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R603 UPDATE-16 4/29/93 <br /> WEGE' s portable laboratory and analyzed in WEGE' s portable <br /> laboratory utilizing the Photovac 10s50 PID-GC and Shimadzu FID- <br /> GC. These samples were analyzed for TFH and BTEX along with <br /> screening for Tetrachloroethylene (PCE) , Trichloroethylene (TCE) <br /> and 1, 2 , -Dichloroethane (DCE) using a Shimadzu GC-FID <br /> chromatograph mounted permanently in WEGE' s portable laboratory <br /> These compounds have the following retention times in the above <br /> chromatograph, DCE = 2 . 079 minutes, TCE = 3 023 minutes and PCE <br /> 3 75 minutes . Before sampling the wells or the system, a <br /> calibrant made from fresh gasoline is infected into the GC-PID <br /> and GC-FID. The resulting chromatograms has numerous responses <br /> The microprocessor of the GC-PID and GC-FID computes the area per <br /> response in volt seconds and assigns a peak number and retention <br /> time The sum of all the responses are then used to obtain a <br /> mg/L per volt second calibrant factor, which is used to calculate <br /> mg/L as gasoline vapor from each analysis produced. Pounds per <br /> day can be computed using these mg/L values produced from the <br /> analysis of the different vapor recovery wells, the influent to <br /> the oxidizer, the pressure differential created at the orifice to <br /> determine flow rates for each well, and the influent to the <br /> oxidizer. The pounds per day values for each well and the <br /> influent are averaged with the preceding site visit' s pound per <br /> day value . This figure is then multiplied by the number of hours <br /> the system operated between visits, to estimate the total pounds <br /> each well and the system has removed for that time period This <br /> figure is added to the accumulated poundage of the previous visit <br /> to update the total pounds removed. The effluent sample is <br /> computed in the same fashion, but also includes natural gas flow <br /> along with the influent orifice flow rate. <br /> SAMPLING VAPOR STREAMS <br /> The vapor samples are obtained by attaching a dedicated air tight <br /> poly tubing to a sample port on the vapor recovery manifold (on <br /> the well side of the orifice plate) The tubing is attached to a <br /> air tight fitting that connects a valved one liter tedlar bag <br /> which is placed inside a air tight sample box The sample port <br /> is opened and a vacuum is placed on the tedlar bag inside the <br /> sample box, falling the tedlar bag with the vapor stream. Once <br /> full the sample port is closed, the vacuaot as witiidrarin and the <br /> tedlar bag valve is closed, sealing the vapor stream sample <br /> inside the tedlar bag A small dedicated needle attached to a <br /> dedicated 1 cc syringe is then inserted into the septum of the <br /> tedlar bag to obtain the sample to be infected into the PID-GC <br /> and FID-GC. The lcc syringe is purged numerous tames before <br /> filling it with the sample All but 0 5 cc of the sample is <br /> effected into the air before injecting the remaining 0 . 5 cc <br /> syringe sample into the chromatographs (the calibrant infection <br /> is 0 5 cc) . Once the chromatogram is recorded an instrument <br /> blank is run prior to the next sample . The instrument blank <br /> indicates if residual peaks are being carried onto the next <br /> analysis <br /> Prior to sampling an individual vapor stream, flow rates are <br /> recorded and vacuum influent readings are obtained from the wells <br /> PAGE 5 <br />