . . _ _ , , , , ._

. ._. . . _ _ . . . . ~ . _ _ _ . _ _ , _ _ - __ _ . _ . . . _ _ _. - __ . _ _ .

i e ,

! data set 21 time = 1930 date = 1120 i

I, sensor raw data value i

temperature 1( 76.390 ) = 76.390 deg. F f 76.590 deg. F j temperature 2( 76.590 ) =

temperature 3 ( 76.560 ) = 76.560 dag. F

{

temperature 4 ( 76.730 ) = 76.730 deg. F i temperature -5 ( 75.710 ) = 75.710 dag. F j temperature 6( 75.960 ) = 75.960 deg. F j temperature 7 ( 75.860 ) = 75.860 deg. F

! temperature 8 ( 76.520 ) = 76.520 dag. F j temperature 9 ( 76.520 ) = 76.520 dag. F j temperature 10 ( 75.340 ) = 75.340 deg. F temperature 11 ( 76.590.) = 76.590 deg. F i

temperature 12 ( 76.430 ) = 76.430 deg. F temperature 13 ( 77.180 ) = 77.180 deg. F j temperature 14 ( 63.200 ) = 63.200 deg.~ F i temperature 15 ( 76.580 ) =

^

76.580 deg. F temperature 16 ( 74.350 ) = 74.350 deg. F temperature 17 ( 74.290 ) = 74.290 deg. F i temperature 18 ( 73.460 ) = 73.460 deg. F temperature 21 ( 82.580 ) = 82.580 deg. F

• j temperature 22 ( 78.060 ) = 78.060 deg. F

temperature 23 ( -74.820 ) = 74.820 deg. F temperature 24 ( 71.740 ) = 71.740 deg. F temperature 25 ( 72.150 ) = 72.150 dag. F j temperature 26 ( 70.660 ) = 70.660 deg. F j dewpoint 1 ( 70.630 ) = 70.630 deg. F , 0.3708 psia 4 dewpoint 2 ( 70.460 ) = 70.460 dag. F , 0.3687 psia j dewpoint 3 ( 70.910 ) = 70.910 deg. F , 0.3743 psia

dewpoint 4 ( 70.360 ) = 70.360 dag.'F , 0.3674 psia i dewpoint 21 ( 62.230 ) = 62.230 deg. F , 0.2772 psia dewpoint 22 ( 61.490 ) = 61.490 deg. F , 0.2700 psia pressure 1 ( 26.5980 ) = 26.5980 psia i pressure 2 ( 26.6012 ) = 26.6012 psia weighted averages, volume and air mass l

4 temperature = 75.35077 deg. F l

4 pressure = 26.59855 psia j vapor pressure = 0.35294 psia

, volume = 1670000 cu. ft. ,

j dry air mass = 221121.31 lba i

i 4

• e 4

data set 22 l

< time = 1945 date = 1120 i

l sensor raw data value temperature 1( 76.360 ) = 76.360 dag. F 1

, temperature 2( 76.540 ) = 76.540 deg. F temperature 3( 76.520 ) = 76.520 deg. F temperature 4( 76.680 ) = 76.680 deg. F f temperature 5( 75.660 ) = 75.660 deg. F temperature 6( 75.890 ) = 75.890 deg. F temperature 7( 75.830 ) = 75.830 deg. F temperature 8( 76.480 ) = 76.480 dag. F temperature 9( 76.470 ) = 76.470 deg. F temperature 10 ( 75.370 ) = 75.370 deg. F temperature 11 ( 76.580 ) = 76.580 deg. F temperature 12 ( 76.380 ) = 76.380 deg. F temperature 13 ( 77.130 ) = 77.130 deg. F temperature 14 ( 63.230 ) = 63.230 deg. F temperature 15 ( 76.530 ) = 76.530 deg. F temperature 16 ( 74.320 ) = 74.320 deg. F temperature 17 ( 74.270 ) = 74.270 dag. F temperature 18 ( 73.450 ) = 73.450 deg. F

. temperature 21 ( 82.540 ) = 82.540 dag. F

• temperature 22 ( 78.210 ) = 78.210 deg. F temperature 23 ( 74.880 ) = 74.880 deg. F 4

temperature 24 ( 71.840 ) = 71.840 deg. F l

temperature 25 ( 72.290 ) = 72.290 deg. F j temperature 26 ( 70.780 ) = 70.780 deg. F dewpoint 1 ( 70.640 ) = 70.640 dag. F, 0.3709 psia dewpoint 2 ( 70.480 ) = 70.480 deg. F , 0.3689 psia dewpoint 3 ( 70.910 ) = 70.910 deg. F, 0.3743 psia dewpoint 4 ( 70.370 ) = 70.370 deg. F , 0.3675 psia dewpoint 21 ( 62.320 ) = 62.320 deg. F, 0.2781 psia dewpoint 22 ( 61.630 ) = 61.630 deg. F , 0.2714 psia 3

pressure 1 ( 26.5974 ) = 26.5974 psia 4

pressure 2 ( 26.6009 ) = 26.6009 psia weighted averages, volume and air mass temperature = 75.34054 deg. F pressure = 26.59800 psia vapor pressure = 0.35329 psia volume = 1670000 cu. ft.

' dry air mass = 221117.96 lbm 1

4

=

i . )

< data set 23 l

time = 2000 date = 1120 sensor raw data value temperature 1( 76.340 ) = 76.340 deg. F temperature 2( 76.510 ) = 76.510 deg. F temperature 3( 76.520 ) = 76.520 deg. F temperature 4( 76.660 ) = 76.660 deg. F temperature 5( 75.650 ) = 75.650 deg. F temperature 6 ( 75.880 ) = 75.880 deg. F temperature 7 ( 75.770 ) = 75.770 deg. F temperature 8( 76.440 ) = 76.440 deg. F temperature 9 ( 76.420 ) = 76.420 dag. F temperature 10 ( 75.330 }- = 75.330 deg. F temperature 11 ( 76.600 ) = 76.600 deg. F temperature 12 ( 76.340 ) = 76.340 deg. F temperature 13 ( 77.090 ) = 77.090 deg. F temperature 14 ( 63.260 ) = 63.260 deg. F temperature 15 ( 76.510 ) = 76.510 deg. F temperature 16 ( 74.290 ) = 74.290 deg. F temperature 17 ( 74.240 ) = 74.240 dag. F temperature 18 ( 73.440 ) = 73.440 deg. F temperature 21 ( 82.640 ) = 82.640 deg. F temperature 22 ( 78.340 ) = 78.340 deg. F .

temperature 23 ( 74.960 ) = 74.960 deg. F temperature 24 ( 71.930 ) = 71.930 deg. F temperature 25 ( 72.370 ) = 72.370 deg. F temperature 26 ( 70.850 ) = 70.850 deg. F dewpoint 1 ( 70.660 ) = 70.660 deg. F , 0.3712 psia dewpoint 2 ( 70.510 ) = 70.510 deg. F , 0.3693 psia dewpoint 3 ( 70.880 ) = 70.880 deg. F , 0.3740 psia dewpoint 4 ( 70.380 ) = 70.380 deg. F , 0.3677 psia dewpoint 21 ( 62.450 ) = 62.450 deg. F , 0.2793 psia dewpoint 22 ( 61.750 ) = 61.750 deg. F , 0.2725 psia pressure 1 ( 26.5968 ) == 26.5968 psia pressure 2 ( 26.6002 ) 26.6002 psia weighted averages, volume and air mass temperature = 75.33797 deg. F pressure = 26.59738 psia vapor pressure = 0.35362 psia volume = 1670000 cu. ft.

dry air mass = 221111.02 lbm I

a .

data set 24 time = 2015 date = 1120 sensor raw data value temperature 1 ( 76.320 ) = 76.320 deg. F temperature 2 ( 76.460 ) = 76.460 deg. F temperature 3 ( 76.480 ) = 76.480 deg. F temperature 4 ( 76.700 ) = 76.700 deg. F temperature 5 ( 75.660 ) = 75.660 deg. F temperature 6 ( -75.880 ) = 75.880 75.750 deg.

deg.

F F

temperature 7 ( 75.750 ) =

76.430 deg. F temperature 8 ( 76.430 ) = ,

temperature 9 ( 76.400 ) = 76.400 75.300 dag.

deg.

F F

temperature 10 ( 75.300 ) =

temperature 11 ( 76.550 ) = 76.550 deg. F temperature 12 ( 76.320 ) = 76.320 dag. F temperature 13,( 77.070 ) = 77.070 deg. F temperature 14 ( 63.300 ) = 63.300 deg. F temperature 15 ( 76.570 ) = 76.570 deg. F temperature 16 ( 74.310 ) = 74.310 deg. F temperature 17 ( 74.220 ) = 74.220 deg. F ,

temperature 18 ( 73.430 ) = 73.430 deg. F temperature 21 ( 82.630 ) = 82.630 deg. F .

temperature 22 ( 78.440 ) = 78.440 dag. F temperature 23 ( 74.990 ) = 74.990 deg. F temperature 24 ( 72.040 ) = 72.040 dag. F temperature 25 ( 72.520 ) = 72.520 deg. F temperature 26 ( 70.910 ) = 70.910 deg. . F dewpoint 1 ( 70.640 ) = 70.640'deg. F , 0.3709 psia dewpoint 2 ( 70.480 ) = 70.480 deg. F , 0.3689 psia dewpoint 3 ( 70.910 ) = 70.910 dag. F , 0.3743 psia dewpoint 4 ( 70.400 ) = 70.400 deg. F , 0.3679 psia dowpoint 21 ( 62.520 ) = 62.520 deg. F , 0.2800 psia dewpoint 22 ( 61.890 ) = 61.890 deg. F , 0.2739 psia pressure 1 ( 26.5963 ) == 26.5963 psia pressure 2 ( 26.5997 ) 26.5997 psia weighted averages, volume and air mass temperature = 75.34680 deg..F pressure = 26.59688 psia vapor pressure = 0.35377 psia volume = 1670000 cu. ft.

dry air mass = 221101.85 lbm I

l

I data set 25 time = 2030 date = 1120 sensor raw data value temperature 1( 76.300 ) = 76.300 deg. F temperature 2 ( 76.480 ) = 76.480 deg. F temperature 3( 76.500 ) = 76.500 deg. F temperature 4( 76.600 ) = 76.600 deg. F temperature 5( 75.660 ) = 75.660 deg. F temperature 6( 75.880 ) = 75.880 deg. F temperature 7( 75.750 ) = 75.750 deg. F temperature 8( 76.470 ) = 76.470 deg. F temperature 9( 76.350 ) = 76.350 deg. F temperature 10 ( 75.320 ) = 75.320 deg. F temperature 11 ( 76.570 ) = 76.570 deg. F temperature 12 ( 76.340 ) = 76.340 deg. F temperature 13 ( 77.020 ) = 77.020 deg. F temperature 14 ( 63.320 ) = 63.320 deg. F temperature 15 ( 76.530 ) = 76.530 deg. F temperature 16 ( 74.280 ) = 74.280 deg. F temperature 17 ( 74.230 ) = 74.230 deg. F temperature 18 ( 73.430 ) = 73.430 deg. F temperature 21 ( 82.690 ) = 82.690 dag. F temperature 22 ( 78.540 ) = 78.540 dag. F temperature 23 ( 75.040 ) = 75.040 deg. F temperature 24 ( 71.990 ) = 71.990 deg. F temperature 25 ( 72.530 ) = 72.530 deg. F temperature 26 ( 70.970 ) = 70.970 deg. F dewpoint 1 ( 70.660 ) = 70.660 deg. F , 0.3712 psia dewpoint 2 ( 70.510 ) = 70.510 deg. F, 0.3693 psia dewpoint 3 ( 70.900 ) = 70.900 deg. F, 0.3742 psia dewpoint 4 ( 70.400 ) = 70.400 deg. F, 0.3679 psia dewpoint 21 ( 62.630 ) = 62.630 deg. F, 0.2811 psia ,

dewpoint 22 ( 62.000 ) = 62.000 deg. F, 0.2749 psia pressure 1 ( 26.5961 ) = 26.5961 psia pressure 2 ( 26.5996 ) = 26.5996 psia weighted averages, volume and air mass l

temperature = 75.34541 deg. F pressure = 26.59670 psia vapor pressure = 0.35411 psia volume .= 1670000 cu. ft.

dry air mass = 221098.08 lbm

data set 26 time = 2045 date = 1120 sensor raw data value temperature 1 ( 76.290 ) = 76.290 deg. F temperature 2 ( 76.490 ) = 76.490 deg. F temperature 3 ( 76.440 ) = 76.440 deg. F temperature 4 ( 76.620 ) = 76.620 75.660 deg.

deg.

F F

temperature 5 ( 75.660 ) =

75.870 deg. F temperature 6 ( 75.870 ) =

temperature 7 ( 75.760 ) = 75.760 deg. F temperature 8 ( 76.430 ) = 76.430 deg. F temperature 9 ( 76.300 ) = 76.300 dag. F temperature 10 ( 75.330 ) = 75.330 deg. F temperature 11 ( 76.630 ) = 76.630 deg. F temperature 12 ( 76.360 ) = 76.360 deg. F temperature 13 ( 76.980 ) = 76.980 deg. F temperature 14 ( 63.360 ) = 63.360 deg. F temperature 15 ( 76.530 ) = 76.530 deg. F temperature 16 ( 74.270 ) = 74.270 deg. F temperature 17 ( 74.230 ) = 74.230 dag. F temperature 18 ( 73.430 ) = 73.430 deg. F temperature 21 ( 82.630 ) = 82.630 deg. F i

temperature 22 ( 78.630 ) = 78.630 deg. F temperature 23 ( 75.130 ) = 75.130 deg. F temperature 24 ( 72.070 ) = 72.070 deg. F temperature 25 ( 72.630 ) = 72.630 deg. F temperature 26 ( 71.040 ) = 71.040 deg. F dewpoint 1 ( 70.650 ) = 70.650 deg. F, 0.3710 psia dewpoint 2 ( 70.500 ) = 70.500 deg. F , 0.3692 psia dewpoint 3 ( 70.910 ) = 70.910 dag. F , 0.3743 psia dewpoint 4 ( 70.430 ) = 70.430 deg. F, 0.3683 psia dewpoint 21 ( 62.740 ) = 62.740 deg. F , 0.2822 psia dewpoint 22 ( 62.100 ) = 62.100 deg. F , 0.2759 psia pressure 1 ( 26.5963 ) == 26.5963 psia pressure 2 ( 26.5997 ) 26.6997 psia weighted averages, volume and air mass temperature = 75.35567 deg. F pressure = 26.59688 psia vapor pressure = 0.35428 psia volume = 1670000 cu. ft, dry air mass = 221093.89 lbm

data set 27 time = 2100 date = 1120 sensor raw data value temperature 1( 76.270 ) = 76.270 deg. F temperature 2( 76.440 ) = 76.440 deg. F temperature 3 ( 76.450 ) = 76.450 deg. F temperature 4 ( 76 570 ) = 76.570 deg. F temperature 5( 75.620 ) = 75.620 deg. F temperature 6( 75.860 ) = 75.860 deg. F temperature 7( 75.740 ) = 75.740 deg. F temperature 8 ( 76.410 ) = 76.410 deg. F temperature 9( 76.330 ) = 76.330 deg. F temperature 10 ( 75.360 ) = 75.360 deg. F temperature 11 ( 76.640 ) = To.640 deg. F temperature 12 ( 76.320 ) = 76.320 deg. F temperature 13 ( 76.990 ) = 76.590 deg. F temperature 14 ( 63.390 ) = 63.390 deg. F temperature 15 ( 76.450 ) = 76.450 deg. F temperature 16 ( 74.320 ) = 74.320 deg. F temperature 17 ( 74.240 ) = 74.240 deg. F temperature 18 ( 73.410 ) = 73.410 deg. F temperature 21 ( 82.690 ) = 82.690 deg. F  ;

78.760 )

temperature 22 ( = 78.760 deg. F temperature 23 ( 75.190 ) = 75.190 deg. F temperature 24 ( 72.180 ) = 72.180 deg. F temperature 25 ( 72.630 ) = 72.630 deg. F temperature 26 ( 71.140 ) = 71.140 deg. F dewpoint 1 ( 70.730 ) = 70.730 deg. F , 0.3721 psia devpoint 2 ( 70.420 ) = 70.420 deg. F , 0.3682 psia devpoint 3 ( 70.920 ) = 70.920 deg. F, 0.3745 psia dewpoint 4 ( 70.450 ) = 70.450 deg. F , 0.3685 psia dewpoint 21 ( 62.830 ) = 62.830 deg. F , 0.2831 psia dewpoint 22 ( 62.210 ) = 62.210 deg. F , 0.2770 psia pressure 1 ( 26.5965 ) = 26.5965 psia pressure 2 ( 26.6000 ) = 26.6000 psia weighted averages, volume and air mass temperature = 75.35690 deg. F pressure = 26.59710 psia vapor pressure = 0.35448 psia volume = 1670000 cu. ft.

dry air mass = 221093.53 lbm )

1 l

l l

i data set 28

! time = 2.15 date = 1120 sensor raw data value

~

temperature 1( 76.250 ) = '76.250 deg. F temperature 2( 76.450 ) = 76.450 deg. F

temperature 3( 76.480 ) = 76.480 deg. F temperature 4( 76.540 ) = 76.540 deg. F temperature 5 ( 75.640 ) = 75.640 deg. F temperature 6( 75.800 ) = 75.800 deg. F temperature 7 ( 75.710 ) = 75.710 deg. F

.t temperature 8 ( 76.430 ) = 76.430 dag. F temperature 9 ( 76.280 ) = 76.280 deg. F temperature 10 ( 75.340 ) = 75.340 deg. F

temperature 11 ( 76.660 ) = 76.660 deg. F temperature 12 ( 76.310 ) = 76.310 deg. F temperature 13 ( 76.950 ) = 76.950 deg. F temperature 14 ( 63.430 ) = 63.430 deg. F temperature 15 ( 76.420 ) = 76.420 deg. F temperature 16 ( 74.300 ) = 74.300 deg. F temperature 17 ( 74.230 ) = 74.230 deg. F temperature 18 ( 73.420 ) = 73.420 deg. F temperature 21 ( 82.730 ) = 82.730 deg. F  ;

temperature 22 ( 78.910 ) = 78.910 deg. F temperature 23 ( 75.280 ) = 75.280 deg. F temperature 24 ( 72.280 ) = 72.280 deg. F

. temperature 25 ( 72.750 ) = 72.750 deg. F 71.220 )

temperature 26 ( = 71.220 deg. F

$ dewpoint 1 ( 70.720 ) = 70.720 deg. F, 0.3719 psia dewpoint 2 ( 70.500 ) = 70.500 deg. F , 0.3692 psia dewpoint 3 ( 70.940 ) = 70.940 deg. F , 0.3747 psia i dewpoint 4 ( 70.450 ) = 70.450 deg. F , 0.3685 psia dewpoint 21 ( . 64.200 ) = 64.200 deg. F, 0.2970 psia dewpoint 22 ( 62.310 ) = 62.310 deg. F , 0.2780 psia pressure 1 ( 26.5965 ) = 26.5965 psia pressure 2 ( 26.6001 ) = 26.6001 psia weighted averages, volume and air mass temperature = 75.36850 deg. F pressure = 26.59711 psia vapor pressure = 0.35494 psia volume = 1670000 cu. ft.

. dry air mass = 221085.00 lbm 4

l

R 4 i i

• s j

! l

j. data set 29 4

I time = 2130 date = 1120 ,

I.

sensor raw data value 4

{ temperature 1( 76.220 ) = 76.220 deg. F

! temperature 2 ( 75.430 ) = 76.430 deg. F  ;

l temperature 3( 76.400 ) = 76.400 deg. F 4( 76.510 ) 76.510 deg. F

~

=

temperature temperature 5 ( 75.610 ) = 75.610 deg. F

]i temperature 6( 75.810 ) = 75.810 deg. F 3 temperature 7( 75.730 ) = 75.730 deg. F i- temperature 8( 76.420 ) = 76.420 deg. F temperature 9( 76.280 ) = 76.280 deg. F i temperature 10.( 75.330 ) = 75.330 deg. F

temperature 11 ( 76.580 ) = 76.580 deg. F

! temperature 12 ( 76.290 ) = 76.290 deg..F l temperature 13 ( 76.920 ) = 76.920 deg. F l' temperature 14.( 63.460 ) = 63.460 deg. F j temperature 15 ( 76.460 ) = 76.460 deg. F temperature 16 ( 74.230 ) = 74.230 deg. F i temperature 17 ( 74.210 ) = 74.210 dag. F i

! temperature 18 ( 73.410 ) = 73.410 deg. F j temperature 21 ( 82.710_). = 82.710 deg. F  ;

79.010 )- 79.010 deg. F temperature 22 ( =

i l temperature 23 ( 75.350 ) = 75.350 deg. F i temperature 24 ( 72.390 ) =~ -72.390 deg. F

{ temperature 25 ( 72.870 ) = 72.870 deg. F

.I temperature 26 ( 71.320 ) = 71.320 deg. F .

I j dewpoint 1 ( 70.700.) _ = 70.700 deg. F , 0.3717 psia i dewpoint 2 ( 70.500 ) = 70.500 deg. F , 0.3692 psia

] dewpoint 3 ( 70.960 ) = 70.960 deg. F , 0.3750 psia dewpoint 4 70.400-) 70.400 deg. F, 0.3679 psia

~

=

(

dewpoint 21 ( 63.000 ) = 63.000 deg. F , 0.2848 psia

dewpoint 22 ( 62.400 ) = 62.400.deg. F , 0.2788 psia ,

pressure 1 ( 26.5952 ) == 26 5952 psia j pressure 2 ( 26.5987 ) 26.5987 psia  ;

I i weighted averages, volume and air mass ,

j temperature = 75.36750 deg. F j pressure = 26.59580 psia i vapor pressure = 0.35497 psia volume = 1670000 cu. ft.

i[ dry air mass = 221074'.08 lba L

i l

1 4

e .

data set 30 time = 2145 date = 1120 sensor raw data value temperature 1( 76.230 ) = 76.230 deg. F temperature 2 ( 76.410 ) = 76.410 deg. F temperature 3 ( 76.400 ) = 76.400 deg. F temperature 4( 76.520 ) = 76.520 deg. F temperature 5 ( _75.570 ) = 75.570 deg. F temperature 6 ( 75.790 ) = 75.790 deg. F temperature 7 ( 75.670 ) = 75.670 dag. F temperature 8 ( 76.380 ) = 76.380 deg. F temperature 9 ( 76.300 ) = 76.300 dag. F temperature 10 ( 75.320 ) = 75.320 deg. F temperature 11 ( 76.570 ) = 76.570 deg. F temperature 12 ( 76.240 ) = 76.240 deg. F temperature 13 ( 76.890 ) = 76.890 deg. F temperature 14 ( 63.500 ) = 63.500 deg. F temperature 15 ( 76.410 ) = 76.410 deg. F temperature 16 ( 74.230 ) = 74.230 deg. F temperature 17 ( 74.220 ) = 74.220 deg. F temperature 18 ( 73.440 ) = 73.440 dag. F temperature 21 ( 82.740 ) = 82.740 deg. F '

temperature 22 ( 79.040 ) = 79.040 deg. F temperature 23 ( 75.420 ) = 75.420 deg. F temperature 24 ( 72.420 ) = 72.420 deg. F temperature 25 ( 72.810 ) = 72.810 deg. F temperature 26 ( 71.300 ) = 71.300 dag. F dewpoint 1 ( 70.690 ) = 70.690 ag. F , 0.3716 psia dewpoint 2 ( 70.520 ) = 70.52' .g . F, 0.3694 psia dewpoint 3 ( 70.920 ) = 70.920 aeg. F , 0.3745 psia dewpoint 4 ( 70.450 ) = 70.450 deg. F , 0.3685 psia dewpoint 21 ( 63.090 ) = 63.090 dag. F , 0.2857 psia dewpoint 22 ( 62.510 ) = 62.510 deg. F , 0.2799 psia pressure 1 ( 26.5939 ) = 26.5939 psia pressure 2 ( 26.5975 ) = 26.5975 psia weighted averages, volume and air mass temperature = 75.35963 deg. F pressure = 26.59451 psia i vapor pressure = 0.35522 psia volume = 1670000 cu. ft.

dry air mass = 221064.40 lbm l

f data set 31 time = 2200 date = 1120 sensor raw data value temperature 1( 76.200 ) = 76.200 deg. F temperature 2( 76.390 ) = 76.390 deg. F temperature 3( 76.370 ) = 76.370 deg. F temperature 4 ( 76.480 ) = 76.480 deg. F temperature 5 ( 75.550 ) = 75.550 deg. F temperature 6 ( 75.780 ) = 75.780 deg. F temperature 7 ( 75.690 ) = 75.690 deg. F temperature 8 ( 76.360 ) = 76.360 deg. F temperature 9 ( 76.290 ) = 76.290 deg. F temperature 10 ( 75.330 ) = 75.330 deg. F temperature 11 ( 76.530 ) = 76.530 deg. F temperature 12 ( 76.240 ) = 76.240 deg. F temperature 13 ( 76.890 ) = 76.890 deg. F temperature 14 ( 63.520 ) = 63.520 deg. F temperature 15 ( 76.370 ) = 76.370 deg. F temperature 16 ( 74.230 ) = 74.230 deg. F temperature 17 ( 74.220 ) = 74.220 deg. F temperature 18 ( 73.450 ) = 73.450 deg. F temperature 21-( 82.780 ) = 82.780 deg. F ,

temperature 22 ( 79.050 ) = 79.050 dag. F temperature 23 ( 75.430 ) = 75.430 deg. F temperature 24 ( 72.340 ) = 72.340 dag. F temperature 25 ( 72.890 ) = 72.890 deg. F temperature 26 ( 71.290 ) = 71.290 deg. F dewpoint 1 ( 70.730 ) = 70.730 dag. F , 0.3721 psia dewpoint 2 ( 70.500 ) = 70.500 deg. F , 0.3692 psia dewpoint 3 ( 70.970 ) = 70.970'deg. F , 0.3751 psia dewpoint 4 ( 70.460 ) = 70.460_deg. F , 0.3687 psia.

dewpoint 21 ( 63.170 ) = 63.170 deg. F, 0.2865 psia dewpoint 22 ( 62.590 ) = 62.590 deg. F , 0.2807 psia pressure 1 ( 26.5940 ) = 26.5940 psia  ;

( 26.5972 )

pressure 2 = 26.5972 psia weighted averages, volume and air mass temperature = 75.34837 deg. F pressure = 26.59455 psia ,

vapor pressure = 0.35552 psia  !

volume = 1670000 cu. ft.

dry air mass = 221066.82 lbm l

l. - -

. .. )

data set 32

~ '

time = 2215 date.= 1120 sensor raw data value temperature 1( 76.180;) = 76.180 deg. F-temperature 2. ( 76.370 ) = 76.370 deg. F temperature 3 ( 76.320 ) = 76.320 dag. F temperature 4 ( 76.500 ) = 76.500 deg. F-

, ~ temperature 5( 75.520 ) = 75.520 deg. F temperature 6( 75.750 ) = 75.750 deg. F

temperature 7 75.650-)

(- = 75.650 deg. F i

temperature 8 ( 76.340 ) = 76.340 deg. F temperature 9( 76.310 ) = 76.310 deg. F temperature 10 ( 75.270 ) = 75.270 deg. F temperature 11 ( 76.530 ) = 76.530 deg. F temperature 12 ( 76.180 ) = 76.180 deg. F temperature 13 ( 76.890 ) = 76.890 dag. F temperature 14 ( 63.550_.) = 63.550 deg. F temperature 15'( 76.410 ) = 76.410 dag. F temperature 15 ( 74.280 ) = 74.280 dag. F ,

temperature 17 ( 74.230 ) = 74.230 deg. F '

temperature 18 ( 73.440 ) =- 73.440 deg. F

-temperature 21 (- 82.780 )- = 82.780_deg. F  ;

temperature 22 ( 79.060 )

= 79.060 deg. F temperature 23 ( 75.510 ) = 75.510 deg. .F temperature 24 ( 72.420 ) = 72.420 deg. F temperature 25 ( 72.890 ) = 72.890 deg.-.F temperature 26 ( 71.320 ) = 71.320'deg.- F-dewpoint 1 ( 70.730 ) = 70.730 dag. F , 0.3721 psia  !

dewpoint 2 ( 70.530 ) = 70.530 deg. F ,- 0.3695 psia dewpoint 3 ( 70.970 ) = 70.970 deg. F , 0.3751 psia dewpoint 4 ( 70.530 ) = 70.530 deg. F , 0.3695 psia dewpoint 21 ( 63.230 ) = 63.230 deg. F, 0.2871 pria dewpoint 22 ( 62.660 ) = 62.660 deg. F, 0.2814 psia i pressure 1 ( 26.5937 ) = 26.5937 psia pressure 2 ( 26.5973 ) = 26.5973 psia weighted averages, volume and air mass temperature = 75.34451 deg. F j pressure = 26.59431 psia i vapor pressure = 0.35588 psia volume = 1670000 cu. ft.

dry air mass = 221063.40 lba

4 data set 33 i- time = 2230 date = 1120 l

sensor raw data value j

temperature 1( 76.160 ) = 76.160 deg. F

temperature 2 ( 76.340 ) = 76.340 deg. F J temperature 3 ( .76.340 ) = 76.340.deg. F temperature 4-( 76.500 ) = 76.500 deg. F l temperature 5( 75.500 ) = 75.500 deg. F

? temperature 6( 75.720 ) = 75.720 deg. F

temperature 7( 75.640 ) = 75.G40 deg. F temperature 8( 76.390 ) = 76.390 deg. F l temperature 9( 76.340 ) = 76.340 deg. F i temperature 10 ( 75.320 ) = 75.320 dag. F l

} temperature 11 ( 76.560 ) = 76.560 dag. F,  :

temperature 12 ( 76.240 ) = 76.240 deg. F 3

temperature 13 ( 76.900 ) = 76.900 deg. F d

temperature 14 ( 63.600 ) = 63.600 dag. F temperature 15 ( 76.350 ) = 76.350 dag. F -

I temperature 16 ( 74.320 ) = 74.320 deg.-F i temperature 17 ( 74.260 ) = 74.260 deg. F i temperature 18 ( 73.450 ) = 73.450 deg. F j temperature 21 ( 82.800 ) = 82.800 deg. F ,

temperature 22 ( 79.090 ) = 79.090 deg. F  ?

temperature 23 ( 75.560-) = 75.560 dag. F 4

temperature 24 ( 72.500 ) = 72.500 deg. F

temperature 25 ( 72.940 ) = 72.940 deg. F

]

temperature 26 ( 71.380 ) = 71.380 deg. F

dewpoint 1 ( 70.740 ) = 70.740 dag. F, 0.3722 psia I dewpoint 2 ( 70.530 ) = 70.530 deg. F , 0.3695 psia i dewpoint 3 ( 70.960 ) = 70.960 deg. F , 0.3750 psia dewpoint 4 ( 70.580 ) = 70.580 deg. F, 0.3702 psia

dewpoint 21 ( 63.300 ) = 63.300 dag. F, 0.2878 psia

dewpoint 22 ( 62.750 ) = '62.750 deg. F, 0.2823 psia

l. pressure 1 ( 26.5938 ) = 26.5938 psia pressure -2 ( 26.5972 ) = 26.5972 psia i

weighted averages, volume and air mass temperature = 75.35703 deg. F j

~

pressure = 26.59438 psia vapor pressure = ~0.35615 psia )

volume = 1670000 cu. ft, dry air mass = 221056.54 lbm i

1 4

i i  !

i 1

i l

_ _ - _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ . _ _ _ _ _ _ _ _ _ _ _ ~

I data set 34 l

time = 2245 date = 1120 sensor raw data value j temperature 1( 76.150 ) = 76.150 deg. F l 76.300 )

temperature 2 ( = 76.300 deg. F temperature 3 ( 76.260 ) = 76.260 deg. F temperature 4 ( 76.430 ) = 76.430 deg. F temperature 5 ( 75.430 ) = 75.430 deg. F  ;

temperature 6( 75.710 ) = 75.710 deg. F l temperature 7 ( 75.610 ) = 75.610 deg. F l temperature 8 ( 76.310 ) = 76.310 deg. F I temperature 9 ( 76.310 ) = 76.310 deg. F temperature 10 ( 75.260 ) = 75.260 deg. F temperature 11 ( 76.530 ) = 76.530 deg. F temperature 12 ( 76.210 ) = 76.210 deg. F temperature 13 ( 76.890 ) = 76.890 deg. F temperature 14 ( 63.610 ) = 63.610 deg. F temperature 15 ( 76.300 ) = 76.300 deg. F temperature 16 ( 74.300 ) = 74.300 deg. F temperature 17 ( 74.240 ) = 74.240 deg. F temperature 18 ( 73.430 ) = 73.430 dag. F temperature 21 ( 82.810 ) = 82.810 deg. F  ;

79.200 ) 79.200 deg. F temperature 22 ( =

temperature 23 ( 75.640 ) = 75.640 deg. F temperature 24 ( 72.610 ) = 72.610 deg. F temperature 25 ( 73.120 ) = 73.120 deg. F temperature 26 ( 71.500 ) = 71.500 deg. F dewpoint 1 ( 70.750 ) = 70.750 deg. F, 0.3723 psia dewpoint 2 ( 70.580 ) = 70.580 deg. F, 0.3702 psia dewpoint 3 ( 70.980 ) = 70.980 deg. F , 0.3752 psia dewpoint 4 ( 70.630 ) = 70.630 deg. F, 0.3708 psia dewpoint 21 ( 63.400 ) = 63.400 deg. F, 0.2888 psia dewpoint 22 ( 62.860 ) = 62.860 deg. F, 0.2834 psia pressure 1 ( 26.5930 ) = 26.5930 psia pressure 2 ( 26.5964 ) = 26.5964 psia weighted averages, volume and air mass temperature = 75.34347 deg. F pressure = 26.59358 psia vapor pressure = 0.35668 psia volume = 1670000 cu. ft.

dry air mass = 221050.94 lbm l I

l

• +

data set 35 time = 2300 date = 1120 sensor raw data value temperature 1 ( 76.110 ) = 76.110 deg. F temperature 2 ( 76.280 ) = 76.280 deg. F temperature 3 ( 76.240-) = 76.240 deg. F temperature 4( 76.420 ) = 76.420 deg. F temperature 5 ( 75.370 ) = 75.370 deg. F temperature 6( 75.660 ) = 75.660 deg. F temperature 7( 75.580 ) = 75.580 deg. F temperature 8( 76.310 ) = 76.310 dag. F temperature 9( 76.330 ) = 76.330 deg. F temperature 10 ( 75.260 ) = 75.260 dag. F temperature 11 ( 76.530 ) = 76.530 deg. F temperature 12 ( 76.220 ) = 76.220 deg. F temperature 13 ( 76.900 ) = 76.900 deg. F temperature 14 ( 63.650 ) = 63.650 deg. F temperature 15 ( 76.320 ) = 76.320 dag. F temperature 16 ( 74.340 ) = 74.340 deg. F temperature 17 ( 74.260 ) = 74.260 deg. F temperature 18 ( 73.420 ) = 73.420 deg. F tamperature 21 ( 82.830 ) = 82.830 deg. F 79.180 ) 79.180 deg. F '

=

temperature 22 (

temperature 23 ( 75.660 ) = 75.660 deg. F temperature 24 ( 72.640 ) = 72.640 deg. F temperature 25 ( 73.000 ) = 73.000 dag. F temperature 26 ( 71.500 ) = 71.500 deg. F dewpoint 1 ( 70.740 ) = 70.740 deg. F , 0.3722 psia dewpoint 2 ( 70.530 ) = 70.530 deg. F , 0.3695 psia dewpoint 3 ( 71.020 ) = 71.020 deg. F , 0.3757 psia dewpoint 4 ( 70.660 ) = 70.660 deg. F , 0.3712 psia dewpoint 21 ( 63.490 ) = 63.490 deg. F , 0.2897 psia dewpoint 22 ( 62.880 ) = 62.880 deg. F , 0.2836 psia pressure 1 ( 26.5922 ) = 26.5922 psia pressure 2 ( 26.5959 ) = 26.5959 psia weighted averages, volume and air mass temperature = 75.33031 deg. F pressure = 26.59283 psia vapor pressure = 0.35664 psia volume = 1670000 cu. ft.

dry air mass = 221050.42 lbm

• +

data set 36 time = 2315 date = 1120 sensor raw data value temperature 1( 76.120 ) = 76.120.deg. F temperature 2-( 76.290-) = 76.290 deg. F temperature 3 ( 76.240 ) = 76.240 deg. F temperature 4 ( 76.460 ) = 76.460 deg. .F temperature 5 (- 75'.360 ) = 75.360 deg. F temperature 6( 75.660 ) = 75.660 dag. F temperature 7( 75.600 ) =' 75.600 deg. F

- temperature 8 ( 76.350 ) = 76.350 deg. F temperature 9 ( 76.350 ) = 76.350 dag. F temperature 10 ( 75.240 ) = 75.240 dag. F temperature.11 ( 76.540 ) = 76.540_deg. F temperature 12 ( 76.190 ) = 76.190 deg. F '

temperature 13 ( 76.930 ) = 76.930 dag. F temperature 14 ( 63.680 ) = 63.680 deg. F temperature 15 ( 76.300 ) = 76.300 deg. F temperature 16 ( 74.390 ) = 74.390 deg. F temperature 17 ( 74.270 ) = 74.270 dag. F temperature 18 ( 73.410 ) = 73.410 deg. F temperature 21 ( 82.820-) = 82.820 deg. F  ;

temperature 22 ( 79.200 ) = 79.200 dag. F temperature 23 ( 75.720 ) = 75.720 deg. F temperature 24 ( 72.710 ) = 72.710 deg. F temperature 25 ( 73.090 ) = 73.090 deg. F temperature 26 ( 71.520 ) = 71.520.deg. F dewpoint 1 ( 70.740 ) = 70.740 deg. F , 0.3722 psia dewpoint 2 ( 70.580 ) = 70.580 dag. F-, 0.3702 psia dewpoint 3 ( 71.030 ) = 71.030 deg. F , 0.3759 psia dewpoint 4 ( 70.690 ) = 70.690 deg. F , 0.,3716 psia dewpoint 21 ( 63.530 ) = 63.530 deg. F , 0.2901 psia ,

dewpoint 22- ( 63.000 ) = 63.000 deg. F . 0.2848 psia l l pressure 1 ( 26.5920 ) == 26.5920 psia l

]

pressure 2 ( 26.5956 ) 26.5956 psia weighted averages, volume and air mass

~

l 5 temperature = 75.34750 deg. F j pressure = 26.59262 psia j vapor pressure = 0.35710 psia volume = 1670000 cu. ft. 1 i dry air mass = 221037.58 lba j

4 4

4 i

i 1 .

I data set 37 i l time = 2330 date = 1120 l l sensor raw data value temperature 1( 76.110 ) = 76.110 deg. F j temperature 2( 76.250 ) = 76.250 deg. F

temperature 3( 76.220 ). = 76.220 dag. F

! temperature 4( 76.410 ) = 76.410 deg. F j temperature 5( 75.350 ) = 75.350 deg. F

[j temperature 6( 75.660 ) = 75.660 deg. F temperature 7 ( 75.570 ) = 75.570.deg. F

{ temperature 8 (- 76.410 ) = 76.410 deg. F i temperature 9( 76.330 ) = 76.330 deg. F

temperature 10 ( 75.250 ) = 75.250 deg. F temperature 11 ( 76.530 ) = 76.530 deg. F i temperature 12 ( 76.160 ) = 76.160 deg. F j temperature 13 ( 76.900 ) = 76.900 deg. F temperature 14 ( 63.700-) = 63.700 dag. F 1- temperature 15.( 76.260 ) = 76.260 dag. F temperature 16 ( 74.380 ) = 74.380 dag. F 3 temperature 17 ( 74.270 ) = 74.270 deg. F 4 temperature 18 ( 73.410 ) = 73.410 deg. F

, temperature 21 ( 82.800 ) = 82.800 deg. F  ;

79.230 )

temperature 22 ( = 79.230 deg. F 1 temperature 23-( 75.780 ) = 75.780 deg. F 1- temperature 24 ( 72.770 ) = 72.770 deg. F

! temperature 25 ( 73.110 ) = 73.110 dag. F i temperature 26 ( 71.570 ) = 71.570 deg. F dewpoint 1 ( 70.810 ) = 70.810 deg. F, 0.3731 psia i dewpoint 2 ( 70.570 ) = 70.570 deg. F , 0.3700 psia dewpoint 3 ( 71.040 ) = 71.040 deg. F , 0.3760 psia dewpoint 4 ( 70.710 ) = 70.710-deg. F, 0.3718 psia ,

dewpoint 21 ( 63.600 ) = 63.600 deg. F , 0.2909 psia-  ;

63.060 )

dewpoint 22 ( = 63.060 deg. F , 0.2854 psia

{ pressure 1 ( 26.5922 ) = 26.5922 psia i pressure 2 ( 26.5959 ) = 26.5959 psia weighted averages, volume and air mass i

{ temperature = 75.34210 deg. F 3 pressure = 26.59283 psia

. vapor pressure = 0.35744 psia l volume = 1670000 cu. ft.

] dry air mass = 221038.79 lba 4

I 1

I l

' e data set 38 3

time = 2345 date = 1120 J

sensor raw data value temperature 1( 76.110 ) = 76.110 dag. F temperature 2( 76.270 ) = 76.270 dag. F l- temperature 3 ( 76.220 ) = 76.220 deg. F

temperature 4 ( 76.390 ) = 76.300 deg. F

. temperature 5 ( 75.330 ) = 75.330 deg. F temperature 6 ( 75.650 ) = 75.650 dag. F temperature 7 ( 75.570 ) = 75.570 deg. F temperature 8 ( 76.410 ) = 76.410 deg. F

. temperature 9 ( 76.350 ) = 76.350 deg. F-temperature 10 ( 75.220 ) = 75.220 deg. F temperature 11 ( 76.530 ) = 76.530 deg. F j temperature 12 ( 76.170 ) = 76.170 dag. F

! temperature 13 (. 76.920 ) = 76.920 deg.-F i temperature 14 ( 63.720 ) = 63.720 deg. F temperature 15 ( 76.250 ) = 76.250 deg. F temperature 16 ( 74.370 ) = 74.370 deg. F temperature 17 ( 74.250 ) = 74.250 deg. F temperature 18 ( '73.380 ) = 73.380 dag. F 2

temperature 21 ( 82.750 ) = 82.750 deg. F ,

22.( 79.240 ) 79.240 deg. F '

temperature =

temperature 23 ( 75.820') = 75.820 deg. F

temperature 24 ( 72.790 ) = 72.790 dag. F

temperature 25 ( 73.220 ) = 73.220 deg. F i temperature 26 ( 71.650 ) = 71.650 dag. F 1

dewpoint 1 ( 70.750 ) = 70.750 dag. F , 0.3723 psia dewpoint 2 ( 70.560 ) = 70.560 deg. F ,'O.3699 psia

dewpoint 3 ( 71.020 ) = 71.020 deg. F , 0.3757 psia dewpoint 4 ( 70.720 ) = 70.720 dag. F , 0.3719 psia dewpoint 21 ( 63.690 ) = 63.690 deg. F , 0.2918 psia dewpoint 22 ( 63.120 ) = 63.120 dag. F , 0.2860 psia pressure 1 ( 26.5927 ) = 26.5927 psia pressure 2 ( 26.5962 ) = 26.5962 psia weighted averages, volume and air mass J

temperature = 75.34627 deg. F 4

pressure = 26.59330 psia

vapor pressure = 0.35731 psia

volume = 1670000 cu. ft.

dry air mass = 221042.12 lba 4

)

i i

i. * .

i data set 39 f

I time = 0 date = 1121-(.

i sensor raw data value

temperature 1( 76.080 ) = 76.080 deg. F

} temperature 2( 76.250 ) = 76.250 deg. F l temperature 3 ( 76.180 ) = 76.180 deg. F

temperature 4 ( 76.400 ) = 76.400 dag. F l temperature 5 ( 75.310 ) = 75.310 deg..F j temperature 6( 75.620 ) = 75.620 dag. F l temperature 7 ( 75.550 ) = 75.550 dag. F l' temperature 8 ( 76.300 ) = 76.300 deg. F temperature 9 ( 76.330 ) = 76.330 deg. F

temperature 10 ( 75.230 ) = 75.230 deg. F j temperature 11-( 76.500 ) = 76.500 deg. F

. temperature 12 ( 76.180 ) = 76.180 deg. F i temperature 13 ( 76.920 ) = 76.920 deg. F temperature 14 ( 63.760-) = 63.760 deg. F temperature 15 ( 76.230 ) = 76.230 deg. F temperature 16 ( 74.420 ) = 74.420 deg. F 3-temperature 17 ( 74.240 ) = 74.240 deg. F

temperature 18 ( 73.390 ) = 73.390.deg. F temperature 21 ( 82.760 ) = 82.760 deg. F ,

i temperature 22 ( 79.300 ) = 79.300 deg. F 1 l temperature 23 ( 75.890 ) = 75.890 deg. F j temperature 24 ( 72.810 ) = 72.810 deg. F l temperature 25 ( 73.290 ) = 73.290 deg. F

]

temperature 261( 71.740 ) = 71.740 deg. F dowpoint 1 ( 70.770 ) = 70.770.deg. F , 0.3726 psia dewpoint- 2 ( 70.570 ) = 70.570 deg. F , 0.3700 psia dewpoint 3 ( 71.040 ) =- 71.040 deg. F , 0.3760 psia dewpoint 4 ( 70.710 ) = 70.710 deg. F;, 0.3718 psia dewpoint 21 ( 63.730 ) = 63.730 deg. F , 0.2922 psia dewpoint 22 ( 63.210 ) = 63.210 deg. F , 0.2869 psia pressure 1 ( 26.5924 ) = 26.5924 psia pressure 2 ( 26.5961 ) = .26.5961 psia weighted averages, volume and air mass l l

l temperature = 75.34424 deg. F pressure = 26.59303 psia vapor pressure = 0.35758 psia volume = 1670000 cu. ft, dry air mass = 221038.45 lba 1

l l

1 w 'uv-"+- . m.

i l

l data set 40 time = 15 date = 1121 l

}

. sensor raw data value a

f temperature 1 ( 76.070 ) = 76.070 deg. F g temperature 2 ( 76.210 ) = 76.210 deg. F temperature 3 ( 76.170 ) = 76.170 deg. .F

j. temperature 4 ( 76.490 ) = 76.490 deg. F temperature 5 ( 75.290 ) = 75.290 deg. F

) temperature 6 ( 75.610 ) = .75.610 deg. F j temperature 7 ( 75.520 ) = 75.520 deg.'F l temperature 8 ( 76.320 ) = 76.320 deg. F temperature' 9.( 76.340 ) = 76.340 deg. F

. temperature 10 ( 75.310 ) = 75.310 dag. F

! temperature 11 ( - 76.510 ) = 76.510 deg. F

temperature 12 ( 76.180 ) = 76.180 deg. F

! temperature 13 ( 76.930 ) = 76.930 deg. F j temperature 14 ( 63.790 ) = 63.790 deg. F i temperature 15 ( 76.240 ) = 76.240 deg. F temperature 16 ( 74.400 ) = 74.400 deg. F temperature 17 ( 74.260 ) = 74.260 deg. F temperature 18 ( .73.390 ) = 73.390 deg. F l_ temperature 21 ( 82.800 ) = 82.800 dag. F ,

j temperature 22 ( 79.380 ) = . 79.380 deg. F -

]

temperature 23 ( 75.940 ) = 75.940 dag. F

. temperature 24 ( 72.900 ) = 72.900 deg. F

temperature 25 ( 73.390 ) = 73.390 deg. F temperature 26 ( 71.810 ) = 71.810 deg. F j dewpoint 1 ( 70.790 ) = 70.790 deg. F , 0.3728 psia

dewpoint 2 ( 70.590 ) = 70.590 deg. F, 0.3703 psia

! dewpoint -3 ( 71.060 ) = 71.060 deg. F, 0.3763 psia j dewpoint 4 ( 70.740 ) = 70.740 dag. F , 0.3722 psia 1 dewpoint 21 ( 63.820 ) = 63.820 dag. F, 0.2931 psia j dewpoint 22 ( 63.290 ) = 63.290 deg. F, 0.2877 psia i

i pressure' 1 ( 26.5923 ) = 26.5923 psia j pressure 2 ( 26.5958 ) = 26.5958 psia i

j weighted averages, volume and air mass

! temperature = 75.36203 deg. F pressure = 26.59290 psia l vapor pressure. = 0.35794 psia i volume = 1670000 cu.~ft.

j dry air mass = 221026.88 lba i i

1 i a

1

, , .- e , .-. -. a - - -

• o data set 41 time = 30 date = 1121 sensor raw data value temperature 1( 76.060 ) = 76.060 deg. F temperature 2( 76.150 ) = 76.150 dag. F temperature 3( 76.170 ) = 76.170 deg. F temperature 4 ( 76.560 ) = 76.560 dag. F temperature 5 ( 75.270 ) = 75.270 deg. F temperature 6 ( 75.579 ) = 75.570 deg. F temperature 7 ( 75.610 ) = 75.510 deg. F temperature 8 ( 76.340 ) = 76.340 deg. F temperature 9 ( 76.320 ) = 76.320 deg. F temperature 10 ( 75.220 ) = 75.220 deg. F temperature 11 ( 76.540 ) = 76.540 deg. F temperature 12 ( 76.200 ) = 76.200 deg. F temperature 13 ( 76.890 ) = 76.890 deg. F temper,ature 14 ( 63.820 ) = 63.820 dag. F temperature 15 ( 76.180-) = 76.180 deg. F temperature 16 ( 74.420 ) = 74.420 dag. F temperature 17 ( 74.260 ) = 74.260 deg. F temperature 18 ( 73.380 ) = 73.380 deg. F tamperature 21 ( 82.800 ) = 82.800 deg. F ,

temperature 22 ( 79.420 ) = 79.420 deg. F temperature 23.( 76.020 ) = 76.020 deg. F temperature 24 ( 72.970 ) = 72.970 deg. F temperature 25 '( 73.380 ) = 73.380 dag. F temperature 26 ( 71.870 ) = 71.870 deg. F dewpoint 1 ( 70.690 ) = 70.690 dag. F , 0.3716 psia dewpoint 2 ( 70.600 ) = 70.600 deg. F , 0.3704 psia dewpoint 3 ( 71.080 ) = 71.080_deg. F , 0.3765 psia dewpoint 4 ( 70.740 ) = -70.740 deg. F , 0.3722 psia dewpoint 21 ( 63.880 ) = 63.880 deg. F , 0.2937 psia dewpoint 22 ( 63.360 ) = 63.360 dag. F , 0.2884 psia pressure 1 ( 26.5916 ) = 26.5916 psia pressure 2 ( 26.5954 ) = 26.5954 psia weighted averages, volume and air mass temperature = 75.36283 deg. F pressure = 26.59225 psia vapor pressure = 0.35783 psia volume = 1670000 cu. ft.

dry air mass = 221022.02 lbm

-. - . . - . . . . . _ . . . . . - . - .~ ..

I e .

l data set 42 time = 45 date = 1121 i

sensor raw data value i

temperature 1( 76.060') = 76.060 deg. F l temperature 2( 76.160 ) = 76.160 deg. F temperature 3 ( 76.120 ) = 76.120 dag. F l temperature 4 ( 76.450 ) = 76.450 deg. F i temperature 5( 75.250 ) = 75.250 deg. F j temperature 6( 75.530 ) = 75.530 deg. F l temperature .7 ( 75.520 ) = 75.520 deg. F temperature 8 ( 76.300 ) = 76.300 deg. F temperature 9( 76.280 ) = 76.280 deg. F temperature 10 ( 75.210 ) = 75.210 deg. F temperature 11 ( 76.530 ) = 76.530 deg. F temperature 12 ( 76.190 ) = 76.190 deg. F temperature 13 ( 76.920 ) = 76.920 deg. F temperature 14 ( 63.840 ) = 63.840 deg. F -

temperature 15 ( 76.290 ) = 76.290 deg. F temperature 16 ( 74.420 ) = 74.420 deg. F temperature 17 ( 74.270 ) =- 74.270 dag. F temperature 18-( 73.380 ) = 73.380 deg. F temperature 21 ( 82.800 ) = 82.800 deg. F temperature 22 ( 79.450 ). = 79.450 deg. F i temperature 23 ( 76.080 ) = 76.080 dag. F temperature 24 ( 73.050 ) = 73.050 deg. F temperature 25 ( 73.450 ) = 73.450 deg. F temperature 26 ( 71.910 ) = 71.910 deg. F dewpoint 1 ( 70.730 ) = 70.730 deg. F , 0.3721 psia dewpoint 2 ( 70.590 ) = 70.590 deg. F , 0.3703 psia dewpoint 3 ( 71.090 ) = 71.090 deg. F , 0.3766 psia dewpoint 4 ( 70.760 ) = 70.760 deg. .

F , 0.3724 psia dewpoint 21 ( 63.950 ) = 63.950 deg. F , 0.2945 psia dewpoint 22 ( 63.440 ) = 63.440 deg. F , 0.2892 psia pressure 1 ( 26.5918 ) = 26.5918 psia pressure 2 ( 26.5952 ) = 26.5952 psia weighted averages, volume and air mass temperature = 75.35947 deg. F pressure = 26.59238 psia vapor pressure = 0.35812 psia volume = 1670000 cu. ft.

dry air mass = 221022.14 lba

• s data set 43 time = 100 date = 1121 sensor raw data value temperature 1( 76.040 ) = 76.040 deg. F temperature 2 ( 76.190 ) = 76.190 deg. F temperature 3 ( 76.100 ) = 76.100 deg. F temperature 4( 76.300 ) = 76.300 deg. F temperature 5( 75.240 ) = 75.240 deg. F temperature 6( 75.560 ) = 75.560 deg. F temperature 7 ( 75.470 ) = 75.470 deg. F temperature 8( 76.290 ) = 76.290 deg. F temperature 9( 76.280 ) = 76.280 deg. F temperature 10 ( 75.190 ) = 75.190 deg. F temperature 11 ( 76.480 ) = 76.480 deg. F temperature 12 ( 76.220 ) = 76.220 deg. F temperature 13 ( 76.900 ) = 76.900 deg. F temperature 14 ( 63.880 ) = 63.880 deg. F temperature 15 ( 76.210 ) = 76.210 deg. F temperature 16 ( 74.400 ) = 74.400 deg. F temperature 17 ( 74.260 ) = 74.260 deg. F temperature 18 ( 73.380 ) = 73.380 deg. F temperature 21 ( 82.790 ) = 82.790 deg. F .

temperature 22 ( 79.460 ) = 79.460 deg. F temperature 23 ( 76.120 ) = 76.120 deg. F temperature 24 ( 73.090 ) = 73.090 deg. F temperature 25 ( 73.470 ) = 73.470 deg. F temperature 26 ( */1.900 ) = 71.900 deg. F l dewpoint 1 ( 70.790 ) = 70.790 deg. F, 0.3728 psia dewpoint 2 ( 70.610 ) = 70.610 deg. F, 0.3705 psia dewpoint 3 ( 71.100 ) = 71.100 deg. F, 0.3768 psia dewpoint 4 ( 70.750 ) = 70.750 deg. F , 0.3723 psia dewpoint 21 ( 63.990 ) = 63.990 deg. F, 0.2949 psia dewpoint 22 ( 63.470 ) = 63.470 deg. F , 0.2895 psia i

pressure 1 ( 26.5915 ) == 26.5915 psia pressure 2 ( 26.5949 ) 26.5949 psia weighted averages, volume and air mass temperature = 75.34303 deg. F pressure = 26.59208 psia vapor pressure = 0.35842 psia volume = 1670000 cu. ft.

dry air mass = 221023.81 lba

o .

data set 44 time = 115 date = 1121 sensor raw data value temperature 1( 76.030 ) = 76.030 deg. F temperature 2( 76.210 ) = 76.210 dag. F temperature 3( 76.140 ) = 76.140 deg. F temperature 4( 76.420 ) = 76.420 deg. F temperature 5( 75.260 ) = 75.260 deg. F temperature 6( 75.560 ) = 75.560 deg. F temperature 7-( 75.490 ) = 75.490 deg. F temperature 8( 76.300 ) = 76.300 deg. F temperature 9 -( 76.290 ) = 76.290 dag. .

F temperature 10 ( 75.160 ) = 75.160 deg. F temperature 11 ( 76.480 ) = 76.480 deg. F temperature 12 ( 76.150 )- = 76.150 deg. F temperature 13 ( 76.880 ) = 76.880 deg. F temperature 14 ( 63.900 ) = 63.900 dag. F temperature 15 ( 76.190 ) = 76.190 deg. F temperature 16 ( 74.390 ) = 74.390 deg. F temperature 17 ( 74.260 ) = 74.260 deg. F temperature 18 ( 73.360 ) = 73.360 deg. F temperature 21 ( 82.790 ) = 82.790 dag. F .

temperature 22 ( 79.460 ) = 79.460 deg. F temperature 23 ( 76.170 ) = 76.170 dag. F temperature 24 ( 73.140 ) = 73.140 deg. F temperature 25 ( 73.560 )' = 73.560 deg. F temperature 26 ( 71.950 ) = 71.960 deg. F dewpoint 1 ( 70.880 ) = 70.880 deg. F, 0.3740 psia dewpoint 2 ( 70.660 ) = 70.660 deg. F , 0.3712 psia dewpoint 3 ( 71.110 ) = 71.110 dag. F , 0.3769 psia dewpoint 4 ( 70.770 ) = 70.770 deg. F , 0.3726 psia dewpoint 21 ( 64.050 ) = 64.050 deg. F , 0.2955 psia dewpoint 22 ( 63.530 ) = 63.530 deg. F, 0.2901 psia

} pressure 1 ( 26.5913 ) = 26.5913 psia pressure. 2 ( 26.5946 ) = 26.5946 psia

, weighted averages, volume and air mass temperature = 75.36296 deg. F pressure = 26.59186 psia vapor pressure = 0.35904 psia volume = 1670000 cu. ft.

dry air mass = 221008.53 lbm i

data set 45 time = 130 date = 1121 sensor raw data value i l

temperature 1( 76.020 ) = 76.020 deg. F l temperature 2 ( 76.150 ) = 76.150 deg. F temperature 3 ( 76.110 ) = 76.110 deg. F temperature 4( 76.410 ) = 76.410 deg. F temperature 5 ( 75.240 ) = 75.240 deg. F temperature 6( 75.560 ) = 75.560 deg. F temperature 7 ( 75.450 ) = 75.450 deg. F temperature 8 ( 76.300 ) = 76.300 deg. F temperature 9 ( 76.270 ) = 76.270 deg. F ,

temperature 10 ( 75.240 ) = 75.240 deg. F l temperature 11 ( 76.480 ) = 76.480 deg. F temperature 12 ( 76.150 ) = 76.150 deg. F temperature 13 ( 76.890 ) = 76.890 deg. F temperature 14 ( 63.930 ) = 63.930 deg. F temperature 15 ( 76.160 ) = 76.160 deg. F temperature 16 ( 74.380 ) = 74.380 deg. F temperature 17 ( 74.250 ) = 74.250 deg. F temperature 18 ( 73.360 ) = 73.360 deg. F temperature 21 ( 82.710 ) = 82.710 deg. F temperature 22 ( 79.470 ) = 79.470 dag. F i temperature 23 ( 76.220 ) = 76.220 deg. F temperature 24 ( 73.200 ) = 73.200 dag. F temperature 25 ( 73.540 ) = 73.540 deg. F temperature 26 ( 71.970 ) = 71.970 deg. F dewpoint 1 ( 70.830 ) = 70.830 dag. F , 0.3733 psia dewpoint 2 ( 70.650 ) = 70.650 deg. F , 0.3710 psia dewpoint 3 ( 71.110 ) = 71.110 deg. F, 0.3769 psia dewpoint 4 ( 70.760 ) = 70.760 deg. F , 0.3724 psia dewpoint 21 ( 64.080 ) = 64.080 deg. F, 0.2958 psia dewpoint 22 ( 63.580 ) = 63.580 deg. F, 0.2907 psia pressure 1 ( 26.5909 ) = 26.5909 psia pressure 2 ( 26.5944 ) = 26.5944 psia weighted averages, volume and air mass temperature = 75.35577 deg. F pressure = 26.59150 psia vapor pressure = 0.35892 psia volume = 1670000 cu. ft.

dry air mass = 221009.45 lba

.. . _ . . ~ _

f data' set 46 j time = 145 date = 1121 1

sensor raw data value 2

temperature 1 ( 76.020 ) = 76.020 deg. F j temperature .2-( .76.130.) -= 76.130 deg. F l temperature 3-( 76.060 ) = 76.060 deg. F j temperature 4 ( 76.420 ) = 76.420 deg. F l temperature 5 ( 75.220 ) = 75.220 deg. F j temperature' 6 ( 75.510 ) = 75.510 deg. F j temperature .7 ( 75.420 ): = 75.420 deg.-F j temperature 8 ( 76.340 ) = 76.340 deg. F

temperature 9 ( 76.320 ) = 76.320;deg. F

temperature.1'O ( 75.370 ) = 75.370 deg.

P

! temperature 11 ( 76.490 ) = 76.490 deg. F f temperature 12 ( 76.140 ) = 76.140.deg. F:

f temperature 13 ( 76.850-) = 76.850 deg. F t temperature 14 ( 63.950-) = 63.950 deg. F ,

4 temper.ature 15-( 76.170-) = 76.170 dag. F

] temperature 16 ( 74.390 ) = 74.390 deg. F j temperature 17 ( 74.260 ) = 74.260 deg. F temperature 18 ( 73.350 ) = 73.350 dag. F. -

temperature 21 ( 82.760 ) = 82.760 deg. F j temperature 22 ( 79.470 ) = 79.470 deg. F i

! temperature 23 ( 76.270 ) = 76.270 deg. F

temperature 24 ( 73.280 ) = -73.280 deg. F i temperature 25 ( 73.600 ) = 73.600 deg. F-l temperature 26 ( 72.010 ) = 72.010 deg. F

dewpoint 1 ( 70.840 ) = 70.840 deg. F, 0.3735 psia

dewpoint 2 ( 70.660 )' = 70.660 deg. F , 0.3712 psia j dewpoint 3 ( 71.170 ) = 71.170 deg. F , 0.3777 psia-

. dewpoint 4 ( 70.780 ) = 70.780 deg. .

F , 0.3727 psia j- dewpoint 21 ( 64.160 ) = 64.160 deg. F , 0.2966 psia f dewpoint 22 ( 63.650 ) = 63.650 deg. F , 0.2914 psia t

l pressure 1 ( 26.5909 ) = 26.5909 psia i pressure 2 ( 26.5943 ) = 26.5943 psia o

j weighted averages, volume and air mass

! temperature = 75.35973 deg. F j pressure = 26.59148 psia 1 vapor pressure = 0.35926 psia l' volume = 1670000 cu. ft.

I dry air mass = 221004.80 lba i

4

)

, e

~

data set 47 l

time = 200 date = 1121 sensor raw data value

, temperature 1( 76.000 ) = 76.000 deg. F temperature 2( 76.090 )- = 76.090 deg. F temperature 3( 76.030 ) = 76.030 deg. F 4 temperature 4( 76.420 ) = 76.420 deg. F 2

temperature 5 ( 75.270 ) = 75.270 deg. F temperature 6 ( 75.510 ) = 75.510 deg. F temperature 7 ( 75.490 ). = 75.490 deg. F temperature 8( 76.300 ) = 76.300 deg. F i temperature 9 ( 76.270 ) = 76.270 deg. F

! temperature 10 ( 75.410 ) = 75.410 deg. F 4

temperature 11 ( 76.530 ) = 76.530 deg. F temperature 12 ( 76.220 ) = 76.220 deg. F temperature 13 ( 76.930 ) = 76.930 deg. F temperature 14 ( 63.980 ) = 63.980 deg. F temperature 15 ( 76.120 ) = 76.120 deg. F temperature 16 ( 74.450 ) = 74.450 deg. F temperature 17 ( 74.300 ) = 74.300 deg. F temperature 18 ( 73.360 ) = 73.360 deg. F temperature 21 ( 82.740 ) = 82.740 deg. F .

temperature 22 ( 79.490 ) = 79.490 deg. F temperature 23 ( 76.340 ) = 76.340 deg. F temperature 24 ( 73.250 ) = 73.250 deg. F temperature 25 ( 73.650 ) = 73.650 deg. F l

temperature 26 ( 72.070 ) = 72.070 deg. F i

l dewpoint 1 ( 70.740 ) = 70.740 deg. F, 0.3722 psia dewpoint 2 ( 70.690 ) = 70.690 deg. F , 0.3716 psia dewpoint 3 ( 71.120 ) = 71.120 deg. F , 0.3770 psia

dewpoint 4 ( 70.790 ) = 70.790 deg. F , 0.3728 psia dewpoint 21 ( 63.440 ) = 63.440 deg. F , 0.2892 psia dewpoint 22 ( 63.690 ) = 63.690 deg. F , 0.2918 psia pressure 1 ( 26.5910 ) = 26.5910 psia pressure 2 ( 26.5946 ) = 26.5946 psia weighted averages, volume and air mass temperature = 75.37236 deg. F pressure = 26.59161 psia vapor pressure = 0.35906 psia volume = 1670000 cu. ft.

dry air mass = 221002.39 lbm

• w l

data set 48 time = 215 date = 1121 sensor

~

raw data value temperature 1( 76.000 ) = 76.000 deg. F

temperature 2( 76.120 ) = 76.120 deg. F temperature 3 ( 76.060 ) = 76.060 deg. F

temperature 4 ( 76.420 ) = 76.420 deg. F temperature 5( 75.250 ) = 75.250 deg. F temperature 6( 75.500 ) = 75.500 deg. F

- temperature 7( 75.500 ) = 75.500 deg. F temperature 8( 76.280_) = 76.280 deg. F 3- temperature 9( 76.210 ) = 76.210 deg. F temperature 10 ( 75.270 ) = 75.270 deg. F temperature 11 ( 76.470 ) = 76.470 deg. F

, temperature 12 ( 76.160 ) = 76.160 deg. F temperature 13 ( 76.930 ) = 76.930 deg. F i temperature 14 ( 64.020 ) = 64.020 dag. F temperature 15 ( 76.190 ) = 76.190 deg. F temperature 16 ( 74.440 ) = 74.440 deg. F temperature 17 ( 74.310 ) = 74.310 deg. F

, temperature 18 ( 73.350 ) = 73.350 dag. F temperature 21 ( 82.760 ) = 82.760 deg. F .

temperature 22 ( 79.540 ) = 79.540 deg. F temperature 23 ( 76.390 ) = 76.390 deg. F j temperature 24 ( 73.290 ) = 73.290 deg. F temperature 25 ( 73.700 ) = 73.700 deg. F temperature 26 ( 72.150 ) = 72.150 deg. F dewpoint 1 ( 70.740 ) = 70.740 deg. F, 0.3722 psia i dewpoint 2 ( 70.660 ) = 70.660 deg. F, 0.3712 psia j dewpoint 3 ( 71.150 ) = 71.150 deg. F , 0.3774 psia dewpoint 4 ( 70.800 ) = 70.800 dag. F, 0.3729 psia dewpoint 21 ( 64.250 ) = 64.250 deg. F, 0.2976 psia i dewpoint 22 ( 63.750 ) = 63.750 deg. F, 0.2924 psia l pressure 1 ( 26.5916 ) = 26.5916 psia ,

l pressure 2 ( 26.5953 ) = 26.5953 psia j 1

weighted averages, volume and air mass temperature = 75.37816 deg. F j pressure = 26.59223 psia vapor pressure = 0.35913 psia '

volume = 1670000 cu. ft.

I dry air mass = 221004.61 lbm i

f 4

4

-. - - - - - , , , , - n.- - - - -

data set 49 time = 230 date = 1121 sensor raw data value

temperature 1 ( 76.010 ) = 76.010 deg. F )

temperature 2( 76.100 ) = 76.100 deg. F 1 l

temperature 3 ( 76.060 ) = 76.060 dag. F temperature 4 ( 76.350 ) = 76.350 deg. F temperature 5 ( 75.170 ) = 75.170 deg. F temperature 6 ( 75.520 ) = 75.520 deg. F temperature 7 ( 75.450 ) = 75.450 deg. F l temperature 8 ( 76.320 ) = 76.320 dag. F temperature 9 ( 76.260 ) = 76.260 deg. F

, temperature 10 ( 75.360 ) = 75.360 dag. F temperature 11 ( 76.460 ) = 76.460 deg. F temperature 12 ( 76.160 ) = 76.160 deg. F i temperature 13 ( 76.920 ) = 76.920 deg. F temperature 14 ( 64.040 ) = 64.040 deg. F l temperature 15 ( 76.090 ) = 76.090 deg. F temperature 16 ( 74.420 ) = 74.420 deg. F j temperature 17 ( 74.280 ) = 74.280 deg. F temperature 18 ( 73.360 ) = 73.360 deg. F 4 temperature 21 ( 82.740 ) = 82.740 deg. F

temperature 22 ( 79.590 ) = 79.590 deg. F i

temperature 23 ( 76.420 ) = 76.420 deg. F 4

temperature 24 ( 73.360 ) = 73.360 deg. F

temperature 25 ( 73.770 ) = 73.770 deg. F j temperature 26 ( 72.220 ) = 72.220 deg. F

. dewpoint 1 ( 70.790 ) = 70.790 deg. F , 0.3728 psia dewpoint 2 ( 70.660 ) = 70.660 deg. F , 0.3712 psia dewpoint 3 ( 71.170 ) = 71.170 deg. F , 0.3777 psia

i. dewpoint 4 (- 70.820 ) = 70.820 deg. F, 0.3732 psia dewpoint 21 ( 64.300 ) = 64.300 deg. F , 0.2981 psia j dewpoint 22 ( 63.800 ) = 63.800 deg. F, 0.2929 psia 4

pressure 1 ( 26.5914 ) = 26.5914 psia l pressure 2 ( 26.5948 ) = 26.5948 psia weighted averages, volume and air mass temperature = 75.37479 deg. F i

pressure = 26.59198 psia )

vapor pressure = 0.35945 psia l a volume = 1670000 cu. ft. I j dry air. mass = 221001.21 lbm

)

1 l

1 I

i

l I o data set 50 1

time = 245 date = 1121 sensor raw data value i

temperature 1( 75.990 ) = 75.990 deg. F temperature 2( 76.030 ) = 76.030 deg. F temperature 3( 76.010 ) = 76.010 deg. F temperature 4 ( 76.350 ) = 76.350 deg. F temperature 5( 75.220 ) = 75.220 deg. F temperature 6( 75.470 ) = 75.470 deg. F temperature 7( 75.450 ) = 75.450 deg. F temperature 8( 76.290 ) = 76.290 deg. F temperature 9( 76.230 ) = 76.230 deg. F temperature 10 ( 75.310 ) = 75.310 deg. F temperature 11 ( 76.450 ) = 76.450 deg. F temperature 12 ( 76.140 ) = 76.140 deg. F temperature 13 ( 77.020 ) = 77.020 deg. F temperature 14 ( 64.060 ) = 64.060 deg. F temperature 15 ( 76.150 ) = 76.150 dag. F temperature 16 ( 74.470 ) = 74.470 dag. F temperature 17 ( 74.320 ) = 74.320 deg. F temperature 18 ( 73.360 ) = 73.360 dag. F temperature 21 ( 82.730 ) = 82.730 deg. F temperature 22 ( 79.630 ) = 79.630 deg. F i temperature 23 ( 76.490 ) = 76.490 dag. F temperature 24 ( 73.400 ) = 73.400 dag. F temperature 25 ( 73.830 ) = 73.830 deg. F temperature 26 ( 72.280 ) = 72.280 deg. F dewpoint 1 ( 70.750 ) = 70.750 deg. F , 0.3723 psia dewpoint 2 ( 70.730 ) = 70.730 deg. F , 0.3721 psia dewpoint 3 ( 71.180 ) = 71.180 deg. F , 0.3778 psia dewpoint 4 ( 70.830 ) = 70.830 deg. F , 0.3733 psia dewpoint 21 ( 64.350 ) = 64.350 deg. F , 0.2986 psia dewpoint 22 ( 63.850 ) = 63.850 deg. F , 0.2934 psia i l

pressure 1 ( 26.5913 ) = 26.5913 psia i pressure 2 ( 26.5950 ) = 26.5950 psia weighted averages, volume and air mass temperature = 75.37862 deg. F pressure = 26.59193 psia l vapor pressure = 0.35970 psia l volume = 1670000 cu. ft.

dry air mass = 220997.04 lbm

• i.

l data set 51 time = 300 date = 1121 I

sensor raw data value

! temperature 1( 75.950 ) = 75.950 deg. F

temperature 2( 76.000 ) = 76.000 deg. F

' temperature 3( 76.010 ) = 76.010 deg. F temperature 4 ( 76.270 ) = 76.270 deg. F temperature 3( 75.210 ) = 75.210 dag. F temperature 6( 75.460 ) = 75.460 deg. F temperature 7 ( 75.390 ) = 75.390 deg. F temperature 8( 76.290 ) = 76.290 deg. F temperature 9( 76.230 ) = 76.230 deg. F temperature 10 ( 75.370 ) = 75.370 dag. F temperature 11 ( 76.450 ) = 76.450 dag. F temperature 12 ( 76.150 ) = 76.150 deg. F temperature 13 ( 77.040 ) = 77.040 deg. F temperature 14 ( 64.080 ) = 64.080'deg. F temper'ature 15 ( 76.140 ) = 76.140 deg. F temperature 16 ( 74.450 ) = 74.450 dag. F temperature 17 ( 74.320 ) = 74.320 deg. F temperature 18 ( 73.360 ) = 73.360 dag. F temperature 21 ( 82.790 ) = 82.790 deg. F ,

?

temperature 22 ( 79.660 ) = 79.660 dag. F temperature 23 ( 76.550 ) = 76.550 deg. F temperature 24 ( 73.480 ) = 73.480 deg. F temperature 25 ( 73.840 ) = 73.840 deg. F temperature 26 ( 72.330 ) = 72.330.deg. F dewpoint 1 ( 70.870 ) = 70.870 deg. F , 0.3738 psia dewpoint 2 ( 70.720 ) = 70.720 deg. F , 0.3719 psia dewpoint 3 ( 71.200 ) = 71.200 deg. F , 0.3780 psia dewpoint 4 ( 70.840 ) = 70.840 deg. F , 0.3735 psia dewpoint 21 ( 64.410 ) = 64.410 deg. F , 0.2992 psia dewpoint 22 ( 63.920 ) = 63.920 deg. F, 0.2941 psia pressure 1 ( 26.5912 ) = 26.5912 psia pressure 2 ( 26.5947 ) = 26.5947 psia weighted averages, volume and air mass temperature = 75.37246 deg. F pressure = 26.59180 psia ,

vapor pressure = 0.36022 psia i I

volume = 1670000 cu. ft.

dry air mass = 220994.16 lba l

l

' w data set 52 time = 315 date = 1121 sensor raw data value temperature 1( 75.970 ) = 75.970 deg. F temperature 2( 76.020 ) = 76.020 dag. F temperature 3( 76.000 ) = 76.000 dag. F temperature 4 ( 76.330 ) = 76.330 deg. F temperature 5 ( 75.200 ) = 75.200 deg. F temperature 6 ( 75.460 ) = 75.460 deg. F temperature 7 ( 75.410 ) = 75.410 deg. F temperature 8 ( 76.240 ) = 76.240 deg. F temperature 9 ( 76.200 ) = 76.200 deg. F temperature 10 ( 75.380 ) = 75.380 deg. F temperature 11 ( 76.440 ). = 76.440 deg. F temperature 12 ( 76.140 ) = 76.140 deg. F temperature 13 ( 77.020 ) = 77.020 deg. F temperature 14 ( 64.110 ) = 64.110 deg. F temperature 15 ( 76.140 ) = 76.140 dag. F temperature 16 ( 74.480 ) = 74.480 deg. F temperature 17 ( 74.330 ) = 74.330 deg._F temperature 18 ( 73.380 ) = 73.380 dag. F temperature 21 ( 82.750 ) = 82.750 deg. F ,

temperature 22 ( 79.670 ) = 79.670 deg. F temperature 23 ( 76.580 ) = 76.580 deg. F temperature 24 ( 73.530 ) = 73.530 dag. F temperature 25 ( 73.920 ) = 73.920 deg. F temperature 26 ( 72.350 ) = 72.350 dag. F dewpoint 1 ( 70.890 ) = 70.890 deg. F , 0.3741 psia dewpoint 2 ( 70.730 ) = 70.730 deg. F , 0.3721 psia dewpoint 3 ( 71.220 ) = 71.220 dag. F , 0.3783. psia dewpoint 4 ( 70.850 ) = 70.850 deg..F , 0.3736 psia dewpoint 21 ( 64.450 ) = 64.450 deg. F , 0.2996 psia dewpoint 22 ( 63.950 ) = 63.950 deg. F , 0.2945 psia pressure 1 ( 26.5912 ) = 26.5912 psia pressure 2 ( 26.5950 ) = 26.5950 psia weighted averages, volume and air mass temperature = 75.38570 deg. F pressure = 26.59185 psia vapor pressure = 0.36042 psia volume = 1670000 cu. ft.

dry air mass = 220987.38 lba l

data set 53 time = 330 date = 1121 i sensor raw data value temperature 1( 75.950 ) = 75.950 deg. F i temperature 2( 75.980 ) = 75.980 deg. F l temperature 3( 75.980 ) = 75.980 deg. F l temperature 4( 76.250 ) = 76.250 dog. F l temperature 5( 75.160 ) = 75.160 deg. F temperature 6 ( 75.390 ) = 75.390 deg. F temperature 7 ( 75.400 ) = 75.400 deg. F temperature 8 ( 76.300 ) = 76.300 deg. F .

temperature 9( 76.200 ) = 76.200 deg. F temperature 10 ( 75.360 ) = 75.360 deg. F l temperature 11 ( 76.430 ) = 76.430 deg. F temperature 12 ( 76.120 ) = 76.120 deg. F temperature 13 ( 77.030 ) = 77.030 deg. F temperature 14 ( 64.140 ) = 64.140 deg. F temperature 15 ( 76.130 ) = 76.130 deg. F temperature 16 ( 74.450 ) = 74.450 deg. F temperature 17 ( 74.350 ) = 74.350 deg. F temperature 18 ( 73.380 ) = 73.380 deg. F temperature 21 ( 82.700 ) = 82.700 deg. F  ;

79.700 )

temperature 22 ( = 79.700 deg. F temperature 23 ( 76.630 ) = 76.630 deg. F temperature 24 ( 73.620 ) = 73.620 deg. F temperature 25 ( 74.000 ) = 74.000 deg. F temperature 26 ( 72.390 ) = 72.390 deg. F dewpoint 1 ( 70.870 ) = 70.870 deg. F , 0.3738 psia dewpoint 2 ( 70.750 ) = 70.750 deg. F, 0.3723 psia dewpoint 3 ( 71.210 ) = 71.210 deg. F , 0.3782 psia dewpoint 4 ( 70.840 ) = 70.840 deg. F , 0.3735 psia dewpoint 21 ( 64.530 ) = 64.530 deg. F, 0.3005 psia dewpoint 22 ( 64.010 ) = 64.010 deg. F, 0.2951 psia pressure 1 ( 26.5912 ) = 26.5912 psia pressure 2 ( 26.5945 ) = 26.5945 psia weighted averages, volume and air mass temperature = 75.37736 deg. F pressure = 26.59176 psia vapor pressure = 0.36050 psia volume = 1670000 cu. ft, dry air mass = 220989.44 lbm

1 I

l l'

data set 54 time = 345 date = 1121 sensor raw data value temperature 1( 75.930 ) = 75.930 deg. F temperature 2( 76.000 ) = 76.000 deg. F temperature 3 ( 75.980 ) = 75.980 dag. F temperature 4 ( 76.310 ) = 76.310 deg. F temperature 5( 75.170 ) = 75.170 deg. F temperature 6( 75.450 ) = 75.450 deg. F temperature 7 ( 75.450 ) = 75.450 deg. F temperature 8( 76.270 ) = 76.270 deg. F temperature 9( 76.190 ) = 76.190 deg. F temperature 10 ( 75.410 ) = 75.410 deg. F temperature 11 ( 76.430 ) = 76.430 deg. F temperature 12 ( 76.140 ) = 76.140 deg. F temperature 13 ( 77.040 ) = 77.040 deg. F temperature 14 ( 64.170 ) = 64.170 deg. F temper'ature 15 ( 76.070 ) = 76.070 deg. F temperature 16 ( 74.470 ) = 74.470 deg. F temperature 17 ( 74.330 ) = 74.330 deg. F temperature 18 ( 73.380 ) = 73.380 deg. F i temperature 21 ( 82.760 ) = 82.760 deg. F  ;

l temperature 22 ( 79.730 ) = 79.730 deg. F i temperature 23 ( 76.670 ) = 76.670 deg. F temperature 24 ( 73.660 ) = 73.660 deg. F temperature 25 ( 73.990 ) = 73.990 deg. F i 72.430 )

temperature 26 ( = 72.430 deg. F dewpoint 1 ( 70.910 ) = 70.910 deg. F, 0.3743 psia dewpoint 2 ( 70.770 ) = 70.770 deg. F, 0.3726 psia dewpoint 3 ( 71.220 ) = 71.220 deg. F, 0.3783 psia dewpoint 4 ( 70.840 ) = 70.840 deg. F, 0.3735 psia dewpoint 21 ( 64.570 ) = 64.570 deg. F , 0.3009 psia dewpoint 22 ( 64.060 ) = 64.060 deg. F, 0.2956 psia pressure 1 ( 26.5913 ) = 26.5913 psia pressure 2 ( 26.5948 ) = 26.5948 psia weighted averages, volume and air mass temperature = 75.39299 deg. F pressure = 26.59190 psia vapor pressure = 0.36080 psia volume = 1670000 cu. ft.

dry air mass = 220981.56 lbm

data set 55 time = 400 date = 1121 sensor raw data value temperature 1( 75.940 ) = 75.940 deg. F temperature 2( 76.030 ) = 76.030 deg. F temperature 3( 76.010 ) = 76.010 deg. F temperature 4 ( 76.290 ) = 76.290 deg. F temperature 5( 75.130 ) = 75.130 deg. F temperature 6( 75.430 ) = 75.430 deg. F temperature 7 ( 75.370 ) = 75.370 deg. F temperature 8 ( 76.270 ) = 76.270 deg. F temperature 9( 76.210 ) = 76.210 deg. F temperature 10 ( 75.410 ) = 75.410 dag. F temperature 11 ( 76.430 ) = 76.430 deg. F temperature 12 ( 76.140 ) = 76.140 dag. F temperature 13 ( 77.020 ) = 77.020 deg. F temperature 14 ( 64.190 ) = 64.190 deg. F temperature 15 ( 76.120 ) = 76.120 deg. F temperature 16 ( 74.420 ) = 74.420 deg. F temperature 17 ( 74.320 ) = 74.320 deg. F temperature 18 ( 73.390 ) = 73.390 deg. F temperature 21 ( 82.690 ) = 82.690 deg. F .

temperature 22 ( 79.730 ) = 79.730 dag. F temperature 23 ( 76.720 ) = 76.720 deg. F temperature 24 ( 73.740 ) = 73.740 deg. F temperature 25 ( 74.030 ) = 74.030 deg. F temperature 26 ( 72.490 ) = 72.490 deg. F dewpoint 1 ( 70.930 ) = 70.930 deg. F, 0.3746 psia dewpoint 2 ( 70.760 ) = 70.760 deg. F , 0.3724 psia dewpoint 3 ( 71.240 ) = 71.240 deg. F, 0.3786 psia dewpoint 4 ( 70.870 ) = 70.870 deg. F , 0.3738 psia dewpoint 21 ( 64.660 ) = 64.660 deg. F , 0.3018 psia dewpoint 22 ( 64.120 ) = 64.120 deg. F , 0.2962 psia pressure 1 ( 26.5924 ) = 26.5924 psia pressure 2 ( 26.5958 ) = 26.5958 psia weighted averages, volume and air mass temperature = 75.39629 deg. F pressure = 26.59298 psia vapor pressure = 0.36103 psia volume = 1670000 cu. ft.

dry air mass = 220987.40 lbm

L- ,

i i

, data set 56 time =' 415 date = 1121 j

i sensor raw data value

'.t 1( 75.950 ) 75.950 deg. F

=

temperature temperature 2( 76.020 ) = 76.020 deg. F i I

4 temperature 3( 76.000 ) = 76.000 deg. F .

temperature 4( 76.300 ) = 76.300 deg.-F l

temperature 5( 75.150 ) = 75.150 deg. F l j temperature 6( 75.450 ) = 75.450 deg. F 'l

temperature 7 ( 75.460 ) = 75.460 deg. F l temperature 8 ( 76.300 ) = 76.300 dag. F '

! -temperature 9( 76.230 ) = 76.230 deg. F temperature 10 ( 75.410 ) = 75.410 deg. F temperature 11 ( 76.440 ) = 76.440 deg. F temperature 12 ( 76.140 ) = 76.140 deg. F j temperature 13 ( 77.040 ) = 77.040 dag. F

! temperature 14 ( 64.240 ) = 64.240 deg. F l

temperature 15 ( 76.060 ) = 76.060 deg. F. i temperature 16 ( 74.460 ) = 74.460 deg.'F l

L temperature 17 ( 74.330 ) = 74.330 deg. F l temperature 18 ( 73.370 ) = 73.370 deg. F j i

temperature 21 ( 82.700 ) = 82.700 deg. F .

i temperature 22 ( 79.750 ) = 79.750 dag. F '

- temperature 23 ( 76.780 ) = 76.780-deg. F l j temperature 24 ( 73.680 ) = 73.680 deg. F i temperature 25 ( 74.110 ) = 74.110 deg. F

temperature 26 ( 72.500 ) = 72.500 deg. F a

dewpoint 1 ( 71.060 ) = 71.060 deg. F , 0.3763 psia i dewpoint 2 ( .70.790 ) = 70.790 deg. F , 0.3728 psia dewpoint 3 ( 71.250 ) = 71.250 deg. F , 0.3787 psia

dewpoint 4 ( 70.870 ) = 70.870 deg. F , 0.3738 psia dewpoint 21 ( 64.680 ) = 64.680 deg. F , 0.3021 psia dewpoint 22 ( 64.160 ) = 64.160 deg. F , 0.2966 psia l pressure 1 ( 26.5935 ) = 26.5935 psia pressure 2 ( 26.5968 )' = 26.5968 psia i

4 weighted averages, volume and air mass .

1 i

i

temperature = 75.40955 deg. F

' pressure = 26.59406 psia l vapor pressure = 0.36163 psia volume = 1670000 cu. ft.

dry air mass = 220986.01 lba t

4 7

4 4

i l

l e

data set 57 l l

time = 430 date = 1121 sensor raw data value temperature 1( 75.930 ) = 75.930 deg. F temperature 2 ( 75.960 ) = 75.960 deg. F temperature 3( 75.960 ) = 75.960 deg. F temperature 4 ( 76.250 ) = 76.250 deg. F temperature 5( 75.140 ) = 75.140 deg. F temperature 6( 75.380 ) = 75.380 deg. F temperature 7 ( 75.380 ) = 75.380 deg. F temperature 8 ( 76.320 ) = 76.320 deg. F temperature 9 ( 76.200 ) = 76.200 deg. F temperature 10 ( 75.440 ) = 75.440 deg. F temperature 11 ( 76.430 ) = 76.430 deg. F temperature 12 ( 76.120 ) = 70.120 deg. F temperature 13 ( 77.030 ) = 77.030 deg. F temperature 14 ( 64.240 ) = 64.240 deg. F temperature 15 ( 76.090 ) = 76.090 deg. F temperature 16 ( 74.470 ) = 74.470 deg. F temperature 17 ( 74.340 ) = 74.340 deg. F temperature 18 ( 73.360 ) = 73.360 deg. F temperature 21 ( 82.680 ) = 82.680 deg. F  ;

temperature 22 ( 79.770 ) = 79.770 deg. F temperature 23 ( 76.840 ) = 76.840 deg. F temperature 24 ( 73.750 ) = 73.750 deg. F temperature 25 ( 74.180 ) = 74.180 deg. F temperature 26 ( 72.540 ) = 72.540 deg. F dewpoint 1 ( 70.970 ) = 70.970 deg. F, 0.3751 psia dewpoint 2 ( 70.790 ) = 70.790 deg. F, 0.3728 psia dewpoint 3 ( 71.240 ) = 71.240 deg. F, 0.3786 psia dewpoint 4 ( 70.860 ) = 70.860 deg. F, 0.3737 psia dewpoint 21 ( 64.750 ) = 64.750 deg. F, 0.3028 psia dewpoint 22 ( 64.220 ) = 64.220 deg. F, 0.2972 psia pressure 1 ( 26.5941 ) = 26.5941 psia pressure 2 ( 26.5977 ) = 26.5977 psia weighted averages, volume and air mass temperature = 75.39756 deg. F pressure = 26.59472 psia j vapor pressure = 0.36142 psia j volume = 1670000 cu. ft.

dry air mass = 220998.21 lbm l 1

l 1

data set 58 time = 445 date = 1121 l

sensor raw data value temperature 1 ( 75.930 ) = 75.930 deg. F

temperature 2 ( 75.970 ) = 75.970 deg. F temperature 3 ( 75.900 ) = 75.900 deg. F temperature 4( 76.230 ) = 76.230 deg. F temperature 5( 75.170 ) = 75.170 deg. F temperature 6( 75.400 ) = 75.400 deg. F

< temperature 7 ( 75.380 ) = 75.380 deg. F temperature 8 ( 76.290 ) = 76.290 deg. F temperature 9( 76.200 ) = 76.200 deg. F temperature 10 ( 75.410 ) = 75.410 deg. F temperature 11 ( 76.430 ) = 76.430 deg. F temperature 12 ( 76.130 ) = 76.130 deg. F temperature 13 ( 77.030 ) = 77.030 deg. F 4

temperature 14 ( 64.280 ) = 64.280 deg. F temperature 15 ( 76.060 ) = 76.060 deg. F temperature 16 ( 74.450 ) = 74.450 deg. F temperature 17 ( 74.350 ) = 74.350 deg. F 1

temperature 18 ( 73.380 ) = 73.380 deg. F temperature 21 ( 82.710 ) = 82.710 deg. F .

temperature 22 ( 79.750 ) = 79.750 deg. F 4 temperature 23 ( 76.880 ) = 76.880 deg. F temperature 24 ( 73.790 ) = 73.790 deg. F temperature 25 ( 74.200 ) = 74.200 deg. F temperature 26 ( 72.580 ) = 72.580 deg. F dewpoint 1 ( 70.920 ) = 70.920 deg. F, 0.3745 psia l dewpoint 2 ( 70.810 ) = 70.810 deg. F, 0.3731 psia dewpoint 3 ( 71.270 ) = 71.270 deg. F, 0.3789 psia dewpoint 4 ( 70.860 ) = 70.860 deg. F , 0.3737 psia dewpoint 21 ( 64.810 ) = 64.810 deg. F , 0.3034 psia dewpoint 22 ( 64.280 ) = 64.280 deg. F, 0.2979 psia pressure 1 ( 26.5950 ) = 26.5950 psia pressure 2 ( 26.5986 ) = 26.5986 psia weighted averages, volume and air mass temperature = 75.39703 deg. F pressure = 26.59562 psia vapor pressure = 0.36150 psia volume = 1670000 cu. ft.

dry air mass = 221005.32 lbm l l

l l

l

w data set 59 time = 500 date = 1121 sensor raw data value temperature 1( 75.910 ) = 75.910 deg. F temperature 2 ( 75.930 ) = 75.930 deg. F temperature 3 ( 75.890 ) = 75.890 deg. F temperature 4( 76.190 ) = 76.190 deg. F temperature 5( 75.130 ) = 75.130 deg. F temperature 6( 75.290 ) = 75.290 deg. F temperature 7 ( 75.340 ) = 75.340 deg. F temperature 8 ( 76.250 ) = 76.250 deg. F temperature 9 ( 76.210 ) = 76.210 deg. F temperature 10 ( 75.380 ) = 75.380 deg. F temperature 11 ( 76.440 ) = 76.440 deg. F temperature 12 ( 76.120 ) = 76.120 deg. F temperature 13 ( 77.030 ) = 77.030 deg. F

. temperature 14 ( 64.310 ) = 64.310 deg. F temperature 15 ( 76.050 ) = 76.050 deg. F temperature 16 ( 74.480 ) = 74.480 deg. F temperature 17 ( 74.340 ) = 74.340 deg. F temperature 18 ( 73.390 ) = 73.390 dag. F temperature 21 ( 82.670 ) = 82.670 deg. F .

temperature 22 ( 79.770 ) = 79.770 dag. F temperature 23 ( 76.930 ) = 76.930 deg. F temperature 24 ( 73.840 ) = 73.840 deg. F temperature 25 ( 74.220 ) = 74.220 deg. F temperature 26 ( 72.610 ) = 72.610 deg. F dewpoint 1 ( 70.950 ) = 70.950 deg. F , 0.3749 psia dewpoint 2 ( 70.810 ) = 70.810 deg. F , 0.3731 psia dewpoint 3 ( 71.250 ) = 71.250 deg. F , 0.3787 psia dewpoint 4 ( 70.870 ) = 70.870 deg. F , 0.3738 psia dewpoint 21 ( 64.820 ) = 64.820 deg. F , 0.3035 psia dewpoint 22 ( 64.330 ) = 64.330 deg. F, 0.2984 psia pressure 1 ( 26.5959 ) = 26.5959 psia pressure 2 ( 26.5992 ) = 26.5992 psia  ;

1 weighted averages, volume and air mass temperature = 75.38286 deg. F l pressure = 26.59646 psia vapor pressure = 0.36167 psia volume = 1670000 cu. ft.

dry air mass = 221016.94 lbm

f o- o data set 60 i

time = 515 date = 1121 l~

I sensor raw data value temperature 1 ( 75.900 ) = 75.900 deg. F temperature 2 ( 75.970 ) = 75.970 deg. F l 75.890 deg. F temperature 3 ( 75.890 ) =

temperature 4 ( 76.320 ) = 76.320 deg. F temperature 5 ( 75.140 ) = 75.140 deg. F temperature- 6 ( 75.410 ) = 75.410 deg. F i temperature 7 (- 75.320 ) = 75.320 deg. F.

! temperature 8 ( 76.360 ) = 76.360 deg. F temperature 9 ( 76.200 ) = 76.200 deg. F i temperature 10 ( 75.460 ) = 75.460 deg. F temperature 11 ( 76.430 ) = 76.430 deg. F j

temperature 12.( 76.110 ) = 76.110 deg. F temperature 13 ( 77.020 ) = 77.020 deg. F

< temperature 14 ( 64.320 ) = 64.320 deg. F temperature 15 ( 76.060 ) = 76.060 deg. F temperature 16 ( 74.490 ) = 74.490 dag. F

< temperature 17 ( 74.350 ) = 74.350 dag. F temperature 18 ( 73.380 ) = 73.380 dag. F

, temperature 21 ( 82.650 ) = 82.650 dag. F  ;

temperature 22 ( 79.760 ) = 79.760 deg. F temperature 23 ( 76.940 ) = 76.940 deg. F ,

, temperature 24 ( 73.880 ) = 73.880 deg. F temperature 25 ( 74.210 ) = 74.210 deg. F temperature 26 ( 72.630 ) = 72.630 deg. F a dewpoint 1 ( 70.9?a ) = 70.980 dag. F , 0.3752 psia dewpoint 2 ( 70.81s ) = 70.810 deg. F , 0.3731 psia .

i dewpoint 3 ( 71.270 ) = 71.270 deg. F , 0.3789 psia 70.870 deg. F , 0.3738 psia j dewpoint 4 ( 70.870 ) =

l dewpoint 21 ( 64.920 ) = 64.920 deg. F , 0.3046 psia dewpoint 22 ( 64.380 ) = 64.380 deg. F , 0.2989 psia pressure 1 ( 26.5972 ) = 26.5972 psia pressure 2 ( 26.6006 ) = 26.6006 psia

)

weighted averages, volume and air mass temperature = 75.40979 deg. F pressure = 26.59778 psia vapor pressure = 0.36189 psia volume = 1670000 cu. ft.

dry air mass = 221015.08 lba pp

c data set 61 2

time = 530 date = 1121 sensor raw data value temperature 1 ( 75.920 ) = 75.920 deg. F temperature 2 ( 75.930 ) = 75.930 deg. F temperature 3 ( 75.940 ) = 75.940 deg. F temperature 4 ( 76.170 ) = 76.170 deg. F temperature 5 ( 75.120 ) = 75.120 deg. F 4

temperature 6 ( 75.400 ) = 75.400 deg. F

temperature 7 ( 75.370 ) = 75.370 deg. F temperature 8 ( 76.220 ) = 76.220 deg. F temperature 9 ( 76.160 ) = 76.160 deg. F temperature 10 ( 75.460 ) = 75.460 deg. F temperature 11 ( 76.390 ) = 76.390 deg. F temperature 12 ( 76.090 ) = 76.090 deg. F temperature 13 ( 77.040 ) = 77.040 deg. F temperature 14 ( 64.350 ) = 64.350 deg. F temperature 15 ( 76.050 ) = 76.050 deg. F

temperature 16 ( 74.500 ) = 74.500 deg. F temperature 17 ( 74.370 ) = 74.370 deg. F temperature 18 ( 73.390 ) = 73.390 deg. F temperature 21 ( 82.650 ) = 82.650 deg. F .

temperature 22 ( 79.780 ) = 79.780 deg. F temperature 23 ( 77.000 ) = 77.000 dag. F 1

temperature 24 ( 73.950 ) = 73.950 dag. F temperature 25 ( 74.270 ) = 74.270 deg. F temperature 26 ( 72.670 ) = 72.670 deg. F

< dewpoint 1 ( 71.010 ) = 71.010 deg. F , 0.3756 psia dewpoint 2 ( 70.840 ) = 70.840 deg. F, 0.3735 psia dewpoint 3 ( 71.260 ) = 71.260 deg. F, 0.3788 psia dewpoint 4 ( 70.880 ) = 70.880 dag. F , 0.3740 psia dewpoint 21 ( 64.970 ) = 64.970 deg. F , 0.3051 psia dewpoint 22 ( 64.400 ) = 64.400 deg. F , 0.2991 psia pressure 1 ( 26.5983 ) = 26.5983 psia pressure 2 ( 26.6018 ) = 26.6018 psia weighted averages, volume and air mass ,

temperature = 75.40395 deg. F I pressure = 26.59890 psia vapor pressure = 0.36212 psia volume = 1670000 cu. ft, dry air mass = 221024.90 lbm l

l

i 1

data set 62 1 time = 545 date = 1121 sensor raw data value e 75.900 deg. F

! temperature 1( 75.900 ) =

temperature 2 ( 75.960 ) = 75.960 dag. F l 75.920 deg. F j temperature 3 ( 75.920 ) =

76.250 deg. F

]

temperature 4 ( 76.250 ) =

75.130 deg. F temperature 5 ( 75.130 ) =

75.410 deg. F

temperature- 6( 75.410 ) =

temperature 7 ( 75.360 )

= 75.360 deg. F temperature 8 ( 76.250 ).

= 76.250 dag. F J temperature 9 ( 76.170 )

76.170 dag. F temperature 10-( ~75.520 ) = 75.520 deg. F j 76.410 deg. F temperature 11 ( 76.410 )

temperature 12 ( 76.100 ) = 76.100 deg. F temperature 13 ( 77.040;) = 77.040 deg. F l 64.380-deg. F temperature 14 ( _64.380 ) =

76.040 deg. F temperature 15'( .76.040 ) =

74.480 deg. F temperature 16 ( 74.480 ) =

74.360 deg. F temperature 17 ( 74.360 ) =

73.400 ) = 73.400 deg. F

!l

temperature 18 (

temperature 21 ( 82.680 ) = 82.680 dag. F  ;

temperature 22 ( 79.830 ) = 79.830 deg. F j- 77.060 ) 77.060 deg. F temperature 23 ( =

74.020 dag. F temperature 24 ( 74.020 ) =

temperature 25 ( 74.330 ) = 74.330 deg. F 2

temperature 26 ( 72.760 ) = 72.760 deg. F y

71.030 ) 71.030 deg. F 0.3759 psia dewpoint 1 (

= ,

4 dewpoint 2 ( 70.860 ) = 70.860 deg. F , 0.3737 psia 71.280 ) = 71.280 dag. F 0.3791 psia i dewpoint. 3 ( ,

70.910 ) 70.910 deg. F 0.3743 psia

dewpoint 4 (

=

F, 0.3059 psia i dewpoint 21 ( 65.040 ) = 65.040 dag.

64.480 ) = 64.480 deg. F, 0.3000 psia

dewpoint 22 (

pressure 1 ( 26.5999 ) = 26.5999 psia pressure 2 ( 26.6036 ) = 26.6036 psia weighted averages, volume and air mass l

- temperature = 75.42482 deg. F j pressure = 26.60053 psia vapor pressure = 0.36250 psia .

volume = 1670000 cu. ft.

dry air mass = 221026.88 lba l

l l

1 F l 5 I

• a I

data set 63 time = 600 date = 1121 sensor raw data value temperature 1 ( 75.900 ) = 75.900 deg. F temperature 2 ( 75.920 ) = 75.920 dag. F temperature 3 ( 75.870 ) = 75.870 deg. F temperature 4 ( 76.210 ) = 76.210 deg. F temperature 5 ( 75.190 ) = 75.190 deg. F temperature 6 ( 75.330 ) = 75.330 deg. F temperature 7 ( 75.420 ) = 75.420 deg. F temperature 8 ( 76.270 ) = 76.270 deg. F temperature 9 ( 76.170 ) = 76.170 deg. F temperature 10 ( 75.490 ) = 75.490 deg. F temperature 11 ( 76.420 ) = 76.420 deg. F temperature.12 ( 76.090 ) = 76.090 deg. F temperature 13 ( 77.070 ) = 77.070 deg. F temperature 14 ( 64.400 ) = 64.400 dag. F temperature 15 ( 76.040 ) = 76.040 deg. F temperature 16 ( 74.500 ) = 74.500 deg. F temperature 17 ( 74.370 ) = 74.370 dag. F temperature 18 ( 73.400 ) = 73.400 deg. F temperature 21 ( 82.630 ) = 82.630 deg. F .

temperature 22 ( 79.890 ) = 79.890 deg. F temperature 23 (. 77.120 ) = 77.120 deg. F temperature 24 ( 74.090 ) = 74.090 deg. F temperature 25 ( 74.430 ) = 74.430 deg. F temperature 26 ( 72.830') = 72.830 dag. F dowpoint 1 ( 70.980 ) = 70.980 deg. F , 0.3752 paia dewpoint 2 ( 70.860 ) = 70.860 deg. F , 0.3737 psia dewpoint 3 ( 71.330-) = 71.330 deg. F , 0.3797 psia dewpoint 4 ( 70.910 ) = 70.910 deg.-F., 0.3743 psia dewpoint 21 ( 65.090 ) = 65.090 deg. F , 0.3064 psia dev)oint 22 ( 64.550 ) = 64.550 dag. F , 0.3007 psia pressure 1 ( 26.6013 ) == 26.6013 psia pressure 2 ( 26.6049 ) 26.6049 psia weighted averages, volume and air mass temperature = 75.43169 deg. F pressure = 26.60192 psia vapor pressure = 0.36256, psia volume = 1670000 cu. ft.

dry air mass = 221035.15 lba

_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _-.______.___________.--._._____________________u

I' l

' data set 64 f

time = 615 date = 1121 l

sensor raw data value l temperature 1( 75.890 ) = 75.890 deg. F.

temperature 2( 75.970 ) = 75.970 deg. F temperature 3( 75.920 ) = 75.920 deg. F ,

! temperature 4 ( 76.260 ) = 76.260 deg. F  !

1 temperature 5 ( 75.110') = 75.110 deg. F

' temperature 6( 75.390 ) '= -75.390_deg. F .

temperature 7 ( 75.340 ) = 75.340 deg. F l i

temperature 8 ( 76.280 ) = 76.280 deg. F l temperature 9 '( 76.160 ) = 76.160 deg. .F i temperature 10 ( 75.520 ) = 75.520 deg. F temperature 11 ( 76.450 ) = 76.450 deg. F temperature 12 ( 76.100 ) = 76.100 deg. F temperature 13 ( 77.060.) = 77.060 deg. F j temperature 14 ( 64.420 ) = 64.420 deg. .F temperature 15 ( 76.060 ) = 76.060 deg. F 1 temperature 16 ( 74.470 ) = 74.470 deg. F temperature 17 ( 74.380 ) = 74.380 deg. F temperature 18 ( 73.400 ) = 73.400 deg. F temperature 21 ( 82.670 ) = 82.670 deg. F .

temperature 22 ( 79.960 ) = 79.960 deg. F temperature 23 ( 77.160 ) = 77.160 deg. F 74.150 ) = 74.150 dag. F temperature 24 (

l temperature 25 ( 74.490 ) = 74.490 deg. F temperature 26 ( 72.920 ) = 72.920 deg. F l

l dewpoint 1 ( 71.060 ) = 71.060 deg. F , 0.3763 psia

dewpoint 2 ( 70.870 ) = 70.870 deg. F ,.0.3738 psia

dewpoint 3 ( 71.300 ) = 71.300 deg. F, 0.3793 psia i dewpoint 4 ( 70.910 ) = 70.910 deg. F, 0.3743 psia dewpoint 21 ( 65.190 ) = 65.190 deg. F , 0.3075 psia dewpoint 22 ( 64.590 ) = 64.590 deg. F, 0.3011' psia

! pressure 1 ( 26.6028 ) = 26.6028 psia i

pressure 2 ( 26.6064 ) = 26.6064 psia weighted averages, volume and air mass i temperature = 75.44972 deg. F 1 pressure = 26.60341 psia I vapor pressure = 0.36286 psia l volume = 1670000 cu. ft. l dry air mass = 221037.81 lba i i 4

I - - . .

- _ .__ _ _ _ .- . . _ . - ~ _ . . - . _ . . . .. . _ _ _ _ . . . . _ . _

a data set 65 time = 630 date = 1121 sensor raw data value temperature 1( 75.900 ) = 75.900 deg. F temperature 2 ( 75.970 ) = 75.970 deg. F temperature 3 ( 75.940 ) = 75.940 dag. F temperature 4 ( 76.260 ) = 76.260 deg. F temperature 5 ( 75.080 ) = 75.080-deg. F temperature 6 ( 75.400 ) = 75.400 deg. F temperature 7( 75.370 ) = 75.370 deg. F temperature 8( 76.170 ) = 76.170 deg. F temperature 9( 76.150 ) = 76.150 deg. F temperature 10-( 75.480 ) =- 75.480 deg. F temperature 11 ( 76.410 ) = 76.410 dag. F temperature 12 ( 76.100 ) = 76.100 deg. F temperature 13 ( 77.050 ) = 77.050 deg. F temperature 14 ( 64.460 ) = 64.460 deg. F tempatature 15 ( 76.020 ) = 76.020 deg. F temperature 16 ( 74.500 ) = 74.500 deg. F temperature 17 ( 74.380 ) = 74.380 deg. F temperature 18 ( 73.400 ) = 73.400 deg. F temperature 21 ( 82.640 ) = 82.640 deg. F ,

temperature 22 ( 80.080 ) = 80.080 dag. F temperature 23 ( 77.260 ) = 77.260 deg..F temperature 24 ( 74.240 ) = 74.240 deg. F temperature 25 ( 74.540 ) = 74.540 deg. F temperature 26 ( 73.010 ) = 73.010 deg. F  !

dewpoint 1 ( 71.070 ) = 71.070 deg. F , 0.3764 psia dewpoint 2 ( 70.890 ) = 70.890 dag. F , 0.3741 psia dewpoint 3 ( 71.340 ) = 71.340 deg. F, 0.3798 psia dewpoint 4 ( 70.930 ) = 70.930.deg. F ,-0.3746 psia dewpoint 21 ( 65.190 ) = 65.190 dag. F , 0.3075 psia dewpoint 22 ( 64.650 ) = 64.650 deg. F , 0.3017 psia pressure 1 ( 26.6041 ) = 26.6041 psia pressure 2 ( 26.6076 ) = 26.6076 psia weighted averages, volume and air mass temperature = 75.46149 dag. F pressure = 26.60470 psia vapor pressure = 0.36319 psia volume = 1670000 cu. ft.

dry air mass = 221041.01-lba

j, e

t data set 66 I time = 645 date = 1121

! sensor raw data value I;

J temperature 1 ( 75.870 ) = 75.870 deg. F j temperature 2 ( 75.920 ) = 75.920 deg. F 75.890 ) 75.890 deg..F

=

temperature 3 -(

4 temperature 4-( 76.180 )- = 76.180 deg. F temperature 5 ( 75.100 ) = 75.100 deg. F temperature 6 ( 75.390 ) = 75.390 deg. F temperature 7 ( 75.350 ) = 75.350.dag. F temperature 8 -( 76.210 ) = 76.210 deg. F

{ temperature 9 ( 76.150 ) = 76.150 deg. F j temperature 10 ( 75.500 ) = 75.500 deg. F temperature.11 ( 76.420 ) = 76.420'deg. F j temperature 12 (' 76.080 ) = 76.080 deg. F j- temperature 13'( 77.050 ) = 77.050 deg. F

temperature 14 ( 64.480 ) =- 64.480 deg. F j temperature 15 ( 76.030 ) = 76.030 deg. F j temperature 16 ( 74.500') = 74.500 deg. F j temperature 17 ( 74.390 ) = 74.390 dag. F temperature.18 ( 73.410 ) = 73.410 deg. F 82.640 )

{ temperature 21 ( = 82.640 dag. F ,

j temperature 22 ( 80.190 ) u 80.190 deg. F  ?

temperature 23 ( 77.280 ) = 77.280 deg. F temperature 24 ( 74.180 ) = 74.180.deg. F

temperature-25 ( 74.620 ) = 74.620.deg. F' temperature 26 ( 73.070 ) = 73.070 dag. F

dewpoint 1 ( 71.060 ) = 71.060 deg. F , 0.3763 psia dewpoint 2 ( 70.890 ) = 70.890 dag. F , 0.3741 psia i dewpoint 3 ( 71.320 ) = 71.320 dag. F , 0.3796 psia dewpoint 4 ( 70.930 ) = 70.930 deg. F , 0.3746 psia dewpoint 21 ( 65.230 ) = 65.230 deg. F , 0.3079 psia

! dewpoint 22 ( 64.700 ) = 64.700 deg. F , 0.3023 psia  ;

i

! pressure 1 ( 26.6051 ) == 26.6051 psia pressure 2 ( 26.6086 ) 26.6086 psia weighted averages, volume and air mass

temperature = 75.45629 deg. F

pressure = 26.60570 psia

vapor pressure = 0.36321 psia volume = '1670000 cu. ft.

dry air mass = 221051.41 lba

. - - .. - _. -_..~.. . . . . . - - . . . . - . . . . . .

! 1

! I 9

data set 67 J

! time = 700 date = 1121 sensor raw data value l

temperature 1( 75.880 ) = 75.880 deg. F l temperature 2( 75.890 ) = 75.890 deg. F l temperature 3( 75.870 ) = 75.870 deg. F temperature 4 ( 76.150 ) = 76.150 dag. F j temperature 5 ( 75.110 ) = 75.110 deg. F i I

temperature 6 ( 75.310 ) = 75.310 dag. F temperature 7 ( .75.300 ) = 75.300 deg. F  !

temperature 8 ( 76.150 ) = 76.150 deg. F temperature 9 ( 76.110 ) = 76.110 deg. F temperature 10 ( 75.530 ) = 75.530 deg. F temperature 11 ( 76.410 ) = 76.410 deg. F-temperature 12 ( 76.050 ) = 76.050 deg. F.

temperature 13 ( 77.050 ) = 77.050 deg. F temperature 14 ( 64.510.) = 64.510 deg. F temperature 15 ( 76.010 ) = 76.010 deg. F temperature 16 ( 74.510-) = 74.510 deg. F temperature 17 ( 74.370 ) = 74.370 deg.' F ,

temperature 18 ( 73.380 ) = 73.380 deg. F temperature 21 ( 82.690 ) = 82.690 deg. F .

temperature 22 ( 80.260 ) = 80.260 deg. F temperature 23 ( 77.300 ) = 77.300 deg. F temperature 24 ( 74.250 ) = 74.250 deg. F-temperature 25 ( 74.6P,0 ) = 74.650 deg. F temperature 26 ( 73.120 ) = 73.120 deg. F dewpoint 1 ( 71.110 ) = 71.110 dag. F , 0.3769 psia dewpoint 2 ( 70.880 ) = 70.880 deg. F , 0.3740 psia dewpoint 3 ( 71.300 ) = 71.300 deg. F , 0.3793 psia dewpoint 4 ( 70.940 ) = 70.940 deg. F , 0.3747 psia dewpoint 21 ( 65.260 ) = 65.260 deg. F., 0.3082 psia dewpoint 22 ( 64.760 ) = 64.760 deg. F , 0.3029 psia pressure 1 ( 26.6058 ) == 26.6058 psia pressure 2 ( 26.6094 ) 26.6094 psia i

weighted averages, volume and air mass temperature = 75.44662 deg. F pressure = 26.60642 psia vapor pressure = 0.36342 psia volume = 1670000 cu. ft.

dry air mass = 221059.69 lbm I

.- . . ._- _- -.-. .~ .. _ . - -- -- -. - . _ - . . .~. . . . .

l i,

l e i

) i I. data set 68 i

l time = 715 date = 1121 1

sensor raw data value temperature 1( 75.830 ) = .75.830 deg. F

] temperature 2 ( 75.880 ) = 75.880'deg. F

temperature 3( 75.820 ) = 75.820 dag. F

temperature 4 ( 76.060 ) = 76.060 deg. F

! temperature 5( 75.120 ) = 75.120 deg. F i . temperature 6( 75.250 ) = 75.250 dag. F j temperature 7 ( 75.360 ) = 75.360 deg. F j temperature 8( 76.180 ). = 76.180 deg. F j temperature 9( 76.090 ) = 76.090 dag. F

]

temperature 10 ( 75.520 ) = 75.520 deg. F.

j temperature 11 ( 76.410 ) = 76.410 deg. F j temperature 12 ( 76.050 ) = 76.050 deg. F

] temperature 13 ( 77.050 ) = 77.050 dag. F l temperature 14 ( 64.530 ) = 64.530 deg. F j temperature 15 ( 76.000 ) = 76.000 dag..F l temperature 16 ( 74.500 )' = .74.500 deg. F

temperature 17 ( 74.390 ) = 74.390 dag. F

{

temperature 18 ( 73.390-) *= 73.390 deg. F j temperature 21 ( 82.650 ) = 82.650 dag.'F  ;

i temperature 22 ( 80.330 ) = 80.330'deg. F j temperature 23 ( 77.350 ) = 77.350 deg. F temperature 24 ( 74.300 ) = 74.300 deg. F

. temperature 25 ( 74.700 ) = 74.700 dag.'F temperature 26 ( 73.150 ) = 73.150 dag. F dewpoint 1 ( 71.070 ) = 71.070 dag. F , 0.3764 psia j dewpoint 2 ( 70.890 ) = 70.890 deg. F , 0.3741 psia i dewpoint 3 ( 71.310 ) = 71.310 deg. F ,'O.3795 psia dewpoint 4 ( 70.920 ) = 70.920 deg. F , 0.3745 psia 4 dewpoint 21 ( 65.320 ) = 65.320 deg. F ,.0.3089 psia dewpoint 22 ( 64.790 ) = 64.790 deg. F , 0.3032 psia l

i l

pressure 1 ( 26.6065 ) == 26.6065 psia t pressure 2 ( 26.6100 ) 26.6100 psia weighted averages, volume.and air mass i temperature = 75.44225 deg. F

pressure = 26.60710 psia j vapor pressure = 0.36336 psia volume = 1670000 cu. ft. ,

, dry air mass = 221067.70 lba l 1

i l

I s

1

4 i .-

A data set 69 time = 730 date = 1121 sensor raw data value

temperature 1( 75.860 ) = 75.860 deg. F l

temperature 2( 75.880 ) = 75.880 deg. F

, temperature 3( 75.850 ) = 75.850 deg. F temperature 4( 76.070 ) = 76.070 dag. F temperature 5( 75.090 ) = 75.090 dag. F i temperature 6( 75.190 ) = 75.190 deg. F temperature 7( 75.320 ) = 75.320 deg. F temperature 8( 76.180 ) = 76.180 deg. F temperature 9 ( 76.110 ) = 76.110 deg. F temperature 10 ( 75.460 ) = 75.460 deg. F temperature 11 ( 76.410 ) = 76.410 deg. F temperature 12 ( 76.040 ) = 76.040 deg._F temperature 13 ( 77.060 ) = 77.060 deg. F temperature 14 ( 64.560 ) = 64.560 deg. F temperature 15 ( 76.020 ) = 76.020_deg. F temperature 16 ( 74.500 ) = 74.500 deg. F temperature 17 ( 74.380 ) = 74.380 deg. F temperature 18 ( 73.390 ) = 73.390 deg. F temperature 21 ( 82.630 ) = 82.630 deg. F .

temperature 22 ( 80.350 ) = 80.350 deg. F temperature 23 ( 77.390 ) = 77.390 deg. F temperature 24 ( 74.350-) = 74.350 deg. F temperature 25 ( 74.720 ) = 74.720 deg. F temperature 26 ( 73.170 ) = 73.170 deg. F dewpoint 1 ( 71.060 ) = 71.060 deg. F , 0.3763 psia dewpoint 2 ( 70.900 ) = 70.900 deg. F , 0.3742 psia dewpoint 3 ( 71.320 ) = 71.320 deg. F , 0.3796 psia dewpoint 4 ( 70.940 ) = 70.940 deg. F , 0.3747 psia dewpoint 21 ( 65.400 ) = 65.400 deg. F , 0.3097 psia dewpoint 22 ( 64.850 ) = 64.850 deg. F, 0.3039 psia pressure 1 ( 26.6071 ) = 26.6071 psia pressure 2 ( 26.6108 ) = 26.6108 psia weighted averages, volume and air. mass temperature = 75.44442 deg. F pressure = 26.60773 psia vapor pressure =- 0.36354 psia volume = 1670000 cu.- ft.

dry air mass = '221070.69 lba

i 1

• e data set 70 time = 745 date = 1121 sensor raw data value temperature 1( 75.860 ) = 75.860 deg. F )

temperature 2( 75.870 ) = 75.870 deg. F  :

temperature 3( 75.840 ) = 75.840 deg. F l temperature 4 ( 76.070 ) = 76.070 deg. F l 75.030 ) 75.030 deg. F temperature 5( =

temperature 6( 75.270 ) = 75.270 deg. F temperature 7( 75.250 ) = 75.250 deg. F temperature 8 ( 76.090 ) = 76.090 deg. F

. temperature 9 ( 76.090 ) = 76.090 deg. F temperature 10 ( 75.490 ) = 75.490 dag. F i temperature 11 ( 76.440 ) = 76.440 deg. F temperature 12 ( 76.030 ) = 76.030 deg. F temperature 13 ( 77.030 ) = 77.030 deg. F temperature 14 ( 64.580 ) = 64.580 deg. F temperature 15 ( 75.970 ) = 75.970 deg. F

. temperature 16 ( 74.500 ) = 74.500 deg. F temperature 17 ( 74.350 ) = 74.350 deg. F temperature 18 ( 73.380 ) = 73.380 deg. F temperature 21 ( 82.660 ) = 82.660 deg. F .

temperature 22 ( 80.370 ) = 80.370 dag. F temperature 23 ( 77.430 ) = 77.430 deg. F

temperature 24 ( 74.390 ) = 74.390 deg. F

' temperature 25 ( 74.780 ) = 74.780 deg. F 4 temperature 26 ( 73.200 ) , 73.200 deg. F dewpoint 1 ( 71.090 ) = 71. 090 dag. T/ , 0.3766 psia dewpoint 2 ( 70.890 ) = 70.890 deg. F , 0.3741 psia dewpoint 3 ( 71.330 ) = 71.330 deg. F , 0.3797 psia j dewpoint 4 ( 70.930 ) = 70.930 deg. F , 0.3746 psia dewpoint 21 ( 65.440 ) = 65.440 deg. F , 0.3102 psia-dewpoint 22 ( 64.900 ) = 64.900 deg. F , 0.3044 psia pressure 1 ( 26.6076 ) = 26.6076 psia pressure 2 ( 26.6113 ) = 26.6113 psia weighted averages, volume and air mass temperature = 75.43932 deg. F pressure = 26.60823 psia vapor pressure = 0.36368 psia volume = 1670000 cu. ft.

dry air mass = 221075.76 lbm f

• . e data set 71 )

time = 800 date = 1121  ;

sensor raw data value temperature 1( 75.810 ) = 75.810 dag. F temperature 2( 75.880 ) = 75.880 deg. F temperature 3( 75.850 ) = 75.850 deg. F temperature 4( 76.040 ) = 76.040 deg. F temperature 5( 75.040 ) = 75.040 deg. F temperature 6 ( 75.220 ) = 75.220 deg. F temperature 7( 75.300 ) = 75.300 dag. F temperature 8( 76.230 ) = 76.230 deg. F temperature 9( 76.120 ) = 76.120 deg. F temperature 10 ( 75.490 ) = 75.490 deg. F temperature 11 ( 76.460 ) = 76.460 dag. F temperature 12 ( 76.040 ) = 76.040 deg. F temperature 13 ( 77.030 ) = 77.030 deg. F temperature 14 ( 64.600 ) = 64.600 deg. F temperature 15 ( 75.970 ) = 75.970 dag. F temperature 16 ( 74.480 ) = 74.480 deg. F temperature 17 ( 74.390 ) = 74.390 deg.-F t

temperature 18 ( 73.380 ) = 73.380 dag. F temperature 21 ( 82.680 ) = 82.680'deg. F ,

temperature 22 ( 80.390 ) = 80.390 deg. F temperature 23 ( 77.490 ) = 77.490 deg. F temperature 24 ( 74.420 ) = 74.420 deg. F temperature 25 ( 74.790 ) = 74.790 deg. F.

temperature 26 ( 73.200 ) = 73.200 deg. F ,

dewpoint 1 ( 71.090 ) = 71.090 deg. F , 0.3766 psia dewpoint 2 ( 70.910 ) = 70.910 deg. F , 0.3743 psia dewpoint 3 ( 71.360 ) = 71.360 deg. F , 0.3801 psia dewpoint 4 ( 70.950 ) = 70.950 deg. F , 0.3749 psia dewpoint 21 ( 65.500-) = 65.500 deg. F , 0.3108 psia '

dewpoint 22 ( 64.940 ) = 64.940 deg. F , 0.3048 psia pressure 1 ( 26.6082 ) = 26.6082 psia pressure 2 ( 26.6119 ) = 26.6119 psia weighted averages, volume and air mass temperature = 75.44839 deg. F pressure = 26.60883 psia vapor pressure = 0.36392 psia volume = 1670000 cu. ft, dry air mass = 221075.04 lba I

4

---

_,__._,y- .

, , _ , . ,r,-,_-,,, , , . -, , , , , _

,_ _ _ _ __ _ _ = _ __ _

l r-, ,

a data set 72 l 'l time = 815 date = 1121 l J 1 2

I sensor raw data value

! temperature 1( 75.830 ) = 75.830 dag. F

! temperature 2' ( 75.890 ) = 75.890 dag. F

temperature 3( 75.820 ) = 75.820 dag. F 1, temperature 4( 76.170 ) = 76.170 deg. F l j temperature 5( 75.020 ) = 75.020 dag. F temperature 6 ( 75.270 ) = 75.270 deg. F j temperature 7 ( 75.220 ) = 75.220 dag. F temperature 8 ( 76.110 ) = 76.110 deg. F J temperature 9 ( 76.110 ) = 76.110 deg. F

temperature 10 ( 75.500 ) = 75.500 dag. F

temperature 11 ( 76.470 ) = 76.470 deg. F temperature 12 ( 76.040 ) = 76.040 dag. F j temperature 13 ( 77.000 ) = 77.000 deg. F i temperature 14 ( 64.620 ) = 64.620 deg. F j temperature 15 ( 75.980 ) = 75.980 deg. F

temperature 16 ( 74.500 ) = 74.500 deg. F l temperature 17 ( 74.380 ) = 74.380 deg..F

temperature 18 ( 73.390 ) = 73.390 deg. F

temperature 21 ( 82.670 ) = 82.670 deg. F ,

L temperature 22 ( 80.400 }- = 80.400 dag. F

{ temperature 23 ( 77.510 ) = 77.510 deg. F

temperature 24 ( 74.480 ) = 74.480 dag. F i temperature 25 ( 74.800 ) = 74.800 deg. F j temperature 26 ( 73.220 ) = 73.220 deg. F

dewpoint 1 ( 71.150 ) = 71.150 deg. F , 0.3774 psia j dewpoint 2 ( 70.940 ) = 70.940 deg. F , 0.3747 psia

dewpoint 3 ( 71.370 ) = 71.370 dag. F , 0.3802 psia

dewpoint 4 ( 70.940 ) = 70.940 deg. F , 0.3747 psia l dewpoint 21 ( 65.530 ) = 65.530 deg. F , 0.3111 psia j dewpoint 22 ( 65.010 ) = 65.010 deg. F , 0.3056 psia' l pressure 1 ( 26.6089 ) = 26.6089 psia g

pressure 2 ( 26.6124 ) = 26.6124 psia

weighted averages, volume and air mass i temperature = .75.45599 deg. F pressure = 26.60950 psia vapor pressure = 0.36434 psia

, volume = 1670000 cu. ft.

dry air mass = 221073.98 lba 1

3 i

1 l

j J

data set 73 time = 830 date = 1121 sensor raw data value temperature 1 ( 75.810 ) = 75.810 deg. F ,

temperature 2 ( 75.880 ) = 75.880 dag. F

temperature 3 ( 75.820 ) = 75.820 deg. F

temperature 4 ( 76.170 ) = 76.170 deg. F

temperature 5 ( 75.070 ) = 75.070 deg. F J temperature 6 ( 75.310 ) = 75.310.deg. F

temperature 7 ( 75.260 ) = 75.260 deg. F j temperature 8 ( 76.180 ) = 76.180 deg. F i temperature 9 ( 76.110 ) = 76.110 deg. F l

temperature 10 ( 75.490 ) = 75.490 dag. -

F

- temperature 11 ( 76.420 ) = 76.420 dag. F j temperature 12 ( 76.040-) = 76.040 dag. F J temperature 13 ( 76.990 ) = 76.990 deg. F-

temperature 14.( 64.650 ) = 64.650 dag. F i temperature 15 ( 75.950 ) = 75.950 deg. F temperature 16 ( 74.470 ) = 74.470 dag. F temperature 17 ( 74.380 ) = 74.380 deg. F 1 temperature 18 ( 73.390 ) = 73.390 deg. F temperature 21 ( 82.620 ) = 82.620 deg. F .

temperature 22 ( 80.370 ) = 80.370 deg. F j temperature 23 ( 77.520 ) = 77.520 deg. F

! temperature 24 ( 74.500 ) = 74.500 dag. F

! temperature 25 ( 74.830 ) = 74.830 dag. F temperature 26 ( 73.220 ) = 73.220 deg. F dewpoint 1 ( 71.150 ) = 71.150 dag. F, 0.3774 psia dewpoint 2 ( 70.940 ) = 70.940 dag. F , 0.3747 psia dewpoint 3 ( 71.380 ) = 71.380 dag. F , 0.3804 psia j dewpoint 4 ( 70.960 ) = 70.960 deg. F , 0.3750 psia-

dewpoint 21 ( 65.670 ) = 65.670 deg. F , 0.3127 psia j dewpoint 22 ( 65.040 ) = 65.040 deg. F , 0.3059 psia f

i pressure 1 ( 26.6095 ) == 26.6095 psia

! pressure 2 ( 26.6131 ) 26.6131 psia i weighted averages, volume and air mass i

i temperature = */5.46176 dag. F i pressure = 26.61012 psia vapor pressure = 0.36446 psia volume = 1670000 cu. ft.

dry air mass = 221075.85 lba i-n . - < - . - .

j o , i k

1 I data set 74 4 time = 845 date = 1121 4

sensor raw data value

temperature 1 ( 75.810 ) = 75.810 deg. F temperature 2 ( 75.860 ) = 75.860 deg. F

temperature 3 ( 75.850 ) = 75.850 deg. F

temperature 4 ( 76.130 ) = 76.130 deg. F temperature 5 ( 75.020 ) = 75.020 deg. F temperature 6 ( 75.310 ) = 75.310 deg. F

temperature 7 ( 75.300 ) = 75.300 deg. F

! temperature 8 -( 76.160 ) = 76.160 deg. F temperature 9 ( 76.120 ) = 76.120 deg. F

temperature 10 ( 75.500 ) = 75.500 deg. F r d

temperature 11 ( 76.390 ) = 76.390 deg. F temperature 12 ( 76.040 ) = 76.040 dag. F-1 temperature 13 ( 76.980 )- = 76.980 deg. F temperature 14 ( 64.660 ) = 64.660 deg. F '

- temperature.15 ( 76.000 ) = 76.000 dag. F temperature 16 ( 74.490 ) = 74.490 dag. F temperature 17 ( 74.370 ) = 74.370 deg. F

temperature 18 ( 73.390 ) = 73.390 deg. F l temperature 21 ( 82.600 ) = 82.600 deg. F  ;

80.350 )

temperature.22 ( = 80.350 deg. F temperature 23 ( 77.590 ) = 77.590 deg. F l temperature 24 ( 74.540.) = 74.540 deg. F

]

temperature 25 ( 74.830 ) = 74.830 deg. F i temperature 26 ( 73.240 ) = 73.240 deg. F i

l dewpoint 1 ( 71.150 ) = 71.150 dag. F, 0.3774 psia

dewpoint 2 ( 70.950 ) = 70.950 dag. F, 0.3749 psia 4 dewpoint 3 ( 71.380 ). = 71.380 dag. F., 0.3804 psia dewpoint 4 ( 70.960 ) = 70.960 deg. F , 0.3750 psia l dewpoint 21 ( 65.710 ) = 65.710 deg. F , 0.3131 psia dewpoint 22 ( 65.090 ) = 65.090 deg.'F , 0.3064 psia pressure 1 ( 26.6104 ) = 26.6104 psia 4 pressure 2 ( 26.6139 ) = 26.6139 psia weighted averages, volume and air mass

! temperature = 75.46319 deg. F

! pressure = 26.61100 psia i vapor pressure = 0.36459 psia

volume = 1670000 cu. ft.

~

dry air mass = 221081.61 lba 1

]

i 1

, a

O >

data set 75 time = 900 date = 1121 sensor raw data value J temperature 1( 75.820 ) = 75.820 deg. F j temperature 2 ( 75.850 ) = 75.850 deg. F temperature 3 ( 75.810 ) = 75.810 deg. F temperature 4( 76.050 ) = 76.050 deg. F temperature 5( 75.000 ) = 75.000 deg. F temperature 6( 75.270 ) = 75.270 deg. F temperature 7 ( 75.250 ) = 75.250 deg. F temperature 8( 76.090 ) = 76.090 deg. F temperature 9( 76.090 ) = 76.090 deg. F temperature 10 ( 75.510 ) = 75.510 deg. F temperature 11 ( 76.390 ) = 76.390 deg. F temperature 12 ( 76.010 ) = 76.010 deg. F temperature 13 ( 76.990 ) = 76.990 deg. F temperature 14 ( 64.680 ) = 64.680 deg. F temperature 15 ( 76.040 ) = 76.040 deg. F temperature 16 ( 74.490 ) = 74.490 deg. F temperature 17 ( 74.390 ) = 74.390 deg. F temperature 18 ( 73.400 ) = 73.400 deg. F temperature 21 ( 82.610 ) = 82.610 deg. F ,

temperature 22 ( 80.370 ) = 80.370 deg. F temperature 23 ( 77.610 ) = 77.610 deg. F temperature 24 ( 74.600 ) = 74.600 deg. F

! temperature 25 ( 74.840 ) = 74.840 deg. F temperature 26 ( 73.250 ) = 73.250 deg. F dewpoint 1 ( 71.190 ) = 71.190 deg. F , 0.3779 psia dewpoint 2 ( 70.960 ) = 70.960 deg. F , 0.3750 psia dewpoint 3 ( 71.380 ) = 71.380 deg. F, 0.3804 psia dewpoint 4 ( 70.970 ) = 70.970 deg. F , 0.3751 psia dewpoint 21 ( 65.690 ) = 65.690 deg. F, 0.3129 psia dewpoint 22 ( 65.140 ) = 65.140 deg. F , 0.3069 psia

pressure 1 ( 26.6112 ) == 26.6112 psia pressure 2 ( 26.6147 ) 26.6147 psia

. weighted averages, volume and air mass temperature = 75.45069 deg. F pressure = 26.61180 psia i vapor pressure = 0.36486 psia volume = 1670000 cu. ft.

dry air mass = 221091.22 lba

O r data set 76 time = 915 date = 1121 ,

1 sensor raw data value j temperature 1( 75.790 ) = 75.790 deg. F temperature 2( 75.830 ) = 75.830 deg. F temperature 3( 75.800 ) = 75.800 deg. F temperature 4( 76.020 ) = 76.020 deg. F temperature 5( 75.040 ) = 75.040 deg. F temperature 6( 75.190 ) = 75.190 deg. F temperature 7( 75.270 ) = 75.270 deg. F )

temperature 8( 76.160 ) = 76.160 deg. F 1 temperature 9( 76.070 ) = 76.070 deg. F temperature 10 ( 75.470 ) = 75.470 deg. F temperature 11 ( 76.410 ) = 76.410 deg. F temperature 12 ( 76.000 ) = 76.000 deg. F temperature 13 ( 76.970 ) = 76.970 deg. F temperature 14 ( 64.720 ) = 64.720 deg. F temperature 15 ( 75.940 ) = 75.940 deg. F temperature 16 ( 74.490 ) = 74.490 deg. F temperature 17 ( 74.390 ) = 74.390 deg. F temperature 18 ( 73.390 ) = 73.390 deg. F temperature 21 ( 82.540 ) = 82.540 deg. F temperature 22 ( 80.340 ) = 80.340 deg. F i temperature 23 ( 77.640 ) = 77.640 deg. F temperature 24 ( 74.650 ) = 74.650 deg. F temperature 25 ( 74.910 ) = 74.910 deg. F temperature 26 ( 73.280 ) = 73.280 deg. F dewpoint 1 ( 71.180 ) = 71.180 deg. F, 0.3778 psia dewpoint 2 ( 70.950 ) = 70.950 deg. F , 0.3749 psia dewpoint 3 ( 71.400 ) = 71.400 deg. F , 0.3806 psia dewpoint 4 ( 70.970 ) = 70.970 deg. F , 0.3751 psia dewpoint 21 ( 65.890 ) = 65.890 deg. F, 0.3151 psia dewpoint 22 ( 65.180 ) = 65.180 deg. F , 0.3074 psia pressure 1 ( 26.6120 ) = 26.6120 psia pressure 2 ( 26.6157 ) = 26.6157 psia weighted averages, volume and air mass temperature = 75.44502 deg. F pressure = 26.61263 psia vapor pressure = 0.36490 psia volume = 1670000 cu. ft.

dry air mass = 221100.23 lbm

I* ,

I 4

data set 77 j

j time = 930 date = 1121 sensor raw data value i temperature 1( 75.800 ) = 75.800 deg. F j temperature 2( 75.860 ) = 75.860 deg. F

temperature 3( 75.800 ) = 75.800 deg. F j temperature 4( 76.060 ) = 76.060 deg. F 5( 75.000 )

temperature = 75.000 deg. F i temperature 6( 75.250 ) = 75.250 deg. F l temperature 7( 75.220 ) = 75.220 deg. F temperature 8 ( 76.120 ) = 76.120 deg. F temperature 9-( 76.090 ) = 76.090 deg. F

] temperature 10 ( 75.550 ) = 75.550 deg. F l temperature 11 ( 76.360 ) = 76.360 deg. F

! temperature 12 ( 76.000 ) = 76.000 deg. F

temperature 13 ( 76.990 ) = 76.990 deg. F i temperature 14 ( 64.740 ) = 64.740 deg. F

temperature 15 ( 76.030 ) = 76.030 deg. F i temperature 16 ( 74.480 ) = 74.480 deg. F

! temperature 17 ( 74.370 ) = 74.370 deg. F

temperature 18 ( 73.400 ) = 73.400 deg. F

temperature 21 ( 82.600 ) = 82.600 dag.,F .

temperature 22 ( _80.340 ) = 80.340 deg. F

] temperature 23 ( 77.670 ) = 77.670 deg. F

temperature 24 ( 74.570 ) = 74.570 deg. F

temperature 25 ( 74.940 ) = 74.940 dag. F

temperature 26 ( 73.350 ) = 73.350 deg. F 1 -

dewpoint 1 ( 71.200 ) = 71.200 deg. F , 0.3780 psia l dewpoint 2 ( 71.000 ) = 71.000 deg. F , 0.3755 psia  !

J dewpoint 3 ( 71.410 ) = 71.410 deg. F , 0.3808 psia i dewpoint 4 ( 71.000 ) = _71.000 deg. F , 0.3755 psia  ;

l dewpoint 21 ( 65.770 ) = 65.770 deg. F, 0.3137 psia l j

4 dewpoint 22 ( 65.250 ) = 65.250 deg. F , 0.3081 psia i pressure 1 ( 26.6133 ) = 26.6133 psia pressure 2 ( 26.6169 ) = 26.6169 psia

' weighted averages, volume and air mass j temperature = 75.45436 deg. F l pressure = 26.61392 psia

, vapor pressure = 0.36535 psia i volume = 1670000 cu. ft. 1 dry air mass = 221103.39 lba j l

9

i. 1

• e i

data set 78 l

)i time = 945 date = 1121

) sensor raw data value i temperature 1( 75.800 ) = 75.800 deg. F 1 temperature 2( 75.830 ) = 75.830 deg. F j temperature 3( 75.800 ) = 75.800 deg. F

i. temperature 4( 76.060 ) = 76.060 deg. F i temperature .5 ( 75.020 ) = 75.020 deg. F

} temperature 6( 75.230 ) = 75.230 deg. F 1 temperature 7( 75.240 ) = 75.240 deg. F

! temperature 8( 76.120 ) = 76.120 deg. F

, temperature 9( 76.070 ) .= 76.070 dag. F' i temperature 10 ( 75.520 ) = 75.520 deg. F

! temperature 11 ( 76.390 ) = 76.390 deg. F i temperature 12 ( 76.010 ) = 76.010 deg. F l temperature 13 ( 76.990 ) = 76.990 deg. F

temperature 14 ( 64.770 ) = 64.770 deg. F

! temperature 15 ( 76.000 ) = 76.000 deg. F j . temperature 16 ( 74.490 ) = 74.490 deg. F temperature 17 ( 74.380 ) = 74.380 deg. F temperature 18 ( 73.410 ) = 73.410 deg. F temperature 21 (. 82.580 ) = 82.580 deg. F  ;

80.350 )

. temperature 22 ( = 80.350 dag.-F l' temperature 23 ( 77.700 ) = 77.700 deg. F temperature 24 ( 74.600 ) = 74.600 deg. F temperature 25 ( 74.950 ) = 74.950 deg. F

temperature 26 ( 73.350 ) = 73.350 deg. F i

j dawpoint 1 ( 71.170 ) = 71.170 deg. F , 0.3777 psia a

dewpoint 2 ( 70.960 ) = 70.960 deg.'F , 0.3750 psia dewpoint 3 ( 71.410 ) = 71.410 dag. F, 0.3808 psia

- dewpoint 4 ( 70.990 ) = 70.990 deg. F , 0.3754 psia -

! dewpoint 21 ( 65.820 ) = 65.820 deg. F , 0.3143' psia l

, dewpoint 22 ( 65.280 ) = 65.280 deg. F, 0.3084 psia  ;

j pressure 1 ( 26.6142 ) = 26.6142 psia j pressure 2 ( 26.6178 ) = 26.6178 psia i weighted' averages, volume and air mass i

! temperature = 75.45639 deg. F i pressure = 26.61481 psia .

vapor pressure = 0.36515 psia 1

volume = 1670000 cu. ft.

I dry air mass = 221111.83 lbm f

4 em, 6n- ,<.,.-_.._w -

• n I

data set 79 f time = 1000 date = 1121

] sensor raw data value i

j temperature 1( 75.810 ) = 75.810 deg. F 4 temperature 2( 75.820 ) = 75.820 deg. F

? temperature 3( 75.770 ) = 75.770 deg. F.

i temperature 4( 76.020 ) = 76.020 deg. F j -temperature 5 -( 75.000 ) = 75.000 deg. F i temperature 6( 75.230 ) = 75.230 deg. F l temperature 7( 75.260 ) = 75.260 deg.-F

! temperature 8( 76.100 ) = 76.100 deg..F ,

3 temperature 9( 76.070 ) = 76.070 deg. F l j temperature 10 ( 75.550 ) = 75.550 deg. F j temperature 11 ( 76.390 ) = 76.390 deg. ~ F

! temperature 12 ( 76.000 ) = 76.000 deg. F temperature 13 ( 77.000 ) = 77.000 deg. F l temperature 14 ( 64.780 ) = 64.780 deg. F l temperature 15 ( 75.940 ) = 75.940 dag. F i temperature 16 ( 74.490 ) = 74.490 deg. F temperature 17 ( 74.360 ) = 74.360 deg. F

, temperature 18 ( 73.410 ) = 73.410 deg. F temperature 21 ( 82.560 ) = 82.560 deg. F .

j temperature 22 ( 80.370 ) = 80.370 dag. F

] temperature 23 ( 77.730 ) = 77.730 deg. F j temperature 24 ( 74.660 ) = 74.660 deg. F

temperature 25 ( 75.000 ) = 75.000 deg. F 73.400 ) 73.400 deg.'F temperature 26 ( =

i dewpoint 1 ( 71.170') = 71.170 deg. F , 0.3777 psia i dewpoint 2 ( 70.980 ) = 70.980 deg. F , 0.3752 psia j dewpoint 3 ( 71.430 ) = 71.430 deg. F, 0.3810 psia i dewpoint 4 ( 71.010 ) = 71.010 deg. F , 0.3756 psia I dewpoint 21 ( 65.910 ) = 65.910 deg. F, 0.3153 psia dewpoint 22 ( 65.310 ) = 65.310 deg. F, 0.3088 psia

! l l pressure 1 ( 26.6143 ) = 26.6143 psia j pressure 2 ( 26.6178 ) = 26.6178 psia i

! weighted averages, volume and air mass-1 I temperature = 75.45449 deg. F i pressure = 26.61490 psia j vapor pressure = 0.36535 psia volume = 1670000 cu. ft.

l dry air mass = 221111.59 lba l e

i

, - , ~. , , , ..n,- ..m . , , , - - ,-- - , -

. , . ~ .

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

l l l

• o 2

i data set 80

! time = 1015 date = 1121 sensor raw data value l

! temperature 1( 75.790 ) = 75.790 deg. F 1 temperature 2( 75.790 ) = 75.790 deg. F l temperature 3( 75.780 ) = 75.780 deg. F j temperature 4 ( 76.010-) = 76.010 deg. F j

. temperature 5( 74.980 ) = 74.980 deg. F

temperature 6( 75.220 ) = 75.220 deg. F  !

! temperature 7 ( 75.300 ) = 75.300 deg. F j 76.150 ) 76.150 deg. F '

i temperature =

8 (

l temperature 9( 76.070 ) = 76.070 deg. F

temperature 10 ( 75.500 ) = 75.500 deg. F

! temperature 11 ( 76.350 ) = 76.350 deg. F i temperature 12 ( 76.010 ) = 76.010 deg. F temperature 13 ( 77.000 ) = 77.000 deg. F

temperature 14 ( 64.810 ) = 64.810 deg. F

temperature 15 ( 75.930 ) = 75.930 deg. F j . temperature 16 ( 74.480 ) = 74.480 deg. F j temperature 17 ( 74.390 ) = 74.390 dag. F j temperature 18 ( 73.420 ) = 73.420 deg. F i temperature 21 ( 82.520 ) = 82.520 deg. F ,

temperature 22 ( 80.400 ) = 80.400 deg. F temperature 23 ( 77.790 ) = 77.790 deg. F

temperature 24 ( 74.720 ) = 74.720 deg. F i temperature 25 ( 75.070 ) = 75.070 dag. F temperature 26 ( 73.480 ) = 73.480 dag. F dewpoint 1 ( 71.210 ) = 71.210 deg. F , 0.3782 psia i dewpoint 2 ( 70.970 ) = 70.970 deg. F , 0.3751 psia dewpoint 3 ( 71.450 ) = 71.450 deg. F ,-0.3813 psia

dewpoint 4 ( 71.040-) = 71.040 deg. F , 0.3760 psia dowpoint 21 ( 65.900 ) = 65.900 deg. F, 0.3152 psia dewpoint 22 ( 65.370 ) = 65.370 deg. F, 0.3094 psia

pressure 1 ( 26.6143 ) == 26.6143 psia

pressure 2 ( 26.6178 ) 26.6178 psia i

- weighted averages, volume and air mass-

)

i temperature = 75.46272.deg. F pressure = 26.61490 psia vapor pressure = 0.36565 psia volume = 1670000 cu. ft.

a dry air mass = 221105.71 lbm j

i

_. .- . ._ _ . _ _ . - _ _ . - . _ . - _ _ . _ _ . .m - _ _ . . _ _ _ _ - _ _ -- . _ . . - _ . . - _

1. e data set 81 I

time = 1030 date = 1121 sensor raw data value temperature 1 ( 75.800 ) = ~75.800 deg. F temperature 2 ( 75.830 ) = 75.830 deg. F '

temperature 3 ( 75.770 ) = 75.770 deg. F  !

temperature 4 ( 76.000 ) = 76.000 deg. F l temperature 5 ( 75.000 ) = 75.000 deg. F temperature 6 ( 75.220 ) = 75.220 deg. F temperature 7 ( 75.240 ) = 75.240 deg. F temperature 8 ( 76.230 ) = 76.230 deg. F. l temperature 9 ( 76.080 ) = 76.080 deg. F temperature 10 ( 75.520 ) = 75.520 dag. F temperature 11 ( 76.340 ) = 76.340 deg. F temperature 12 ( 76.010.) = 76.010 deg. F temperature 13 ( 76.970 ) = 76.970 deg. F temperature 14 ( 64.840 ) = 64.840 deg. F temperature 15 ( 76.030 ) = 76.030 dag. F temperature 16 ( 74.470 ) = 74.470 deg. F 74.390 ) 74.390 deg. F temperature-17 ( =

temperature 18.( 73.420 ) = 73.420 deg. F temperature 21 ( 82.550 ) = 82.550 deg. F .

temperature 22 ( 80.430 ) = 80.430 deg. F  ?

temperature 23 ( 77.820 ) = 77.820 deg. F temperature 24 ( 74.770 ) = 74.770 deg. F temperature 25 ( 75.100 ) = 75.100 deg. F temperature 26 ( 73.500 ) = 73.500 dag. F dowpoint. 1 ( 71.210 ) = 71.210 deg. F , 0.3782 psia dewpoint 2 ( 70.980 ) = 70.980 deg. F , 0.3752 psia dewpoint 3 ( 71.460 ) = 71.460 deg. F , 0.3814 psia dewpoint 4 ( 71.040 ) = 71.040 deg. F , 0.3760 psia dewpoint 21 ( 65.920 ) = 65.920 deg. F , 0.3154 psia dewpoint 22 ( 65.410 ) = 65.410 deg. F, 0.3098 psia pressure 1 ( 26.6143 ) = 26.6143 psia pressure 2 ( 26.6177 ) = 26.6177 psia weighted averages, volume and air mass temperature = 75.47489 dag. F pressure = 26.61488 psia vapor pressure = 0.36578 psia volume = 1670000 cu. ft.

dry air ~ mass = 221099.45 lba

- . - - .__ _ __ - - - . - - -._. - =_ - _ . , - -

1. e e

data set 82 1

time = 1045 date = 1121 sensor raw data value temperature 1( 75.790 ) = 75.790 deg. F temperature 2( 75.800 ) = 75.800 deg. F l temperature 3( 75.770 ) = 75.770 deg. F 4

temperature 4 ( 75.960 ) = 75.960 deg. F temperature 5( 74.960 ) = 74.960 deg. F temperature 6( 75.190 ) = 75.190 deg. F temperature 7( 75.230 ) = 75.230 deg. F temperature 8 ( 76.120 ) = 76.120 deg. F temperature 9 ( 76.070 ) = 76.070 deg. F temperature 10 ( 75.520 ) = 75.520 deg. F temperature 11 ( 76.390 ) = 76.390 deg. F temperature 12 ( 76.010 ) = 76.010 deg. F temperature 13 ( 77.020 ) = 77.020 deg. F temperature 14 ( 64.860 ) = 64.860 deg. F temperature 15 ( 75.990 ) = 75.990 deg. F temperature 16 ( 74.500 ) = 74.500 deg. F temperature 17 ( 74.380 ) = 74.380 deg. F temperature 18 ( 73.420 ) = 73.420 deg. F temperature 21 ( 82.520 ) = 82.520 dag. F  ;

a temperature 22 ( 80.440 ) =

80.440 deg. F temperature 23 ( 77.870 ) = 77.870 deg. F temperature 24 ( 74.820 ) = 74.820 dag. F temperature 25 ( 75.090 ) = 75.090 deg. F temperature 26 ( 73.540 ) = 73.540 deg. F dewpoint 1 ( 71.220 ) =

71.-220 dag. F , 0.3783 psia

. dewpoint 2 ( 71.010 ) = 71.010 deg. F, 0.3756 psia dewpoint 3 ( 71.450 ) =

71.450 deg. F , 0.3813 psia dewpoint 4 ( 71.060 ) = 71.060 deg. F, 0.3763 psia dewpoint 21 ( 65.970 ) = 65.970 deg. F, 0.3159 psia dewpoint 22 ( 65.450 ) = 65.450 deg. F, 0.3103 psia 2

pressure 1 ( 26.6141 ) = 26.6141 psia pressure 2 ( 26.6175 ) = 26.6175 psia weighted averages, volume and air mass temperature = 75.46619 deg. F

! pressure = 26.61468 psia vapor pressure = 0.36601 psia volume = 1670000 cu. ft, dry air mass =

221099.35 lbm l

I 1

• w 1

data set 83 time = 1100 date = 1121 sensor raw data value

temperature 1 ( 75.790 ) = 75.790 deg. F temperature 2( 75.800 ) = 75.800 deg. F temperature 3( 75.750 ) =- 75.750 deg. F temperature 4( 75.980 ) = 75.980 deg. F temperature 5( 75.020 ) = 75.020 deg. F temperature 6( 75.210') = 75.210 deg. F temperature 7 ( 75.200 ) = 75.200 deg. F 4 temperature 8( 76.140 ) = 76.140 deg. F 3

temperature 9 ( 76.080 ) = 76.080 deg. F j temperature 10 ( 75.480 ) = 75.480 deg. F temperature 11.( 76.340-) = 76.340 deg. F 4 temperature 12-( 76.010 ) = 76.010 dag. F temperature 13 ( 76.980 ) = 76.980 dag. F temperature 14 ( 64.880 ) = 64.880 dag. F temperature 15 ( 75.900 ) = 75.900 dag. F temperature 16 ( 74.480 ) = 74.480 dag. F temperature 17 ( 74.400 ) = 74.400 deg. F temperature 18 ( 73.430 ) = 73.430 deg. F.

temperature 21 ( 82.550 ) = 82.550 deg. F ,

temperature 22 ( 60.470 ) = 80.470 deg. F l temperature 23 ( 77.910 ) = 77.910 deg. F 74.880.)

temperature 24 ( = 74.880 dag. F ,

temperature 25 ( 75.160 ) = 75.160 deg. F temperature 26 ( 73.570 ) = 73.570 deg. F i

dewpoint 1 ( 71.230 ) = 71.230 deg. F , 0.3784 psia

dewpoint 2 ( 71.010 ) = 71.010 deg. F , 0.3756 psia 5

dewpoint 3 ( 71.480 ) = 71.480 deg. F , 0.3817 psia dewpoint 4 ( 71.060 ) = 71.060 deg. F , 0.3763 psia dewpoint 21 ( 66.000 ) = 66.000 deg. F , 0.3163 psia dewpoint 22 ( 65.500 ) = 65.500 deg. F , 0.3108 psia pressure 1 ( 26.6141 ) = 26.6141 psia pressure 2 ( 26.6175 ) = 26.6175 psia weighted averages, volume and air mass temperature = 75.47250 deg. F pressure = 26.61468 psia vapor pressure = 0.36619 psia volume = 1670000 cu. ft, dry air mass = 221095.24 lba l

l

6 ,

2 84 data set

) time = 1115 date = 1121 sensor raw data value temperature 1 ( 75.780 ) = 75.780 deg. F temperature 2 ( 75.800 ) = 75.800 deg. F 75.780 )

temperature 3 ( = 75.780 deg. F-temperature 4 ( 75.980 ) = 75.980 deg. F

. temperature 5 ( 74.970 ) = 74.970 deg. F temperature 6 ( 75.190 ) = 75.190 dag. F temperature 7 ( 75.210 ) = 75.210 deg. F

temperature 8 ( 76.120 ) = 76.120 deg. F

! temperature 9 ( 76.070 ) = 76.070 dag. F temperature 10 (- 75.510 ) = 75.510 deg. F 1

temperature 11 ( 76.350 ) = 76.350 deg. F

temperature 12 ( 76.010 ) = 76.010 dag. F l temperature 13 ( 76.990 ) = 76.990 deg..F j temperature 14 ( 64.910 ) = 64.910 dag. F temperature.15'( 76.000 ) = 76.000 deg. F temperature 16 ( 74.490 ) =- 74.490 deg. F temperature 17 ( 74.390 ) = 74.390 deg. F

> temperature 18 ( 73.430 ) = 73.430 dag. F,

temperature 21 ( 82.470 ) =~ 82.470 deg. F ,

temperature 22 ( 80.510 ) = 80.510 deg. F temperature 23 ( 77.920 ) = 77.920 deg. F

- temperature 24 ( 74.930 ) = 74.930 dag. F

j. temperature 25-(_ 75.250 ) = 75.250 deg. F temperature 26 ( 73.630 ) = 73.630 dag. F j l

dewpoint 1 ( 71.240 ) = 71.240 deg. F , 0.3786 psia dewpoint 2 ( 71.030 ) = -71.030 deg. F , 0.3759 psia dewpoint 3 ( 71.470 ) = 71.470 deg. F , 0.3815' psia dewpoint 4 ( 71.060 ) = 71.060 dag. F , 0.3763 psia dewpoint 21 -( 66.090 ) = 66.090 deg. F , 0.3172 psia dewpoint 22 ( 65.530 ) = 65.530 deg. F , 0.3111 psia pressure- 1 ( 26.6141 ) = = 26.6141 psia

pressure 2 ( 26.6176 ) 26.6176 psia weighted averages, volume and air mass l temperature = 75.48370 deg. F

, pressure = 26.61470 psia j vapor pressure = 0.36633 psia volume = 1670000 cu. ft.

dry air mass = 221089.57 lba i

i i

4

data set 85 l

time = 1130 date = 1121 l sensor raw data value temperature 1( 75.790 ) = 75.790 deg. F temperature 2( 75.800 ) = 75.800 deg. F temperature 3 ( 75.760 ) = 75.760 deg. F temperature 4 ( 75.990 ) = 75.990 deg. F temperature 5 ( 75.020 ) = 75.020 deg. F temperature 6 ( 75.150 ) = 75.150 deg. F temperature 7 ( 75.240 ) = 75.240 deg. F temperature 8 ( 76.090 ) = 76.090 deg. F temperature 9 ( 76.060 ) = 76.060 deg. F temperature 10 ( 75.510 ) = 75.510 deg. F temperature 11 ( 76.350 ) = 76.350 deg. F temperature 12 ( 76.000 ) = 76.000 deg. F temperature 13 ( 77.040 ) = 77.040 deg. F temperature 14 ( 64.920 ) = 64.920 deg. F temperature 15 ( 75.980 ) = 75.980 deg. F temperature 16 ( 74.500 ) = 74.500 deg. F temperature 17 ( 74.400 ) = 74.400 deg. F temperature 18 ( 73.430 ) = 73.430 deg. F temperature 21 ( 82.520 ) = 82.520 deg. F .

temperature 22 ( 80.540 ) = 80.540 deg. F temperature 23 ( 77.990 ) = 77.990 deg. F temperature 24 ( 74.980 ) = 74.980 deg. F temperature 25 ( 75.290 ) = 75.290 deg. F temperature 26 ( 73.680 ) = 73.680 deg. F dewpoint 1 ( 71.230 ) = 71.230 deg. F, 0.3784 psia dewpoint 2 ( 71.050 ) = 71.050 deg. F , 0.3761 psia dewpoint 3 ( 71.460 ) = 71.460 deg. F , 0.3814 psia dewpoint 4 ( 71.080 ) = 71.080 deg. F, 0.3765 psia dewpoint 21 ( 66.090 ) = 66.090 deg. F , 0.3172 psia dewpoint 22 ( 65.590 ) = 65.590 deg. F , 0.3118 psia pressure 1 ( 26.6143 ) = 26.6143 psia pressure 2 ( 26.6175 ) = 26.6175 psia weighted averages, volume and air mass temperature = 75.49400 deg. F pressure = 26.61485 psia vapor pressure = 0.36651 psia volume = 1670000 cu. ft.

dry air mass = 221085.11 lba l

l I

l

o ,

j l

)

data set 86 I

time = 1145 date = 1121 sensor raw data value temperature 1 ( 75.780 ) = 75.780 deg. F  !

temperature 2( 75.820 ) = 75.820 deg. F f temperature 1 ( 75.760 ) = 75.760 deg. F temperature 4 ( 75.980 ) = 75.980 deg. F l temperature 5 ( 74.970 ) = 74.970 deg. F temperature 6( 75.140 ) = 75.140 deg. F temperature 7 ( 75.260 ) = 75.260 deg. F temperature 8( 76.100 ) = 76.100 deg. F temperature 9 ( 76.090 ) = 76.090 deg. F temperature 10 ( 75.430 ) = 75.430 deg. F temperature 11 ( 76.310 ) = 76.310 deg. F temperature 12 ( 75.990-) = 75.990 deg. F temperature 13 ( 77.050 ) = 77.050 deg. F temperature 14 ( 64.940 ) = 64.940 deg. F temperature 15 ( 75.900 ) = 75.900 deg. F temperature 16 ( 74.480 ) = 74.480 deg. F temperature 17 ( 74.410 ) = 74.410 deg. F temperature 18 ( 73.440 ) = 73.440 deg. F l

temperature 21 ( 82.470 ) = 82.470 dag. F .

temperature 22 ( 80.560 ) = 80.560 deg. F temperature 23 ( 78.010 ) = 78.010 deg. F temperature 24 ( 75.000 ) = 75.000 deg. F temperature 25 ( 75.290 ) = 75.290 deg. F temperature 26 ( 73.720 ) = 73.720 deg. F dewpoint 1 ( 71.180 ) = 71.180 deg. F, 0.3778 psia dewpoint 2 ( 71.040 ) = 71.040 deg. F, 0.3760 psia dewpoint 3 ( 71.450 ) = 71.450 deg. F, 0.3813 psia dewpoint 4 ( 71.090 ) = 71.090 deg. F , 0.3766 psia dewpoint 21 ( 64.390 ) = 64.390 deg. F, 0.2990 psia dewpoint 22 ( 65.610 ) = 65.610 deg. F , 0.3120 psia pressure 1 ( 26.6144 ) = 26.6144 psia pressure 2 ( 26.6179 ) = 26.6179 psia weighted averages, volume and air mass temperature = 75.49017 deg. F pressure = 26.61500 psia vapor pressure = 0.36635 psia i volume = 1670000 cu. ft, dry air mass = 221089.25 lbm 1

.- - ~ - - - -- . - .. . - - - - . - . . - . . .-

e l'

i

data set 87 4

time = 1200 date = 1121  !

sensor raw data value l i .

1( 75.780 ) 75.780 deg. F.

=

y temperature .

temperature 2( 75.790 ) = 75.790 deg. F  !

temperature 3( 75.770 ) = 75.770 deg. F temperature 4( 75.920 ) = 75.920 deg. F temperature 5 _( 75.010 ) = 75.010 deg. F temperature 6 ( . 75.240 ) = 75.240 deg. F temperature _7 ( 75.250 ) = 75.250 deg. F temperature 8 ( 76.140 ) = 76.140 deg. F i temperature 9( 76.070 ) = 76.070 deg. F l temperature 10 ( 75.500 ) = 75.500 deg._F

. temperature 11 ( -76.300 ) = 76.300 deg. F 4 temperature 12 ( 75.990 ) = 75.990 deg. F 4

temperature 13 ( 76.970 ) = 76.970 deg._F i temperature 14 ( 64.980 ) = 64.980 deg. F j temperature 15 ( 75.970 ) = 75.970 deg. F

temperature 16 ( 74.490 ) = _74.490 deg. F 1 temperature 17 ( 74.410 ) = 74.410 deg. F

( 73.440') 73.440 deg. F temperature 18 =

temperature 21 ( 82.490') = 82.490'deg. F  ;

( 80.610 )

i temperature 22 = 80.610 deg. F i temperature 23 ( 78.090 ) = 78.090 deg. F i temperature 24 ( 75.080 ) = 75.080 deg. F

- temperature 25 ( 75.340 ) = 75.340 deg. F j temperature 26 ( 73.790-) = 73.790 deg. F dewpoint 1 ( 71.260 ) = 71.260 deg. F, 0.3788 psia dewpoint 2 ( 71.040-) = 71.040 deg. F , 0.3760 psia j dewpoint 3 ( 71.470 ) = 71.470 deg. F , 0.3815 psia dewpoint 4 ( 71.090 ) = 71.090 deg. F , 0.3766 psia l

dewpoint 21 ( 66.200 ) = 66.200 deg. F , 0.3185 psia (

dewpoint 22 ( 65.680 ) = 65.680 deg. F , 0.3128 psia 0

i pressure 1 ( 26.6143 ) = 26.6143 psia i

4 pressure 2 ( 26.6181 ) = 26.6181 psia i

weighted averages, volume and air mass 1

, temperature = 75.50713 deg. F pressure = 26.61495 psia l vapor pressure = 0.36677 psia volume = 1670000 cu. ft.

dry air mass = 221078.34 lbm i

]

i i

m _ - . _ _

l data set 88

, time = 1215 date = 1121 sensor raw data value l temperature 1- ( 75.780 ) = 75.780 deg. F temperature 2 ( 75.800 ) = 75.800 deg. F temperature 3 ( 75.760 ) = 75.760 deg. F temperature 4( 76.020 ) = 76.020 deg. F temperature 5 ( 74.990 ) = 74.990 deg. F temperature 6( 75.230 ) = .75.230 deg. F temperature 7 ( 75.230 ) = 75.230 deg. F temperature 8( 76.160 ) = 76.160 deg. F temperature 9( 76.070 ) = 76.070 dag. F

temperature 10 ( 75.550 ) = 75.550 deg. F temperature 11 ( 76.300 ) = 76.300 deg. F temperature 12 ( 75.990 ) = 75.990 dag. F temperature 13 ( 77.050 ) = 77.050 deg. F temperature 14-( 65.000 ) = 65.000 dag. F temperature 15 ( 75.940 ) = 75.940 dag. F temperature 16 ( 74.480 ) = 74.480 dag. F temperature 17 ( 74.390 ) = 74.390 deg. F temperature 18 ( 73.430 ) = 73.430 deg. .

F temperature 21 ( 82.490-) _ = 82.490 deg. F ,

temperature 22 ( 80.650 ) = 80.650 deg. F temperature 23 ( 78.140 ) = 78.140 dag. F temperature 24 ( 75.140 ) = 75.140 deg. F temperature 25 ( 75.410 ) = 75.410 deg. F '

temperature 26 ( 73.820 ) = 73.820 deg. F dewpoint 1 ( 71.230 ) = 71.230 deg. F, 0.3784 psia dewpoint 2 ( 71.040 ) = 71.040 dag. F , 0.3760 psia dewpoint 3 ( 71.480 ) = 71.480 deg. F , 0.3817 psia dewpoint 4 ( 71.100 ) = 71.100 deg. F , 0.3768 psia dewpoint 21 ( 66.260 ) = 66.260 deg. F , 0.3191 psia dewpoint 22 ( 65.720 ) = 65.720 deg. F , 0.3132 psia pressure 1 ( 26.6144 ) = 26.6144 psia.

pressure 2 ( 26.6181 ) = 26.6181 psia weighted averages, volume and air mass temperature = 75.52234 dag. F pressure = 26.61503 psia vapor pressure = 0.36679 psia volume = 1670000 cu. ft.

dry air mass = 221072.58 lbm

data set 89 time = 1230 date = 1121 ,

sensor raw data value temperature 1( 75.770 ) = 75.770 deg. F temperature 2 ( 75.790 ) = 75.790 deg. F temperature 3 ( 75.760 ) = 75.760 deg. F temperature 4 ( 75.940 ) = 75.940 deg. F temperature 5( 75.010 ) = 75.010 deg. F temperature 6 ( 75.130 ) = 75.130 dog. F temperature 7 ( 75.270 ) = 75.270 deg. F temperature 8 ( 76.100 ) = 76.100 deg. F i temperature 9 ( 76.060 ) = 76.060 deg. F l temperature 10 ( 75.500 ) = 75.500 deg. F l temperature 11 ( 76.280 ) = 76.280 deg. F l temperature 12 ( 75.990 ) = 75.990 deg. F i temperature 13 ( 77.020 ) = 77.020 deg. F temperature 14 ( 65.020 ) = 65.020 deg. F temperature 15 ( 75.980 ) = 75.980 deg. F temperature 16 ( 74.490 ) = 74.490 deg. F temperature 17 ( 74.390 ) = 74.390 deg. F temperature 18 ( 73.440 ) = 73.440 deg. F temperature 21 ( 82.490 ) = 82.490 deg. F ,

temperature 22 ( 80.670 ) = 80.670 deg. F temperature 23 ( 78.150 ) = 78.150 deg. F temperature 24 ( 75.050 ) = 75.050 deg. F temperature 25 ( 75.490 ) = 75.490 deg. F temperature 26 ( 73.850 ) = 73.850 deg. F dewpoint 1 ( 71.220 ) = 71.220 deg. F , 0.3783 psia dewpoint 2 ( 71.040 ) = 71.040 deg. F , 0.3760 psia dewpoint 3 ( 71.470 ) = 71.470 deg. F , 0.3815 psia dewpoint 4 ( 71.120 ) = 71.120 deg. F , 0.3770 psia dewpoint 21 ( 66.300 ) = 66.300 deg. F , 0.3196 psia dewpoint 22 ( 65.740 ) = 65.740 deg. F, 0.3134 psia pressure 1 ( 26.6144 ) = 26.6144 psia pressure 2 ( 26.6179 ) = 26.6179 psia weighted averages, volume and air mass temperature = 75.51180 deg. F l pressure = 26.61500 psia I vapor pressure = 0.36682 psia l volume = 1670000 cu. ft. I dry air mass = 221076.41 lbm j

e data set 90 time = 1245 date = 1121 sensor raw data value temperature 1 ( 75.760 ) = 75.760 deg. F temperature 2 ( 75.770 ) = 75.770 deg. F temperature 3( 75.760 ) = 75.760 deg. F temperature 4( 75.890 ) = 75.890 deg. F temperature 5( 74.980 ) = 74.980 deg. F 4

temperature 6( 75.120 ) = 75.120 deg. F temperaturs ~/ ( 75.260 ) = 75.260 deg. F tesparature 8( 76.170 ) = 76.170 deg. F temperature 9( 76.070 ) = 76.070 deg. F temperature 10 ( 75.490 ) = 75.490 deg. F temperature 11 ( 76.260 ) = 76.260 deg. F temperature 12 ( 76.010 ) = 76.010 deg. F temperature 13 ( 76.960 ) = 76.960 deg. F temperature 14 ( 65.040 ) = 65.040 deg. F temperature 15 ( 75.930 ) = 75.930 deg. F temperature 16 ( 74.480 ) = 74.480 deg. F temperature 17 ( 74.380 ) = 74.380 deg. F temperature 18 ( 73.440 ) = 73.440 deg. F temperature 21 ( 82.500 ) = 82.500 deg. F  ;

temperature 22 ( 80.720 ) = 80.720 dag. F temperature 23 ( 78.210 ) = 78.210 deg. F temperature 24 ( 75.110 ) = 75.110 deg. F temperature 25 ( 75.510 ) = 75.510 deg. F temperature 26 ( 73.900 ) = 73.900 deg. F dewpoint 1 ( 71.310 ) = 71.310 deg. F, 0.3795 psia dewpoint 2 ( 71.040 ) = 71.040 deg. F , 0.3760 psia dewpoint 3 ( 71.470 ) = 71.470 deg. F , 0.3815 psia dewpoint 4 ( 71.120 ) = 71.120 deg. F , 0.3770 psia dewpoint 21 ( 66.370 ) = 66.370 deg. F , 0.3203 psia dewpoint 22 ( 65.800 ) = 65.800 deg. F , 0.3141 psia pressure 1 ( 26.6142 ) = 26.6142 psia pressure 2 ( 26.6178 ) = 26.6178 psia weighted averages, volume and air mass temperature = 75.50957 deg. F pressure = 26.61481 psia vapor pressure = 0.36721 psia volume = 1670000 cu. ft.

dry air mass = 221072.50 lbm

i 1

data set 91 time = 1300 date = 1121 ,

sensor raw data value temperature 1( 75.760 ) = 75.760 deg. F temperature 2( 75.790 ) = 75.790 deg. F temperature 3( 75.770 ) = 75.770 deg. F temperature 4( 75.870 ) = 75.870 deg. F temperature 5( 74.970 ) = 74.970 deg. F temperature 6( 75.190 ) = 75.190 deg. F t

~

temperature 7 ( 75.300 ) = 75.300 deg. F temperature 8( 76.220 ) = 76.220 deg. F temperature 9( 76.090 ) = 76.090 deg. F temperature 10 ( 75.510 ) = 75.510 deg. F temperature 11 ( 76.300 ) =- 76.300 deg. F temperature 12 ( 76.010 ) = 76.010 deg. F ,

temperature 13 ( 76.910 ) = 76.910 deg. F temperature 14 ( 65.060 ) = 65.060 deg. F temperature 15 ( 75.950 ) = 75.950 dag. F temperature 16 ( 74.470 ) = 74.470 deg. F temperature 17 ( 74.410 ) = 74.410 deg. F temperature 18 ( 73.460 ) = 73.460 deg. F temperature 21 ( 82.460 ) = 82.460 deg. F  ;

temperature 22 ( 80.760 ) = 80.760 deg. F temperature 23 ( 78.250 ) = 78.250 deg. F temperature 24 ( 75.180 ) = 75.180 deg. F temperature 25 ( 75.570 ) = 75.570 deg. F '

temperature 26 ( 73.950 ) = 73.950 deg. F dewpoint 1 ( 71.280 ) = 71.280 deg. F , 0.3791 psia dewpoint 2 ( 71.070 ) = 71.070 deg. F , 0.3764 psia dewpoint 3 ( 71.480 ) = 71.480 deg. F , 0.3817 psia dewpoint 4 ( 71.120 ) = 71.120 deg. F , 0.3770 psia dewpoint 21 ( 66.400 ) = 66.400 deg. F , 0.3207 psia dewpoint 22 ( 65.840 ) = 65.840 deg. F, 0.3145 psia 4 pressure 1 ( 26.6144 ) == 26.6144 psia pressure 2 ( 26.6180 ) 26.6180 psia weighted averages, volume and air mass l temperature = 75.53034 deg. F pressure = 26.61502 psia vapor pressure = 0.36732 psia volume = 1670000 cu. ft.

dry air mass = 221064.68 lbm  ;

l

i. _ -

s data set 92 time = 1315 date = 1121 sensor raw data value temperature 1( 75.770 )- = 75.770 deg. F temperature 2( 75.780-) = 75.780 deg. F temperature 3 ( 75.760 ) = 75.760 deg. F temperature 4( 75.920 ) = 75.920 deg. F temperature 5( 75.000 ) = 75.000 deg. F temperature 6( 75.180 ) = 75.180 dag. F temperature 7 ( 75.300 ) = 75.300 deg. F temperature 8( 76.110 )- = 76.110 deg. F temperature 9( 76.050 ) = 76.050 deg. F temperature 10 ( 75.570 ) = 75.570 dag. F temperature 11-( 76.300 ) = 76.300 deg. F:

temperature 12 ( 76.000 ) = 76.000 dag. F temperature 13 ( -76.920 ) = 76.920 deg. F temperature 14 ( 65.080 ) = 65.080 deg. F temperature 15 ( 75.930 ) = 75.930 deg. F temperature 16 ( 74.510 ) = 74.510 deg. F temperature 17 ( 74.370 ) = 74.370 deg. F temperature 18 ( 73.450 ) = 73.450 deg. F temperature 21 ( 82.470 ) = 82.470 deg. F  ;

temperature 22 ( 80.810 ) = 80.810 deg. F temperature 23 (- 78.280 ) = 78.280 deg. F temperature 24 ( 75.230 ) = 75.230 deg. F temperature 25 (- 75.590 ) =- 75.590 deg. F temperature 26 ( 73.980 ) = 73.980 dag. F dewpoint 1- ( 71.250 ) = 71.250 deg. F , 0.3787 psia dewpoint 2 ( 71.080 ) = 71.080 deg. F , 0.3765 psia dewpoint 3 '( 71.490 ) = 71.490-deg. F , 0.3818 psia dewpoint 4 ( 71.150 ) = 71.150 deg. F , 0.3774 psia dewpoint 21 ( 66.440 ) = 66.440 deg. F , 0.3211 psia dewpoint 22 ( 65.910 ) = 65.910 deg. F , 0.3153 psia pressure 1 ( 26.6144 ) ==- ?6.G144 psia pressure 2 ( 26.6181 ) 26.6181 psia weighted averages, volume and air mass temperature = 75.53645 deg. F pressure = 26.61503 psia vapor pressure = 0.36747 psia volume = 1670000 cu. ft.

dry air mass = 221061.01 lbm

l l

data set 93 time = 1330 date = 1121 sensor raw data value j temperature 1 ( 75.780 ) = 75.780 deg. F j temperature 2 ( 75.770 ) = 75.770 deg. F i temperature 3 ( 75.760 ) = 75.760 deg. F temperature 4 ( 75.870 ) = 75.870 deg. F temperature 5 ( 74.980 ) = 74.930 deg. F temperature 6 ( 75.100 ) = 75.100 deg. F temperature 7 ( 75.260 ) = 75.260 deg. F temperature 8 ( 76.170 ) = 76.170 deg. F temperature 9 ( 76.060 ) = 76.060 deg. F temperature 10 ( 75.500 ) = 75.500 deg. F temperature 11 ( 76.310 ) = 76.310 deg. F temperature 12 ( 76.000 ) = 76.000 deg. F temperature 13 ( 76.980 ) = 76.980 deg. F temperature 14 ( 65.100 ) = 65.100 deg. F temperature 15 ( 75.970 ) = 75.970 deg. F temperature 16 ( 74.520 ) = 74.520 deg. F temperature 17 ( 74.390 ) = 74.390 deg. F temperature 18 ( 73.460 ) = 73.460 deg. F temperature 21 ( 82.440 ) = 82.440 deg. F  ;

temperature 22 ( 80.850 ) = 80.850 deg. F  ;

temperature 23 ( 78.340 ) = 78.340 deg. F temperature 24 ( 75.270 ) = 75.270 deg. F temperature 25 ( 75.640 ) = 75.640 deg. F temperature 26 ( 74.060 ) = 74.060 deg. F dewpoint 1 ( 71.280 ) = 71.280 deg. F, 0.3791 psia dewpoint 2 ( 71.090 ) = 71.090 deg. F , 0.3766 psia dewpoint 3 ( 71.520 ) = 71.520 deg. F, 0.3822 psia dewpoint 4 ( 71.150 ) = 71.150 deg. F, 0.3774 psia dewpoint 21 ( 67.620 ) = 67.620 Beg. F , 0.3345 psia dewpoint 22 ( 65.950 ) = 65.950 deg. F , 0.3157 psia pressure 1 ( 26.6145 ) == 26.6145 psia pressure 2 ( 26.6179 ) 26.6179 psia weighted averages, volume and air mass temperature = 75.53895 deg. F pressure = 26.61508 psia vapor pressure = 0.36773 psia volume = 1670000 cu. ft.

dry air mass = 221058.20 lbm

data set 94 time = 1345 date = 1121 sensor raw data value i

temperature 1( 75.760 ) = 75.760 deg. F temperature 2( 75.770 ) = 75.770 deg. F i

, temperature 3( 75.760 ) = 75.760 deg. F l 1

. temperature 4( 75.910 ) = 75.910 deg. F temperature 5( 74.990 ) = 74.990 deg. F temperature 6( 75.140 ) = 75.140 dag. F temperature 7 ( 75.240 ) = 75.240 deg. F l temperature 8( 76.210 ) = 7 5.210 deg. F temperature 9 ( 76.090 ) =. 76.090 deg. F temperature 10 ( 75.480 ) = ~15.480 dag. F temperature 11 ( 76.330 ) = 16.330 dag. F temperature 12 ( 76.020 ) = 76.020 deg. F temperature 13 ( .76.920 ) = *iS.??O deg. F temperature 14 ( 65.140 ) = 65.140 deg. F temperhture 15 ( 75.990 ) = 75.990 dag. F temperature 16 ( 74.500 ) = 74.500 dag. F temperature 17 ( 74.410 ) = 74.410 deg. F ,

temperature 18 ( 73.460 ) = 73.460 deg. F temperature 21 ( 82.430 ) = 82.430 deg. F 80.890 dag. F i temperature 22 (. 80.890 ) =

temperature 23 ( 78.370 ) = 78.370 deg. F temperature 24 ( 75.330 ) = 75.330 dag. F temperature 25 ( 75.680 ) = 75.680 deg. F temperature 26 ( 74.090 ) = 74.090 deg. F dewpoint 1 ( 71.280 ) = 71.280 deg. F , 0.3791 psia dewpoint 2 ( 71.090 ) = 71.090 deg. F , 0.3766 psia dewpoint 3 ( 71.500 ) = 71.500 deg. F , 0.3819 psia dewpoint 4 ( 71.130 ) = 71.130 dag. F , 0.3772 psia dewpoint 21 ( 65.250 ) = 65.250 deg. F , 0.3081 psia dewpoint 22 ( 65.980 ) = 65.980 deg. F , 0.3160 psia pressure 1 ( 26.6147 ) == 26.6147 psia pressure 2 ( 26.6182 ) 26.6182 psia weighted averages, volume and air mass temperature = 75.55255 deg. F pressure = 26.61530 psia  ;

vapor pressure = 0.36771 psia  ;

volume = 1670000 cu. ft.

dry air mass = 221054.59 lba l

1

.- .- .- -- . . . - . . . - ,_ . - .. .~ . . .

e data set 95 time = 1400 date = 1121 sensor raw data value 1

temperature 1 ( 75.770 ) = 75.770 deg. F  !

temperature 2 ( 75.780 ) = 75.780 deg. F l J

temperature 3 ( 75.770 ) = 75.770 deg. F temperature 4 ( 75.990 ) = 75.990 dag. F temperature 5 ( 75.000 ) = 75.000 deg. F temperature 6 ( 75.200 ) = 75.200 deg. F temperature 7 ( 75.270 ) = 75.270 deg. F.

temperature 8 ( 76.170 ) = 76.170 dag. F temperature. 9 ( 76.080 ) = 76.080 deg. F temperature 10 ( 75.550 ) = 75.550 deg. F temperature 11 ( 76.300 ). = 76.300 deg.-F temperature 12 ( 76.010 ) = 76.010 deg. F temperature 13-( 76.920 ) = 76.920 deg. F temperature 14 ( 65.150 ) = 65.150 deg. F .

temperature.15 ( 76.060 ) = 76.060 dag. F temperature 16 ( 74.520 ) = 74.520 deg. F temperature 17 ( 74.410 ) = 74.410 deg. F temperature 18 ( 73.470 ) = 73.470 deg. F temperature 21 ( 82.430 ) = 82.430 deg..F temperature 22 ( 80.920 ) = 80.920 deg. F  ;

temperature 23 ( 78.420 ) = 78.420 deg. F temperature 24 ( 75.390 ) = 75.390 deg..F temperature 25 ( 75.730 ) = 75.730 dag. F ,

temperature 26 ( 74.120 ) = 74.120 dag. F dewpoint 1 ( 71.350 ) = 71.350 deg. F , 0.3800 psia

. dewpoint 2- ( 71.080 ) = 71.080 deg. F ,.0.3765 psia dewpoint 3 ( 71.540 ) = 71.540 deg. F , 0.3824 psia-

. dewpoint 4 ( 71.150 ) = 71.150 deg. F , 0.3774 psia dewpoint 21 ( 63.300 ) = 63.300 deg. F , 0.2878 psia dewpoint 22 ( 66.040 ) = 66.040 deg. F , 0.3167 psia pressure 1 ( 26.6150 ) == 26.6150 psia pressure 2 ( 26.6186 ) 26.6186 psia weighted averages, volume and air mass ,

temperature = 75.57777 deg. F pressure = 26.61562 psia vapor pressure = 0.36812 psia  !

volume = 1670000 cu. ft.

dry air mass -

?21043.40 lbm.

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BCP Technical Services, Inc.

• Grand Gulf Containment Building 1993 ILRT Final Report APPENDIX IV LOCAL LEAKAGE RATE (TYPE B & C)

TEST RESULT TABULATION i

s Paga 1 of 4 APPENDIX IV (Continued)

Local Leak Rate Teg,t Summary Data Tvoo B and C Test Results Pneumatic Testing Minimum Pathway Leakace (sccm)

RFO4 RF05 RFO6 RF06 Penetration Description As-Left As-Left As- Found As -Lef t 1 Containment Equipment Hatch 0 0 0 151 2 Upper Containment Airlock 0 377 0 91 3 Lower Containment Airlock 0 0 0 91 4 Fuel Transfer Tube 0 40 0 0 5 Main Steam Line A 0 1,805 0 0 6 Main Steam Line B 0 1,507 1,400 138 7 Main Steam Line C 0 263 26,333 1,205 8 Main Steam Line D 0 0 60 101 9 Feedwater Line A 203 101 0 303 10 Feedwater Line B 0 30 20 200 14 RHR Shutdown Cooling Suction 101 112 0 0 17 Steam Supply to RCIC Turbine 191 40 0 0 18 RHR to RPV Head Spray 0 0 0 0 19 Main Steam Line Drain 0 0 40 40 20 Low Pressure Core Injection from 0 303 0 0 RHR A 21 Low Pressure Core Injection from 0 0 874 874 RER B  ;

22 Low Pressure Core Injection from 802 0 0 O RHR C 23 RHR A Test Return (1) 0 0 0 0 24 RHR C Test Return (1) 0 0 0 0 26 HPCS Pump Discharge to RPV O 40 0 0 27 HPCS Test Return (1) 0 0 0 0 29 RCIC Turbine Exhaust (2) (2) 3,382 161 31 LPCS Pump Discharge to RPV 0 30 0 0 32 LPCS Test Return (1) 0 0 0 0 33 CRD Pump Discharge 0 0 0 0 34 Containment Purge Supply 0 0 0 0 35 Containment Purge Exhaust 0 4 0 0 36 Plant Service Water Return 0 0 0 0 37 Plant Service Water Supply 8 0 0 0 38 Chilled Water Supply 0 0 0 0 39 Chilled Water Return 0 0 0 0 40 ILRT--Containment Pressurization 0 0 0 0 41 Service Air Supply 71 10 504 322 42 Instrument Air Supply 320 0 100 100 43 RWCU to Main Condenser 160 243 0 0 44 Component Cooling Water Supply 120 0 0 0 45 Component Cooling Water Return 0 0 0 0 47 Reactor Recirculation Post Accident 0 0 0 0 Sample l 48 RER Heat Exchanger B Relief Valve (2) 0 336 336 l Discharge to Suppression Pool l 49 RWCU Backwash Transfer Pump Discharge 50 0 0 0 50 Drywell & Containment Equipment Drain 0 20 0 0 l

Sump Pump Discharge 51 Drywell & Containment Floor Drain 162 10 0 0 Sump Pump Discharge H : \AMALONE \ EXCEL 4 0\B&CRESLT.XLS Revised: 4/26/94

i Page 2 of 4 APPENDIZ IV (Continued)

Local Leak Rate Test Su--=rv Data Tvoe B and C Test Results

• Pneumatic Testing Minimum Pathway Leakaae (sccm)

RFO4 RF05 RFO6- RFO6 Penetration Descriotion As-Left As-Left As-Found As-Lef t 54 Upper Containment Pool to and from 90 20 0 0 Refueling Water Storage Tank 56 Condensate Makeup to Upper 0 0 0 0 Containment Pool l 57 Fuel Pool Cooling & Cleanup System 0 0 0 0 Discharge to Upper Containment Pool 58 Fuel Pool Cooling & Cleanup System 0 0 0 0 l Return from Upper Containment Pool; I 60 Return from Auxiliary Building Floor 0 0 0 0 Equipment Drain Tanks 61 Standby Liquid Control Mixing Tank 0 0 91 91 (Future Use) 65 Containment Normal Vent & Combustible 0 0 0 0 Gas Control Purge Supply 66 Containment Normal Vent & Combustible 0 20 0 0 Gas Control Purge Exhaust 67 RHR B Test Return m 0 0 0 0 70 Instrument Air to Automatic Depressur 10 0 0 ,

O

?

ization System 73 RHR Shutdown Cooling Relief Valve 0 81 0 0 Discharge to Suppression Pool 75 RCIC Pump Turbine Exhaust Vacuum 20 0 0 0 Breaker 76B RHR Shutdown Cooling Suction Relief 0 0 40 0 Valve Discharge 77 RHR Heat Exchanger A Relief Valve m 0 0 0 Discharge to Suppression Pool 81 Reactor Recirculation Post-Accident 0 0 0 0 Sample 82 ILRT--Drywell Pressurization 0 0 0 0 83 RWCU Return to Feedwater 0 0 0 0 84 Drywell & Containment Chemical Waste 0 0 0 0 Sump Pump Discharge 85 Suppression Pool Cleanup Return 181 101 240 240 86 Demineralized Water Supply 0 0 0 0 87 RWCU Pump Suction from Reactor 504 0 0 0 ,

Recirculation Loops )

88 RWCU Pump Discharge to RWCU Heat 0 0 0 0 l Exchangers 101C Drywell Pressure Instrument 0 0 W W (Narrow Range) 101F Drywell Pressure Instrument 0 0 W W (Wide Range) 102D Drywell Pressure Instrument 20 10 W (4)

(Wide Range) 103D Containment Pressure Instrument 0 0 m (4)

(Wide Range) 104D Containment Pressure Instrument 0 0 W (4)

(Wide Range)

H : \AMALONE\ EXCEL 4 0\B&CRESLT.XLS Revised: 4/26/94

e Paga 3 of 4 APPENDIX IV (Continued)

Local Leak Rate Test Sunnaarv Data

, . h B and C Test Results Pneumatic Testing Minimum Pathway Leakaae (scem) l RFO4 RFO5 RFO6 RF06 i Penetration Descriotion As-Left As-Left As-Found As-Left 105A Containment Hydrogen Analyzer Sample 0 0 M) I4) ,

106A Drywell Hydrogen Analyzer Sample 0 0 14) W  ;

106B Drywell Hydrogen Analyzer Sample 0 0 (4) M) j Return 106E Containment Hydrogen Analyzer Sample 0 0 14) M)

Return 107B Containment Hydrogen Analyzer Sample 0 0 W (41 Return 107D Drywell Hydrogen Analyzer Sample 0 0 W (4) 107E Drywell Hydrogen Analyzer Sample 0 0 M) W Return 108A Containment Hydrogen Analyzer Sample 0 40 I4) 14) 109A Drywell Fission Product Monitor 0 0 MI,5 0

Sample 109B Drywell Fission Product Monitor 30 20 Wm 0 Sample Return 109D Containment Pressure Instrument 0 20 W 14)

(Narrow Range)  ;

110A ILRT Drywell Pressure Instrument 20 0 W 'W 110C ILRT Verification Flow Instruments. 0 0 W) M1 110F ILRT Containment Pressure Instrument 0 0 (4) 141 114 Suppression Pool Level Instrument 20 0 (4) W 116 Suppression Pool Level Instrument 0 0 Mi W 118 Suppression Pool Level Instrument 0 0 (4) 14) 120 Suppression Pool Level Instrument 0 20 (4) (4i ELECTRICAL PENETRATIONS I

201 Reactor Prot. System (Div 1) 0 0 0 0 202 Low Voltage Power (Div 1) 0 0' O O l

203 Instrumentation (ESF Div 1) 0 0 0 0

)

, 204 Instrumentation (Div 1) 0 0 0 0 l t 205 Neutron Monitoring 0 0 0 0 I 206 Low Volt Power & Cntl (Div 1) 0 0 0 0 207 Power & Control (BOP D) 0 0 0 0 208 Instrumentation (Div 1) 0 0 0 0 209 Low Voltage Power (BOP D) 0 0 0 0 210 Radiation Monitoring (BOP D) 0 0 0 0 211 Control (Div 1) 0 0 0 0 i 212 Instrumentation (Div 1) 0 0 0 0 213 Rod Position Ind. (Div 1) 0 0 0 0 i 214 T.I.P. (BOP D) 0 0 0 0 215 6.9 KV Pwr (Rx Recirc Pump A) 0 0 0 0 216 Misc Test Sys & Comm (BOP D) 0 0 0 0 217 Low Volt Power & Cntl (Div 1) 0 0 0 0 4 218 Neutron Monitoring (Div 3) 0 0 0 0 219 Instrumentation (BOP D) 0 0 0 0 220 Instrumentation (Div 3) -Cmptr 0 0 0 0 H:\AMALONE\ EXCEL 40\B&CRESLT.XLS Revised: 4/26/94

dk Paga 4 of 4 APPENDIX IV (Continued)

Local Leak Rate Test Su== mrv Data Tvoe B and C Test Results Pneumatic Testing 4

Minimum Pathway Leakaoe (scem)

RFO4 RFOS RFO6 RFO6  :

Penetration Descriotion As-Left As-Left As-Found As -Lef t 221 Control (BOP D) 0 0 0 0 222 Reactor Prot. System (Div 3) 0 0 0 0 223 Low Volt Power & Cntl (BOP D) 0 0 0 0 224 Instrumentation 0 0 0 0' 225 Low Voltage Power (BOP E) 0 0 0 0 226 Control (BOP E) 0 0 0 0 227 Instrumentation (BOP E) -Vib. 0 0 0 0 228 . Instrumentation (BOP E) TIC. 0 0 0 0 229 Low Volt Power & Cnti (Div 2) O. 0 0 0 230 Reactor Prot. System (Div 2) O. 0 0 0 231 Instrumentation (Div 2) 0 0 0 0 232 Instrumentation (Div 2) 0 0 0 0 233 Rod Position Ind. (Div 2) 0 0 0 0 234 CRD Hydraulic System (BOP E) 0 0 0 0 235 Instrumentation (Div 4) 0 0 0 0 237 Instrumentation (BOP E) -Cmptr 0 0 0 0 238- Reactor Prot. System (Div 4) 0 0 0 0 239 Control (Div 2) 0 0 0- . 0 240 Instrumentation . (BOP E) 0 0 0' O 241 Low Volt Power & Cnti (Div 2) 0 0 0 0 242 Low Voltage Power (BOP E) 0 0 0 0 243 Instrumentation (Div 4) 0 0 0 0 244 Low Voltage Power (Div 2) 0 0 0 0 245 Low Volt Power & Cnti (BOP E) 0 0 0 0 246 Radiation Monitoring (BOP E) 0 0 0 0 247 6.9 KV Pwr (Rx Recirc Pump B) 0 0 0 0 248 6.9 KV Pwr (Temp 480V--BOP E) 0 0 0 0 249 Control (BOP E) 0 0 0 0 TOTAL TYPE B AND C LEAKAGE 3,083 5,267 33,420 4,444 NOTES:

a) Includes only restricting orifice 0-ring seals and their connection valves. The remainder of the penetration is hydrostatically leak rate tested.

El Added to listing of pneumatically tested valves after RFOS, due to concern about potential leakage through RCIC turbine gland seals.

m Includes only heat exchanger drain valve. The remainder of the penetration is hydrostatically leak rate tested.

W) Removed from Type C testing requirements due to strict interpreta-tion of Appendix J requirements.

m The containment isolation valves in this penetration were open dur-ing the initial Type A test but were closed due to excessive leak-age through fission product monitor panel and post-accident sample panel and piping. Subsequent evaluation showed that these valves should be closed as part of the accident response actions. These valves will be Type C tested as required by Appendix J.

H:\AMALONE\ EXCEL 40\B&CRESLT.XLS Revised: 4/26/94

.a

dhk Page 1 of 1 APPENDII IV (Continued)

Local Leak Rate Test Summary Data IvDe C Test Results Hydrostatic Testing Minimum Pathway Leakage (ml/ min)

RF04 RF05 RF06 Penetration Description As-Left As-Left As-Left, 11 RHR A Pump Suction 0 1,600 2,700 12 RER B Pump Suction 2,800 2,400 450 RHR C Pump Suction 2,320 2,000 1,971 13 23 RHR A Test Return to Suppression Pool (1um num num 24 RHR C Test Return to Suppression Pool Gum (Zum Que 25 HPCS Pump Suction 40 34 2,588 27 HPCS Test Return to Suppression Pool Que Qum out RCIC Pump Suction 0 0 0 28 29 RCIC Turbine Exhaust 1,070 440 14) 30 LPCS Pump Suction 0 282 2,556 32 LPCS Test Return to Suppression Pool mum $Um Sum 46 RCIC Pump Minimum Flow Line to 0 0 0 Suppression Pool 48 RHR Heat Exchanger B Relief Valve m.m 330 (a la Discharge to Supp Pool 67 RHR B Test Return to Suppression Pool te,la (m.(m (sum 69 Refueling Water Transfer Pump 0 0 1,750

?

Suction from Suppression Pool 71 A LPCS Relief Valve Discharge to S S S Suppression Pool 71 B RHR C Relief Valve Discharge to m m G)

Supp Pool & Post-Acc Sample Return 77 RHR Heat Exchanger A Relief Valve H) 01 01 Discharge to Suppression Pool 89 Standby Service Water Supply A 0 0 m 90 Standby Service Water Return A 0 0 m 91 Standby Service Water Return B 0 0 m 90 Standby Service Water Return B 0 0 m 113 Suppression Pool Water Level Inst. 0 0 m 115 Suppression Pool Water Level Inst. 0 0 m 117 Suppression Pool Water Level Inst. 0 0 m 119 Suppression Pool Water Level Inst. 0 0 m TOTAL WATER LEAKAGE (ml/ min) 6,560 6,756 12,015 NOTES:

0) Penetration 23 and 77 leakage are included in Penetration 11 total, m Penetration 24 and 71B leakage are included in Penetration 13 total.

a) Penetration 27 leakage is included in Penetration 25 total.

(4) Added to listing of pneumatically tested valves after RFOS, due to concern about potential leakage through RCIC turbine gland seals.

S Penetration 32 and 71A leakage are included in Penetration 30 total.

Im Penetration 48 and 67 leakage are included in Penetration 12 total.

m Removed from Type C testing due to strict interpretation of Appendix J.

Im Does not include restricting orifice flanges and test connection valves, which are pneumatically leak rate tested.

Im Leakage shown is for heat exchanger vent valves which are tested separately.

H: \AMALONE\ EXCEL 4 0\H2ORESLT.XLS Revised: 4/26/94

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BCP Ttichnical Services, Inc.

l Grand Gulf Containment Building C3 1993 ILRT Final Report 4

APPENDIX V

SUMMARY

REPORT OF TYPE A, B, AND C TESTS WHICH FAILED TO MEET ACCEPTANCE CRITERIA OF 10CFR50, APPENDIX J i i

l l

d

4 Appendix V Summary Report of Type A, B and C Tests Which Failed to Meet Acceptatice Criteria of 10CFR50, Appendix J l

Introduction:

This summary report provides details of Type A, B and C tests which failed to meet the acceptance criteria of 10CFR50, Appendix J, Paragraphs Ill.B.3 and Ill.C.3.

The Type A Test which is described in this test was a successful test; therefore, there are no Type A tests since the last reported Type A test (completed on April 16,1989) which have failed to meet the acceptance requirements of 10CFR50, Appendix J, Paragraph lit. A.S.(b).(2).

The following summary table provides details of Type B and C tests which were considered to have failed to meet the acceptance criteria of 10CFR50, Appendix J, Paragraphs Ill.B.3 and Ill.C.3.

Discussion: The Type B and C tests reported in the summary table were performed during Refueling Outage No. 4 (RFO4) during October-November,1990, Refueling Outage No. 5 (RFOS) during April-May,1992 and Refueling Outage No. 6 (RFO6) during October ,

November,1993.  ?

Where the test is indicated to have failed due to being unable to pressurize the test volume to the required test pressure, the test volume could not be pressurized to the required minimum test pressure of 11.5 psig. The leakages were beyond the makeup capability of a 3/4-inch or 1-inch 1.D. hose supplying air between approximately 90 psig to 110 psig. Due to the inability to pressurize the volumes as required to measure the leakages, each of the leakages was conservatively assumed to be infinite.

Where the test is indicated to have failed due to the total Type B and C leakage being higher than the Appendix J limit of 0.60 L., the indicated leakage for the valve was a significant contributer in causing the total Type B and C leakage to exceed 126,100 standard cubic centimeters per minute (sccm), which is the currently accepted limit at Grand Gulf Unit 1. It should be noted that we have conservatively continued to keep track of the total Type B and C leakage, even though there were other tests that had ,

failed due to (assumed) infinite leakage, and that the total leakage of the remaining l components, ignoring those tests determined infinite, was above 126,100 sccm using i maximum pathway leakage methodology. l In each case where excessive leakage was determined, we took action immediately to correct the problem and performed another Type B or C test to verify that the corrective H:\AMALONE\WP\SUMFAIL6.APS y.1

)

+

Appendix V (Continued)

Summary Report of Type A, B and C Tests Which Failed to Meet Acceptance Criteria of 10CFR50, Appendix J (Continued) l action was sufficient. The measured leakages from the retests were added to the combined Type B and C test totals using maximum pathway leakage methodology.

All penetrations with at least two testable barriers in series had at least one of the barriers with acceptable leakage. Therefore, based on experiences during Refueling Outage No.

3 (RFO3) during March-April,1989, we are confident that combined Type B and C leakage, by minimum pathway leakage analysis, would have been less than 0.60 L, at all times when containment integrity was required.

For ISI inspection ports, which are Type B tested by pressurizing between the inboard and outboard seal gaskets, experience during the 1989 Type A test during RFO3 has shown that containment pressure causes the inboard gasket to seal, even though the Type B test may have failed. In this respect the Type B test is excessively conservative i and does not reflect the true sealing capability of the inspection port design during an accident.

Main steam isolation valves (MSIVs) (01B21F022A, B , C,and D and 01B21F028A, B, C and D) are Type C tested by pressurizing between the inboard and outboard valve disks.

Experience has shown that Type C test pressure (11.5 to 12.5 psig) applied against the underside of the inboard MSIV disk, is capable of lifting the disk from the fully leak-tight condition if the springs are weak or there are slight imperfections on the disk or body seating surfaces. In this respect the Type C test is excessively conservative and does not reflect the true sealing capability of the inboard MSIVs during an accident.

1 H:\AMALONE\WP\SUMFAIL6.AP5 V.2 l

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t APPENDIX V (Continued)

TYPE B AND C TESTS WHICH FAILED TO MEET 10CFR50. APPENDIX J. ACCEPTANCE CRITERIA Component Component Date of Description of Type of Date of 1.adqp Description Test Falure Description of Failure Corrective Action Retest Retest (sccm)

Number Q1E51PPN411 ISI inspection 10/03/90 Leakage was 11,987 scem, which contributed Replaced gasket and B 10/17/90 zero port to total Type B & C leakage > 0.60 L,, due tightened bolting per to loose bolting and a bad gasket. WO# 00026401.

01B21PPN427 ISI inspection 10/04/90 Leakage was 90,795 sccm, which contributed Replaced gasket and B 10/17/90 zero port to total Type B & C leakage > 0.60 L , tightened botting per due to loose bolting and a bad gasket. WO# 00026412.

01821PPN422A ISI inspection 10/05/90 Test volume could not be pressurized for Replaced gasket and B 10/10/90 zero port Type B test due to loose botting and a bad tightened botting per gasket. WO# 00026593.

12* motor 10/06/90 Leakage was 13.972 sccm, which contributed Reworked valve actuator C 10/07/90 zero Q1E22F004 operated gate to total Type B & C leakage > 0.60 L,, per WO# 00025564.

valve because valve would not close property.

24' plug check 10/10/90 Test volume could not be pressurized for Replaced valve cap per C 10/10/90 302 01B21F010A valve Type C test due to corrosion on bonnet cap. WO# 00026505.

1.5" motor Leakage was 17,518 sccm, which contributed Replaced valve stem & C 10/26/90 zero 01821F067B 10/18/90 operated globe to total Type B & C leakage > 0.60 L , due disc per WO# 00027340.

valve to steam cuts on the disc.

i 28* air operated Leakage was 80,429 sccm, which contributed Valve was fast-stroked C 10/26/90 2004 Q1821F022C 10/19/90 i globe valve with to total Type B & C leakage > 0.60 L,, be- closed.

poppet cause the valve was not fast-stroked closed.

l 28" air operated Leakage was 17,152 sccm, which contributed Rebuilt valve actuator C 10/25/90 9244 01821F022D 10/22/90 globe valve with to total Type B & C leakage > 0.60 L,, per WO# 00027436.

poppet because the valve was not closing propedy.

y-3 H:\AMALONE\WP\LRT_FAILAP5

( _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ /

)

w APPENDIX V (Continued)

TYPE B AND C TESTS WHICH FAILED TO MEET 10CFR50. APPENDtX J. ACCEPTANCE CRITERIA Component Component Date of Description of Type of Date of Ladeqp Test Failure Description of Failure Corrective Action Retest Retest (secm) l Number Descriotion 1* ball check Test volume could not be pressurtzed for - Replaced valve per C 05/28/92 zero Q1M23Y001 05/27/92 valve on person- Type C test of 1* check valve due to dirt WO# 00073567.

nel aidock on valve seat.

Q1821F028D 28" air operated 05/08/92 Leakage was 23,920 sccm, which contributed Replaced valve stem and C 05/16/92 zero globe valve with to total Type B & C leakage > 0.60 L,. due cleaned intemals per poppet to dirty seat and poppet- WO# 00072471.

4* air operated Leakage was 13.325 sccm, which contributed Replaced valve disc per C 05/28/92 zero 01G36G101 05/20/92 gate valve to total Type B & C leakage > 0.60 L , due - WO# 00073229.

to disc erosion-12" air operated 04/13/92 Leakage was 17,321 sccm, which contributed Replaced packing per C 05/31/92 2423 Q1P60F010 gate valve to total Type B & C leakage > 0.60 L,. due WO# 00070514.

to a packing leak.

24" plug check Test volume could not be pressurized for Replaced reslient seat C 10/15/93 40 01B21F010A 10/01/93 valve Type C test because disc did not fully seat. - per WO# 00102763 and repaired disk guide per WO# 00105509 24* swing check Test volume could not be pressurized for Replaced restient seat C 10/16/93 3000 Q1B21F032A 10/01/93 valve Type C test. Reason for fature could not per WO# 00102761.

be determined Q1B21F028C 28" air operated 10/08/93 Test volume could not be pressurized for Replaced stem and lapped C 10/31/93 1205 globe valve with Type C test due to wom area on main body seat per WO# 00109176.

poppet seat.

5 y.4 H:\AMALONE\WP\LRT FAILAPS v _______ . - _ _ _ _ - _ __-____ - _ _ _ _ _ _ . _ -__ _ __ _ _ - ____ _ _ _ _ _ _ -_ . i

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APPENDIX V (Continued)

TYPE B AND C TESTS WHICH FAILED TO MEET 10CFR50. APPENDIX J. ACCEPTANCE CRITERIA Component Component Date of Description of Type of Date of I.adegy Description Test Failure Description of Failure Corrective Action Retest Retest (sccm)

Number 28" air operated Leakage was 34,937 sccm, which contributed Replaced actuator per C 10/21/93 4500 01B21F022A 10/09/93 globe valve with to total Type B & C leakage > 0.60 L , due WO# 00105537 (scheduled poppet to suspected degradation of actuator (valve Preventive Maintenance).

is leak rate tested in reverse direction).

01821F022C 28* air operated 10/10/93 Leakage was 26,333 sccm, which contributed Replaced actuator per C 10/31/93 8837 globe valve with to total Type B & C leakage > 0.60 L,, due WO# 00105557 (scheduled poppet to suspected degradation of actuator (valve Preventive Maintenance).

is leak rate tested in reverse direction).

01B21F0108 24" plug check 10/18/93 Leakage was 97,208 sccm, which contributed Replaced resilient seat C 10/29/93 zero valve to total Type B & C leakage > 0.60 L , per WO# 00107579 and because of damaged restient seat and wom repaired disk guide per guide on disk plug. WO# 00109243.

01B21F032B 24" swing check 10/19/93 Test volume could not be pressurized for Replaced restient seat C 10/29/93 200 valve Type C test because of deteriorated and per WO# 00107699.

partiaNy missing restient seat.

01E12F041C 12* testable 10/23/93 Test volume could not be pressurized for Exercised disk several C 10/24/93 1963 swing check valve Type C test because of apparent intemal times and flushed valve binding. with water per WO# 00106209 01G36G101 4" air operated 10/26/93 Leakage was 10,601 sccm, which contributed Replaced disk per WO# C 11/08/93 zero gate valve to total Type B & C leakage > 0.60 L , 00109753 because of damaged seating surfaces on disk.

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