Abstract:
Method and apparatus for removing organic contaminants from contaminated materials including a sealed hopper, a heated vapor stripping conveyor sealed from atmospheric air to vapor strip the contaminants from the material, a sealed conveyor to convey the material in sealed condition from the hopper to the vapor stripping conveyor, a supply of non-oxidative gases at a controlled temperature for introduction into the vapor stripping conveyor, an introduction portal for the non-oxidative gases into the vapor stripping conveyor, an exit for removing the non-oxidative gases from the conveyor and located to cause the non-oxidative gases to cross currently sweep over the material to convey contaminants and moisture stripped from the material out of the vapor stripping conveyor, and a controller for controlling the flow rate and temperature of the non-oxidative gases as they flow through the vapor stripping conveyor and to prevent undue surface drying of the material as the material passes through the vapor stripping conveyor.

Description:
BACKGROUND OF THE INVENTION 
     This invention relates to a method and apparatus for decontaminating soil and waste materials, particularly to a method and apparatus for removing volatile and semivolatile hazardous organic contaminants from soil, municipal, chemical and refinery sludges and other particulate materials. 
     DISCUSSION OF THE PRIOR ART 
     With increased environmental awareness and discovery of many landfills, dumps sites and the like containing contaminated soils and waste materials, a number of soil decontamination methods and apparatus have been proposed. These include systems disclosed in U.S. Pat. Nos. 4,738,206, 4,782,625 and 4,864,942. It is vitally important that many of these contaminated areas be freed from hazardous contaminants because of their potential toxicity. Many sites are so close to areas inhabited by humans that direct contact with the soil or waste materials or ingestion of fugitive vapors can be lethal. Also, many sites have the potential to leach hazardous contaminants into ground water supplies, thereby posing further danger. It has accordingly become necessary to develop methods which effectively remove all of the contaminants in a cost efficient manner and dispose of them in an environmentally safe manner. 
     U.S. Pat. No. 4,738,206, issued to one of the inventors hereof and owned by the assignee hereof, discloses an apparatus and method for removing volatile organic contaminants containing moisture by sealing the soil in a stripping conveyor against contact with air and countercurrently vapor stripping the contaminants at a temperature below the boiling points of the contaminants. This method and apparatus has proven to be quite effective for decontaminating soils in many situations. 
     U.S. Pat. No. 4,782,625 discloses a mobile decontamination apparatus for removing halogenated hydrocarbons, petroleum hydrocarbon and derivatives of petroleum hydrocarbons from soil. However, this apparatus suffers the severe problem of being open to the environment. Open systems can be quite hazardous and frequently cause difficulties in obtaining proper permitting for operation thereof. 
     U.S. Pat. No. 4,864,942 discloses a process and apparatus for thermally separating organic contaminants such as PCB&#39;s from soils and sludges. This apparatus provides inadequate disposition of vaporized organic contaminants after volatilization from the soils and sludges. 
     Other prior art known to applicant in completely different areas of endeavor include U.S. Pat. Nos. 2,753,159; 2,731,241; 3,751,267; 4,098,200; 4,139,462; 4,167,909; 4,319,410; 4,330,946; 4,411,074; 4,504,222; 4,544,374; 4,628,828; 4,875,420 and 4,881,473. 
     OBJECTS OF THE INVENTION 
     It is an object of the invention to provide a method and apparatus for removing volatile and semivolatile hazardous organic contaminants from soil and sediments. 
     It is a further object of the invention to provide a method and apparatus for removing volatile and semivolatile hazardous organic contaminants from waste materials such as municipal, refinery and chemical sludges and other particulate wastes. 
     It is another object of the invention to provide a method and apparatus capable of decontaminating large quantities of natural soil without transporting the soil to remote locations. 
     It is yet another object of the invention to decontaminate soil in a manner which poses no environmental risk to surrounding areas and is free from danger of explosion of fire. 
     Other objects and advantages of the invention will become apparent to those skilled in the art from the drawings, the detailed description of preferred embodiments and the appended claims. 
     SUMMARY OF THE INVENTION 
     This invention provides a method for removing volatile organic contaminants from soil and waste materials including removing contaminated material to be treated from its existing location, transporting and placing the contaminated material into a hopper wherein the hopper is substantially sealed from the atmosphere to prevent fugitive emissions of the contaminants from escaping into the atmosphere. The contaminated material is then conveyed under sealed conditions into a heated vapor stripping conveyor. The contaminated material is conveyed under sealed conditions along the vapor stripping conveyor to heat the contaminated material and thereby cause moisture in the material and the contaminants to be stripped away. 
     At the same time the contaminated material is conveyed along the vapor stripping conveyor, non-oxidizing gases are swept across the surface of the material to carry volatilized contaminants and moisture emanating from the material across and away from the material. The cross-sweep of non-oxidizing gas is maintained at a rate of flow and temperature to prevent undue surface drying of the material as the material passes through the conveyor. 
     The invention further provides an apparatus for removing organic contaminants from the contaminated material including a hopper, means for sealing the material from atmospheric air, a heated vapor stripping conveyor sealed from the atmospheric air to vapor strip the volatile contaminants from the material and means for conveying the material in a sealed condition from the hopper to the vapor stripping conveyor. 
     The apparatus further includes means for supplying non-oxidative gases at a temperature greater than ambient to the vapor stripping conveyor, means for introducing the non-oxidative gases into the vapor stripping conveyor and means for removing the non-oxidative gases from the conveyor located to cause the non-oxidative gases to cross-currently sweep over the material to convey volatile contaminants stripped from the material out of the vapor stripping conveyor. The apparatus still further includes means for controlling the flow rate and temperature of the non-oxidative gases as they flow through the vapor stripping conveyor and across the material to prevent undue surface drying of the material as it passes through the vapor stripping conveyor. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 represents a schematic diagram showing one preferred form according to which the invention may be practiced. 
     FIG. 2 shows a schematic top plan view of a vapor stripping material conveyor utilized in accordance with aspects of the invention. 
     FIG. 3 represents a schematic diagram showing another preferred form according to which the invention may be practiced. 
     FIG. 4 is a schematic diagram showing preferred vapor treatment apparatus utilized in accordance with the invention. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     Although a particular form of apparatus and method has been selected for illustration in the drawings, and although specific terms will be used in the specification, for the sake of clarity in describing the apparatus and method steps shown, the scope of this invention is defined in the appended claims and is not intended to be limited either by the drawings selected or the terms used in the specification or abstract. When referring to contaminated soil or waste materials such as municipal, refinery or chemical sludges or particulates, waterway and lagoon sediments and the like the terms &#34;contaminated materials&#34; or &#34;materials&#34; will be used hereinafter for the sake of convenience. 
     Referring now to the drawings in general and FIG. 1 in particular, one embodiment of a decontamination system 10 is shown. Material removing conveyor 12, which may be a conventional belt conveyor, belt conveyor with scoops, front and loader, backhoe or the like, removes contaminated material 14 from its existing location and places it in container 16. Container 16 connects to feeder 18, which connects to sealed conveyor 20. Contaminated material 14 travels under sealed condition to the front end 22 of vapor stripping conveyor 24 by way of hopper 23. Vapor stripping conveyor 24 contains a stripping conveyor 26 (see FIG. 2). The stripping conveyor 26 connects to heat transfer fluid supply line 28 and fluid return line. Fluid supply line 28 and fluid return line 30 connect to fluid heater 32. 
     Vapor stripping conveyor 24 is shown with four non-oxidative gas feed lines 33, 34, 36, 38 connected to one side thereof. The feed lines are positioned substantially equally spaced apart along the longitudinal axis of vapor stripping conveyor 24 and are similarly positioned about mid-way along the vertical direction of vapor stripping conveyor 24. Non-oxidative gas feed lines 33, 34, 36, 38 connect to a non-oxidative gas supply line 40, with one branch 40a connecting to heater 32 and another branch 40b connecting to non-oxidative gas supply fan or blower 42. Non-oxidative gas supply blower 42 connects to non-oxidative gas source 44. Valve 43 may be opened or closed to control the rate of non-oxidative gas channelled to blower 42. 
     The side of vapor stripping conveyor 24 opposite non-oxidative gas feed lines 33, 34, 36, 38 has four vapor exhaust lines 46, 48, 50, 52 (see FIG. 2) which connect to vapor exhaust manifold 54. Supplemental vapor exhaust conduit 56 extends between sealed conveyor 20 and vapor exhaust manifold 54. Vapor exhaust manifold 54 also connects to vapor exhaust blower 58, which connects to vapor exhaust cleaner apparatus 60. Vapor exhaust cleaner apparatus 60 has exhaust purge conduit 62 and exhaust purge recycle conduit 64 connected downstream. Exhaust purge recycle conduit 64 connects to non-oxidative gas supply 44. Heater 32 has air intake line 66 to supply combustion air and exhaust line 68 to exhaust combustion gases to the air or to vapor stripping conveyor 24. Decontaminated material exits the bottom of vapor stripping conveyor 24 at chute 70. 
     FIG. 2 shows one preferred embodiment of a vapor stripping conveyor 24 which may be used to practice the invention. Vapor stripping conveyor 24 has non-oxidative gas feed lines 33, 34, 36, 38 connected on one side and vapor exhaust lines 46, 48, 50, 52 connected on the other side. The non-oxidative gas feed lines and vapor exhaust lines are shown entering and exiting vapor stripping conveyor 24 at essentially right angles to the direction of travel of the material. Non-oxidative gas feed lines 33, 34, 36, 38 connect to non-oxidative gas supply line 40 (FIG. 1) and vapor exhaust lines 46, 48, 50, 52 connect to vapor exhaust conduit 54, also shown in FIG. 1. 
     The interior of vapor stripping conveyor 24 shows two stripping conveyors 26, which include hollow shafts 72 and hollow rods 72 and flights 74. These conveyors are rotated by a motor and gear reducer 73 (shown schematically). The dashed lines on front end 22 of vapor stripping conveyor 24 represent the entry point of sealed hopper 23 from above, while the dashed lines on the other end of vapor stripping conveyor 24 represent the exit point for the contaminated material flowing through chute 70. 
     FIG. 3 shows a schematic view of another preferred embodiment of the invention. The upper portion labelled &#34;A&#34; of the apparatus is similar to that shown in FIG. 1 of the drawings and contains substantially the same numbers applied to the various component portions thereof. In particular, contaminated material 14 travels along conveyor 12 and into container 16. Container 16 connects to feeder 18, which sealingly connects to sealed conveyor 20. The other end of sealed conveyor 20 connects to hopper 23 which sealingly connects to vapor stripping conveyor 24. Vapor stripping conveyor 24 further connects to heat transfer fluid supply line 28, non-oxidative gas feed lines 33, 34, 36, 38 and vapor exhaust lines 46, 48, 50, 52. 
     Also, supplemental vapor exhaust conduit 56 extends between sealed conveyor 20 and vapor exhaust manifold 54. Vapor exhaust manifold 54 extends between vapor exhaust blower 58 and vapor exhaust lines 46, 48, 50, 52. Similarly, vapor exhaust cleaner apparatus 60 connects between vapor exhaust blower 58 and exhaust purge recycle conduit 64. Exhaust purge recycle conduit 64 also connects to non-oxidative gas supply line 40. 
     The portion of FIG. 3 labelled &#34;B&#34; is similar to the apparatus shown in portion &#34;A&#34;. A vapor stripping conveyor 124 is shown connected to vapor stripping conveyor 24 through a transfer chute 76. One end of transfer chute 76 connects to the bottom of vapor stripping conveyor 24 and to the top of vapor stripping conveyor 124. Vapor stripping conveyor 124 is shown having four non-oxidative gas feed lines 133, 134, 136, 138 and four vapor exhaust lines 146, 148, 150, 152. Vapor exhaust lines 146, 148, 150, 152 connect to vapor exhaust manifold 154, which in turn connects to vapor exhaust manifold 54. Chute 170 connects to the bottom of vapor stripping conveyor 124 at the end opposing transfer chute 176. 
     Vapor stripping conveyor 124 further connects to a heat transfer fluid supply line 128, which connects to heater 32 and fluid return line 30, which also connects to heater 32. Non-oxidative gas feed lines 133, 134, 136, 138 all connect to non-oxidative gas supply line 140, which connects to branches 40a and 40b. Non-oxidative gas supply blower 42 extends between branch 40b and non-oxidative gas source 44. 
     FIG. 4 is an exploded representation of one preferred form of exhaust cleaner apparatus 60. The number 61 represents a burner for burning organics received from stripping conveyor 24 and vapor exhaust blower 58. Condenser and carbon absorber 67 connects to blower 58 and condenses some of the hazardous constituents. Catalytic thermal destructor 65 connects to blower 58 and receives exhaust gases from stripping conveyor 24. Wet scrubber 63 connects to burner 61 and catalytic thermal destructor 65 to further treat the exhausted gases. 
     Referring now to FIGS. 1 and 2 of the drawings, one preferred method of decontaminating material is in accordance with aspects of the invention will now be illustrated. As shown in FIG. 1, contaminated material is removed from its existing location by well known conventional means as illustrated by removing conveyor 12 and into container 16. Feeder 18, which may be a pug mill, shredder, screen or the like, creates a seal between container 16 and sealed conveyor 20, accepts material from container 16 and deposits it in sealed conveyor 20. Contaminated material travels through sealed conveyor 20 upwardly into hopper 23 and then into the front end 22 of vapor stripping conveyor 24. Contaminated material 14 spills downwardly through the top of vapor stripping conveyor 24 and engages stripping conveyors 26. Stripping conveyors 26 are rotated by conventional means well known in the art and cause contaminated material 14 to move along the length of vapor stripping conveyor 24. 
     Stripping conveyors 26 receive heated heat transfer fluid, such as air, oil, water, steam, eutectic salts, Dowtherm®, gas and the like through hollow shafts 72 and optionally through flights 74. Heated heat transfer fluid is received from fluid supply line 28, which is heated in heater 32. The heated heat transfer fluid travels along hollow shafts 72 and exits vapor stripping conveyor 24 through fluid return line 30, which returns cooled heat transfer fluid to heater 32 for reheating. It is also possible for heat transfer fluid to be directed into the exterior walls and/or bottom of vapor stripping conveyor 24 if it is constructed to that capacity and if desired. This is especially true in the event conveyors, such as continuous belts or screens or the like, are substituted for rotating screw conveyors. Flowing heated heat transfer fluid through the exterior walls and/or bottom increases the heated surface exposed to the material, thereby enhancing vapor stripping in apparatus utilizing rotating screw conveyors and acting as the primary heat transfer vehicle in the case of alternate conveyors. 
     Contaminated material 14 travels through vapor stripping conveyor 24 by action of the rotating flights 74 and is heated as it progresses from one end to the other by absorbing heat from hollow shafts 72, flights 74 and optionally from the exterior walls and/or bottom of vapor stripping conveyor 24. Absorbed heat causes volatile and semivolatile hazardous organic contaminants contained within the material, as well as moisture contained in the material, to vaporize at points below their boiling temperatures. The combined vaporized organic compounds and water vapor travel upwardly into the open space within vapor stripping conveyor 24 above the material. 
     Because of the potentially toxic nature of the vaporized organic contaminants, it is necessary to ensure that all of the vaporized organics are carried away from vapor stripping conveyor 24. This has proven to be a difficult task for several reasons. One problem has been the need to ensure that vapor stripping conveyor 24 does not leak or permit fugitive toxic vapors to escape into the atmosphere. 
     Another severe problem encountered is the tendency of the material to dry out upon heating. However, this tendency defeats the goal of driving out substantially all (such as 99.99%, for example) of the hazardous organic contaminants contained in the material. Often in prior art apparatus, a dry crust tends to form on the surface of the material due to rapid heating on outer portions thereof, which forms into a vapor impermeable capsule around inner portions of the material. This prevents proper heating of all of the soil and results in trapped hazardous organics within the soil, thereby defeating the decontamination objective. 
     Yet another problem encountered in the prior art has been the extremely high flammability of many of the volatilized contaminants, especially under elevated temperatures. The danger of explosion has proven to be very real. 
     It has been surprisingly discovered that precise channeling of non-oxidative gases over the surface of the material solves the problem of undue drying of the surface portion of the material, which permits substantially all of the hazardous organic contaminants within the material to volatilize and escape. Use of non-oxidative gas has also virtually eliminated the possibility of fire and/or explosion despite the presence of substantial quantities of vaporized, highly flammable organic compounds within the stripping conveyor. It has further been surprisingly discovered that the particular manner of channeling gases inside the conveyor prevents fugitive vapor emissions from vapor stripping conveyor 24. 
     To solve the problems outlined above, non-oxidative gases, such as nitrogen, argon, steam and carbon dioxide, for example, are channeled from a non-oxidative gas supply in a special precise manner into vapor stripping conveyor 24. As shown in FIG. 1, gases such as nitrogen, argon or carbon dioxide and the like may be supplied from an on site non-oxidative gas source 44, through non-oxidative gas supply blower 42, into branch 40b, through non-oxidative gas supply line 40 and into non-oxidative gas feed lines 33, 34, 36, 38. These gases are preferably supplied at temperatures greater than ambient. In the alternative, exhaust gases generated by heater 32 in heating fluids for passage through vapor stripping conveyor 24 may be channeled through branch 40a and into non-oxidative gas supply line 40. 
     As shown in FIG. 2, non-oxidative gases are swept into vapor stripping conveyor 24 through openings in the side wall of the conveyor. The openings are preferably positioned at a point slightly above the surface of the material as it travels along the length of the conveyor. The non-oxidative gases are blown directly across the top of the material and received by vapor exhaust lines 46, 48, 50, 52 wherein they exit vapor stripping conveyor 24. Although the drawings show introduction and exit of the non-oxidative gases at right angles to the direction of travel of the material, such is not required so long as the non-oxidative gases sweep across the soil from side to side. It is possible to introduce and remove the non-oxidative gases at angles other than right angles so long as the critical &#34;cross&#34; sweep of the gases is maintained. Blowing non-oxidative gases perpendicular to the direction of material travel has proven to be the preferred method since this flow direction provides lower &#34;face velocities&#34; of the sweep gases. Lowered face velocities reduce sweep gas turbulence, which increases vapor removal efficiency and reduces dust production. Thus, a higher degree of material cleaning and decontamination can be achieved and emission control is enhanced. 
     Providing multiple gas inlets to cross-sweep vapors and moisture residing in the space above the material has proven to be an especially advantageous and effective way to remove vapors and moisture from the material as soon as the newly formed vapor emerges from the material. By providing multiple sweep gas inlets, the supply of fresh sweep gas ensures that the sweep gas does not become saturated prior to exiting vapor stripping conveyor 24. If the sweep gas becomes saturated before it exits the vapor stripping conveyor, it tends to permit lengthened contact of the hazardous vapors with the material, thereby endangering the effectiveness of material decontamination. It should be noted that although the drawings show four non-oxidative gas feed lines and four vapor exhaust lines, this is only a preferred construction. Use of more or fewer feed and exhaust lines is fully contemplated to fall within the scope of this invention. 
     It is also advantageous that the cross-sweep gases be introduced at a controlled temperature higher than the ambient temperature of the material entering the conveyor. For example, one preferred range of temperature includes those higher than the boiling point of water. Another especially preferred range includes temperatures greater than the boiling point of the volatile organic(s) to be removed. Use of higher than ambient temperature gases in combination with cross-sweeping the gases reduces the amount of hot gases contacting the material at the introduction point of the material when it is at its lowest temperature. This minimizes surface drying and crusting of the feed material, thereby enhancing vapor stripping. 
     Higher than ambient temperature sweep gases provide enhanced vapor and moisture absorbance by the sweep gases. Utilization of greater than ambient temperature sweep gases ensures that the vapors do not have an opportunity to condense prior to being swept out of the vapor stripping conveyor. Condensation of vapors is to be avoided because it recontaminates previously cleaned material. Greater than ambient temperatures also ensure increased partial pressures of the vapors to increase vapor absorbance. Another advantage of greater than ambient temperatures lies with reduced corrosion tendencies that normally result from acid-gas condensation at lower temperatures. Higher than ambient temperatures for the sweep gases still further increase the total thermal efficiency of the process. 
     After hazardous organic vapors and moisture exit vapor stripping conveyor 24, they travel through vapor exhaust lines 46, 48, 50, 52 and into vapor exhaust manifold 54. Vapor exhaust blower 58 conveys the mixture to vapor exhaust cleaner apparatus 60. Vapor exhaust cleaner apparatus 60 can be any decontamination apparatus well known in the art. For example, exhaust cleaner 60 may be capable of filtering to remove dust, scrubbing with wet scrubber 63 for removal of acid gases, burning the organics with burner 61, burning the organics with burner 61 followed by scrubbing with wet scrubber 63, absorbing a portion of the hazardous organics on activated carbon, catalytic thermal destruction with catalytic thermal destructor 65, recovering the hazardous organics by condensation with condenser 63 or recovering by condensation followed by absorption on activated carbon. All of these cleaning apparatus, as well as others, are well known in the art and are not described in detail herein. Cleaned gases may be exhausted into the atmosphere without danger to the surrounding environment through exhaust purge conduit 62 or may be recycled to non-oxidative gas source 44 for reuse by way of exhaust purge recycle conduit 64. 
     Referring now to FIG. 3 of the drawings, an alternative preferred embodiment of a method of performing the invention is described. Contaminated material 14 is removed from its existing location and transported on removing conveyor 12. Contaminated material 14 enters container 16, travels through feeder 18, sealed conveyor 20, hopper 23 and into vapor stripping conveyor 24 in the usual manner. Contaminated material 14 is decontaminated by volatilization of the volatile and semivolatile hazardous organics in the same manner as previously described in conjunction with the apparatus shown in FIGS. 1 and 2. However, instead of material exiting through chute 70 as shown in FIG. 1, the material exits vapor stripping conveyor 24 through transfer chute 76 and into a second vapor stripping conveyor 124 for further decontamination. 
     Introduction of cross-sweeping gases through non-oxidative gas feed lines 133, 134, 136, 138 may be performed in the same manner as through non-oxidative gas feed lines 33, 34, 36, 38. Similarly, a combination of hazardous organic volatile vapors, moisture and the non-oxidizing gas exits vapor stripping conveyor 124 through vapor exhaust lines 146, 148, 150, 152 in the same manner as vapor exhaust lines 46, 48, 50, 52 in vapor stripping conveyor 24. Utilization of the second set of cross-sweeping gas sources further ensures that materials passing through vapor stripping conveyor 124 are completely decontaminated prior to exiting chute 170. 
     However, it has surprisingly been discovered that excellent material decontamination may be achieved by not supplying further non-oxidative gas into vapor stripping conveyor 124. Instead, the flow of cross-sweep gases in vapor stripping conveyor 24 creates a venturi effect through transfer chute 76 and the space above the material in vapor stripping conveyor 124. This venturi effect creates a secondary sweep gas phenomenon in vapor stripping conveyor 124, which is particularly effective to achieve final decontamination of material passing therethrough. 
     Removal of as much as 99.99%, or more, of all volatile and semivolatile organic contaminants in various materials has been continuously achieved at high rates of treatment utilizing the apparatus and method of the invention claimed below. Table I illustrates the effectiveness of the claimed invention in four test runs conducted on soils containing volatile organic contaminants. Similarly, semivolatile organic contaminants were effectively removed in the same four test runs as shown in Table II. 
     The system 10 further contains various valves, dampers, gauges and the like that are not illustrated for the sake of simplicity and ease of understanding. They are employed to control or direct gases and/or fluids through the various conduits in the desired manner. Vapor stripping conveyor 24 has also been illustrated and described in a simplified manner for ease of understanding. For example, the number of flights 74 has been reduced below the number practically employed in use. Also, no specific means for rotating the flights has been shown. Although heating fluid entrances and exits for vapor stripping conveyor 24 have been illustrated as connecting at opposing ends, it should be understood that other constructions are possible, such as by use of standard, commercially available rotary joints. These design features are well known and may be commercially obtained in various forms and configurations. Moreover, conveying means other than rotating flights may be used to convey materials through vapor stripping conveyor 24. 
     Although this invention has been described with reference to specific forms selected for illustrations in the drawings, it will be appreciated that many modifications may be made, that certain steps may be performed independently of other steps, and that a wide variety of equivalent forms of apparatus may be utilized, all without departing from the spirit and scope of this invention, which is defined in the appended claims. 
     
                                           TABLE I__________________________________________________________________________       Test 1       Test 2        Test 4      Test 8       Oil Temperature 600° F.                    Oil Temperature 400° F.                                  Oil Temperature 400°                                              Oil Temperature                                              500° F.       Residence Time 40 min.                    Residence Time 40 min.                                  Residence Time 35                                              Residence Time 40                                              min.       Soil Concentration                    Soil Concentration                                  Soil Concentration                                              Soil Concentration       Feed   Processed                    Feed    Processed                                  Feed  Processed                                              Feed  ProcessedAnalyte     (ug/kg)              (ug/L) (a)                    (ug/kg) (ug/L) (a)                                  (ug/kg)                                        (ug/L) (a)                                              (ug/kg)                                                    (ug/L)__________________________________________________________________________                                                    (a)VolatilesVinyl chloride       &lt;3,500 0.2   &lt;3,600  0.2   &lt;1,600                                        0.2   &lt;1,600                                                    0.2Dichloromethane       &lt;1,800 0.1   &lt;1,800  0.1   &lt;800  0.1   &lt;800  0.11,1-Dichloroethene       &lt;1,800 0.1   &lt;1,800  0.1   &lt;800  0.1   &lt;800  0.1Chloroform  140  J 0.1   180  J  0.1   &lt;800  0.1   &lt;800  0.11,2-Dichloroethane       &lt;1,800 0.1   &lt;1,800  0.1   &lt;800  0.1   &lt;800  0.11,1,1-Trichloroethane       &lt;1,800 0.1   &lt;1,800  0.1   &lt;800  0.1   &lt;800  0.1Trichloroethene       37,250 0.3   111,000                         (b)                            0.3   10,575                                        1.2   8,500 2.3Tetrachloroethene       2,760            J 0.1   3,985                         J  0.1   613 J 0.0   650 J 0.12-Butanone  &lt;11,000              0.6   &lt;11,000 0.6   &lt;4,800                                        0.6   &lt;4,800                                                    0.6Benzene*    &lt;1,800 0.1   &lt;1,800  0.1   745 J 0.1   136 J 0.4Toluene*    &lt;1,800 0.1   8,300   0.1   200 J 0.1   18  J 0.0Chlorobenzene*       &lt;1,800 0.1   &lt;1,800  0.1   &lt;800  0.1   &lt;800  0.1Ethylbenzene*       &lt;1,800 0.1   960  J  0.1   &lt;800  0.1   &lt;800  0.1__________________________________________________________________________ (a) TCLP concentrations. TCLP extract for VOCs was determined by dividing soil concentration by 20, thus simulating a worstcase leachate scenario (all contaminants leached by TCLP). (b) Higher than detection range, estimated value. Replicate indicated an estimated value less than detection limit, however, sample replicate integrity is suspect. *Potential constituent of JP4 fuel. &lt;Not detected at the specified detection limit. J Less than detection limit, estimated value. 
    
     
                                           TABLE II__________________________________________________________________________        Test 1      Test 2      Test 4       Test 8        Oil Temperature 600° F.                    Oil Temperature 400° F.                                Oil Temperature 400° F.                                             Oil Temperature                                             500° F.        Residence Time 40 min.                    Residence Time 40 min.                                Residence Time 35 min.                                             Residence Time 40 min.        Soil Concentration                    Soil Concentration                                Soil Concentration                                             Soil Concentration        Feed  Processed                    Feed  Processed                                Feed   Processed                                             Feed   ProcessedAnalyte      (ug/kg)              (ug/L) (a)                    (ug/kg)                          (ug/L) (a)                                (ug/kg)                                       (ug/L) (a)                                             (ug/kg)                                                    (ug/L)__________________________________________________________________________                                                    (a)Semivolatiles1,2-Dichlorobenzene        35,000              6  J  15,000                          10  J 53,000 6  J  13,500 4   J1,4-Dichlorobenzene        8,700 6  J  3,600                        J &lt;100  14,750 1  J  4,300                                                  J 1   JFluoranthene*        &lt;3,300              &lt;10   2,900                        J &lt;100  1,750                                     J 10 J  795  J &lt;20Benzo(a)anthracene*        &lt;3,300              &lt;10   &lt;3,800                          &lt;100  &lt;3,900 &lt;10   &lt;4,300 &lt;20Benzo(a)pyrene*        &lt;3,300              &lt;10   &lt;3,800                          &lt;100  &lt;3,900 &lt;10   &lt;4,300 &lt;20Benzo(b)fluoroanthene*        &lt;3,300              &lt;10   &lt;3,800                          &lt;100  &lt;3,900 &lt;10   &lt;4,300 &lt;20Chrysene*    &lt;3,300              &lt;10   &lt;3,800                          &lt;100  &lt;3,900 10 J  &lt;4,300 &lt;20Dibenzo(a,h)anthracene*        &lt;3,300              &lt;10   &lt;3,800                          &lt;100  &lt;3,900 10 J  &lt;4,300 &lt;20Acenaphthene*        &lt;3,300              &lt;10   &lt;3,800                          &lt;100  &lt;3,900 10 J  &lt;4,300 &lt;20Acenaphthylene*        &lt;3,300              &lt;10   &lt;3,800                          &lt;100  370  J 10 J  &lt;4,300 &lt;20Anthracene*  60  J &lt;10   770 J &lt;100  120  J 10 J  &lt;4,300 &lt;20Benzo(g,h,i)perylene*        &lt;3,300              &lt;10   &lt;3,800                          &lt;100  &lt;3,900 &lt;10   &lt;4,300 &lt;20Fluorene*    &lt;3,300              &lt;10   &lt; 3,800                          &lt;100  325  J &lt;10   &lt;4,300 &lt;20Indeno(1,2,3-c,d)pyrene*        &lt;3,300              &lt;50   &lt;3,800                          &lt;500  &lt;20,000                                       &lt;50   &lt;22,000                                                    &lt;100Phenanthrene*        790 J &lt;10   820 J &lt;100  960  J 1  J  320  J &lt;20Pyrene*      280 J &lt;10   90  J &lt;100  785  J &lt;10   185  J &lt;20Benzo(k)fluoranthene*        &lt;3,300              &lt;10   &lt;3,800                          &lt;100  &lt;3,900 &lt;10   &lt;4,300 &lt;20__________________________________________________________________________ (a) TCLP concentrations. TCLP extract for VOCs was determined by dividing soil concentration by 20, thus simulating a worstcase leachate scenario (all contaminants leached by TCLP). (b) Higher than detection range, estimated value. Replicate indicated an estimated value less than detection limit, however, sample replicate integrity is suspect. *Potential constituent of JP4 fuel. &lt;Not detected at the specified detection limit. J Less than detection limit, estimated value.