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IT CORPORATION <br /> Mr. J. Kelly Williamson <br /> Kayo Oil Company <br /> April 18, 1985 <br /> Page 2 <br /> Table 3 presents a simple model of the volume of soil that is contami- <br /> nated at each five-foot level under the site. It presents a worst case <br /> volume for the amount of gasoline in the sail of 84 gallons. This does <br /> not include the volume of gasoline in the soil between the 15 and and <br /> 35-foot levels, where we have no data. iowever, it does . not appear <br /> likely that the total contamination could be more than 100 gallons of <br /> gasoline. The laboratory report showing the BTX values used in the <br /> calculation is attached to this report. <br /> i <br /> METHOD FOR TOTAL PRODUCT CALCULATIONS <br /> A simplistic calculation of a worst case scenario to approximate the <br /> total volume of petroleum products in the oil at each of the sites was <br /> completed. The soils at each site were divided into zones five feet <br /> thick from the surface to the bottom of the borehole. Using the bore- <br /> hole data/LEL readings, the lateral exte t of contamination in each <br /> five-foot thick zone was delineated and the "surface" area of this zone <br /> approximated. Since each layer is five feet thick, the volume of con- <br /> taminated soil for each layer was then calculated by multiplying the <br /> "surface area" by 5. The volumes of the individual levels were then <br /> summed, and the worst case volume of hydr carbons present was calcula- <br /> ted. <br /> The total wet weight ,of the soil , assuming 12 percent moisture content, <br /> and then the total dry weight in kilograms was calculated. The highest <br /> hydrocarbon concentration (sum of xylene, benzene and toluene) for each <br /> site was used to calculate the amount of gasoline in the ground. Assum- <br /> ing a specific weight of approximately 0.6 /cc for the hydrocarbons and <br /> 998.6 kgm/cubic meter for water at 50°F, , he volume of gasoline in the <br /> soil was calculated. The calculations are recapped below; <br /> (TOTAL VOLUME OF DRY SOIL)*(125 LBS. PER CUBIC FOOT)= <br /> TOTAL UNIT WEIGHT <br /> (TOTAL UNIT WT)(0.454 kgm/lbs)(1)1.12-soil moisture 12%) = <br /> TOTAL DRY WEIGHT SOIL <br /> (TOTAL DRY WEIGHT SOIL) (TOTAL H OROCARBONS IN ppm) _ <br /> TOTAL HYDROCARBONS in mass <br /> (TOTAL HYDROCARBONS IN MASS)/(0. *998.6) _ <br /> TOTAL HYDROCARBON VOLUME in cubs meters i <br /> CONVERT CUBIC METERS TO LITERS Of HYDROCARBONS <br /> (TOTAL HYDROCARBONS in liters)(i) 3.78)= <br /> TOTAL HYDROCARBONS in gallons <br /> In addition, calculations were completed and are shown in graphical <br /> form, Plate 1, which shows the sensitiv ty of the final hydrocarbon <br />