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VM%.o 1 lG%on1-41t.#HL t5ULl-C 1114 iF V./ <br /> Oxygen Release Compound, ORC® <br /> Quantitative Guidelines for Soil <br /> Remediation Applications (Biopiles) <br /> If the qualitative need to use ORC has been established there are several ways to calculate use rates <br /> One must know the weight of soil either by direct measurement or by soil type estimate Since ORC is <br /> most appropriate for heavy clay soils a value of 3000 lbs/cubic yard will be used in this example Under <br /> these conditions one would need 3 lbs of ORC for every 1% of ORC applied on a wt/wt basis, noting <br /> that ORC is 8% oxygen by weight <br /> Calculation of the hydrocarbons that can be remediated from the oxygen applied through ORC is not <br /> straightforward, unexpectedly lugh results have been noted in field tests Given a straight calculation <br /> based on the standard 3 1 ratio, 3 pounds or 1362 grams of ORC with 8%.axygen, would be able to <br /> remediate 36 grams of hydrocarbons Tlus would be enough to remediate 27 parts per million(ppm) <br /> of hydrocarbon in a cubic yard of the soil as described If the ratio approached 1 I, which more <br /> realistically includes some biological incorporation of carbon in addition to nuneralization to carbon <br /> dioxide, there would be a capacity to remediate about 80 ppm of hydrocarbon for every 1% of ORC <br /> used on a wt/wt basis <br /> In a test of ORC on the remediation of weathered crude oil, about 7000 ppm of hydrocarbon was <br /> rernediated in 200 days (1 application) with 1% ORC By the above calculations, even under the best <br /> of conditions (1 1 ratio), only 800 ppm should have been remediated One of the reasons the higher - <br /> remediation rate may have occurred is related to the physical nature of ORC Because it is a very fine <br /> insoluble particle it has the capability of being intimately mixed throughout a tight soil mass The result <br /> is that one has countless nucxon-sized particles releasing oxygen simultaneously effecting a mass transfer <br /> phenomenon for oxygen that is not possible with forced air Tins generates the observed "yeast effect," <br /> in which the pile expands <br /> What may be happening is that numerous microchannels are being created such that ambient air can more <br /> readily permeate the pile It must be noted that even though a volume of ambient air entered the system <br /> upon mixing,the experiments were done under saturated conditions to effect an anaerobic environment <br /> With the extant oxygen being flushed out,the remediation effects could have been due to a combination <br /> of ORC and the facilitated diffusion of ambient oxygen as mediated by the ORC induced yeast effect <br /> Practically spealang, under the right conditions ORC would best be used in the remediation of several <br /> thousand ppm of hydrocarbons, either itutially in a low contamination situation, or as a polishing agent <br /> after basic forced air applications Concentrations of hydrocarbons that make the soil oily would be hard <br /> to manage as the insoluble ORC particle can become obstructed by coating At a cost of$9 per pound <br /> for ORC,a typical application of 5%ORC which is appropriate for about 3000 - 4000 ppm, would cost <br /> $135 per cubic yard in a 3000 lb/cu yd soil REGENESI5 personnel are available to assist you <br /> with a specific analysis of your needs <br /> REGEN ES IS ----------------------------------------------------------------------------------------- <br /> Bioremediation Products 27130A Paseo Espada, Ste 1407, San Juan Capistrano,CA 92675 <br /> Phone 714-443-3136 Fax 714443-3140 <br />