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ARCHIVED REPORTS XR0006540
EnvironmentalHealth
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EHD Program Facility Records by Street Name
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P
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PACIFIC
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6425
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2900 - Site Mitigation Program
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PR0519189
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ARCHIVED REPORTS XR0006540
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Last modified
8/21/2019 4:12:33 PM
Creation date
8/21/2019 3:08:58 PM
Metadata
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Template:
EHD - Public
ProgramCode
2900 - Site Mitigation Program
File Section
ARCHIVED REPORTS
FileName_PostFix
XR0006540
RECORD_ID
PR0519189
PE
2950
FACILITY_ID
FA0014347
FACILITY_NAME
CURRENTLY VACANT
STREET_NUMBER
6425
STREET_NAME
PACIFIC
STREET_TYPE
AVE
City
STOCKTON
Zip
95207
APN
09741031
CURRENT_STATUS
02
SITE_LOCATION
6425 PACIFIC AVE
P_LOCATION
01
QC Status
Approved
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EHD - Public
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CALCULATIONS <br /> To calculate the pounds (lb) per day the concentration is multiplied <br /> by the volume of air produced in one day <br /> The lab reports the Concentrations (C) of the air sampling in <br /> ug/liter The first step is to convert this value to lbs/cf (pounds <br /> per cubic foot) Jug/1 x 0 . 0000018/ug x 0 . 0022051g/g x 28 . 321/cf - <br /> 0 0000000621lb/cf <br /> The volume of air produced in one day, equals the flow rate (Q) x the <br /> time of flow <br /> V = Q x T = cf/day = cf/min x 1440mi.n/day <br /> The volume must be corrected to standard temperature and pressure <br /> (STP) <br /> P = Pressure = 14 7 lb/jn2 @ STP <br /> V = Volume cf <br /> T = Temperature in degrees above absolute Zero = 491 58OR @ STP <br /> Using the Ideal Gas Law P1V1/T1 = P2V2/T2 <br /> Solving for V2 =P1V1T2/P2T1 <br /> Assuming PI = P2 = 14 7 lb/in2 , P cancels from the equation leaving <br /> . V2 = V1T2/T1 . <br /> V1 = Q cf/m x 1440 min/day <br /> T2 = 491 580R T1 = 459 58 + TOF at sight <br /> V2 = Q cf/min x 1440 min/day x 491 58oR/ (459 580 + TOF) <br /> X lb/day = C ug/l x 0 0000000621 lb 1/ug cf x Q cf/min x 1440 <br /> min/day x 491 58oR/ (459 580 + TOF) <br /> Q for the Influent sample = The well flow rate + the air flow <br /> Q for the Effluent = The well flow + the air flow + the fuel flow <br /> rate <br /> The fuel flow rate must be corrected to account for the change in <br /> volume from combustion <br /> Since the gas volume depends on the number of molecules present the <br /> reaction of propane with oxygen produces an increase in volume The <br /> reaction, 1C3H8 + 502 -> 3CO2 + 4H2O, increases the number of <br /> molecules from 6 to 7 per molecule of propane This effectively <br /> means that after combustion the volume of flow resulting from the <br /> propane is double the propane flow rate The reaction of methane <br /> (Natural Gas) and oxygen does not produce a net change in volume, <br /> CH4 + 2 02 -> CO2 + 2 H2O; therefore a correction for combustion <br /> does not need to be made when methane is burned <br /> page 5 of R603 , 03/01/93 <br />
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