DE3739126A1 - Process and system for decontaminating a soil zone - Google Patents

Abstract

The invention provides a process which makes it possible, effectively to decontaminate in situ a soil zone contaminated with oil or oil- or hydrocarbon-containing substances. To this end, at least one suction shaft is established in the contaminated soil zone, via which a liquid present in the contaminated soil zone, such as ground water and/or a wash liquor and/or a wash gas introduced at a distance from the suction shaft and loaded with the contaminants is drawn off and then purified in a conventional manner. <IMAGE>

Description

The invention relates to a method for decontamination nation one especially with oil, oil or hydrocarbon containing contaminated soil and on a Plant for carrying out this procedure.

For example, in the case of accidents with tankers, in particular it can transport oil or oil-containing substances come that the transport container receives a leak, through which the oil or the oil-containing substance can leak. It is not exclude that the oil or the oily substance in the earth get rich and do the same over a larger area clean. The decontamination of such an area of the earth so far follows in such a way that the soil in the unclean excavated area, transported away and in a special their system cleaned or ge in a hazardous waste landfill is stored. Such a procedure is particularly useful with large ones contaminated areas of the earth complex and expensive.

The invention is based on the object of a method for the decontamination of, in particular, with oil, oil or coal hydrogen-containing substances to contaminated soil create, which remains in place and place of the earth le is feasible.

To solve this problem, a method according to the Invention proposed that in the contaminated area of the earth at least one suction shaft is produced, via which one in the contaminated earth area, existing liquid, such as ground  water, and / or one at a distance from the suction shaft level washing liquid and / or a washing gas, which (s) with the Is loaded, removed and then in is cleaned in a known manner. Such a process is also carried out, for example, when the soil in the area of buildings with oil or oily substances nig and cannot be excavated and transported away. One can also have one or more diffusion shafts Washing liquid, e.g. Water or a solvent, or a Wash gas, e.g. Air or steam, alone, together or be washed in alternately, which is then the one in the earth area existing contaminants absorbed, on the way to suction takes shaft and is suctioned off there. The washed in with If necessary, tel can ent special bacteria or cultures hold or be cleaned with such after its suction.

Further features of the method according to the invention and a Appendix for performing the method are in the claims 2-34 disclosed.

The invention is described below in a drawing in Simplified illustrated embodiments explained. Show

Fig. 1 shows a section through a contaminated earthly realm with a suction duct and two diffusion wells,

Fig 2 fusion shafts. A further embodiment of a suction tube arranged in the ground and two other configurations of Dif,

Fig. 3 shows another embodiment of a suction shaft and two diffusion shafts and interconnected by a horizontal channel

Fig. 4 is a representation corresponding to FIG. 3 with a further embodiment of a diffusion shaft.

In FIGS. 1-4 of the drawing Erdbereiche 3 are shown in section which are to a certain, limited by example as a natural junction depth contaminated with oil or oil-containing substances. For decontamination of these earth regions 3 , a vertical suction shaft 1 is produced, for example, in the center thereof, which is lined according to FIG. 1 with a tube 2 , for example made of plastic. This tube 2 can be drawn into the same at the same time as the production of the suction shaft 1 . The pipe 2 has a multiplicity of holes or bores through which the interior of the pipe 2 communicates with the soil 3 , which, for example, contains sand or gravel. The upper area of the shaft 1 or the tube 2 is sealed off by a plate 4 or the like. In the plate 4 , a suction line 5 is used, which is connected to a pump or suction device, not shown, and which may extend to the lowest point of the tube 2 . The pump or suction device normally has a slight negative pressure in the suction shaft 1 or the pipe 2 .

At a distance around the suction shaft 1 or the tube 2 , several diffusion shafts 6 , for example on a circular line, are evenly distributed on the outer edge of the contaminated earth region, of which only two diffusion shafts 6 are shown in FIG. 1. These diffusion shafts 6 be in the same way as the suction shaft 1 from a tube 7 , which is formed for example from plastic and has a plurality of openings or bores on its surface. The upper region of the tube 7 and thus also the diffusion shafts 6 is sealed off by a plate 4 , into which a pressure line 8 is inserted, which is connected to the interior of the diffusion shafts 6 or tubes 7 .

Via the pressure line 8 , a prepared washing liquid speed a solvent and / or a washing gas, for example air or steam, is conveyed into the diffusion shafts 6 or into the pipes 7 . Via the openings in the pipes 7 , the detergent or cleaning agent supplied passes into the contaminated soil, particularly between the suction shaft 1 and the diffusion shafts 6 . Here, the detergent or cleaning agent absorbs the impurities, for example oil or oil-containing substances, and gradually transports them in the direction of the suction shaft 1 . In the suction shaft 1 , the supplied detergent or cleaning agent, but possibly also groundwater located in the ground, is drawn off and fed via the suction line 5 to a special cleaning device. Here, the detergent or cleaning agent and, if applicable, the groundwater are freed of the contaminants. After a separation, the detergent or cleaning agent can be used again; if the treated groundwater is unpolluted, this can be returned to the ground.

To rule out that the detergent or cleaning agent supplied via the diffusion shafts 6 also extends in the direction opposite the suction shaft 1 , it is possible that the openings or bores in the tubes 7 are only present in the area facing the suction shaft 1 are. The washer fluid, the solvent and the scrubbing gas, such as air or steam, can be fed individually or in combination, depending on the type of impurities, and thus simultaneously, in succession or alternately.

In the embodiment shown in FIG. 2, the suction shaft 1 and possibly further suction shafts are located in the center of the contaminated earth area. This suction shaft 1 receives a tube 2 made of metal or plastic, which is also provided with openings or bores. The tube 2 , however, has a considerably smaller cross section than the shaft 1 . After inserting the tube 2 into the shaft 1 , the annular space located between the tube 2 and the wall of the shaft 1 is filled with a material which forms coarse pores. As such filling material, clay tubes, clay balls, gravel, activated carbon or the like can be used. Ver should be ensured that the filling material has good water or liquid permeability. If necessary for geological reasons, the wall of the shaft 1 can be lined with a special tube having bores or openings. If necessary, it is also possible to first set an outer, completely closed pipe which, after the inner pipe and the filler material have been inserted, is removed from the borehole again.

Around the suction shaft 1 , several diffusion shafts 6 are also arranged here, the arrangement being made so that the one diffusion shaft 6 is located between two suction shafts for at least 1 min. The diffusion shafts 6 here have a larger diameter than the pipe 7 located there. The located between tube 7 and the Wan extension of the shaft 6 cavity is also filled with a material to form coarse pores. Due to this large-pored filling material, moisture, gas or a bacterial flushing solution can be kept in stock in depth due to the large surface area, so that all detergents and cleaning agents can also get into the soil here. Depending on requirements, the tube 7 can be arranged in the center or on one side in the shaft 6 ( FIG. 2). With a central arrangement, the tube 7 has openings or bores uniformly distributed over its surface. In an eccentric arrangement, the tube 7 has openings or bores only in the region which faces the suction shaft 1 .

In the embodiment of FIG. 3, the suction shaft 1 is designed in the same way as in FIG. 2. In the annular space filled with coarse-pored material, however, a line 9 leads downward, which enters the tube 2 from below. Compressed air or the like can be injected into the tube 2 via this tube 9 , which causes the washing or cleaning agent in the tube 2 to move upwards. In Fig. 3, two diffusion shafts 6 are shown, which are in their lower region at a distance below the suction shaft 1 through a horizontal channel 10 connected to each other. This channel 10 can also be inclined. The channel 10 can, if necessary, be lined with a plastic hose with openings and / or be filled with large pore-forming material. Such a channel 10 causes an additional flow of the washing or cleaning agent from bottom to top and to the suction shaft 1 in the contaminated soil area.

In the embodiment of FIG. 3, special hollow lances 11 are provided in the area between the diffusion shafts 6 and the suction shaft 1 . Through these hollow lances 11 , it is possible to introduce detergents or cleaning agents into the soil 3 and, if necessary, in particular in the case of point contamination, to also suck them off. If necessary, the suction shaft 1 and the diffusion shafts 6 can also be formed as hollow lances 11 . In addition, in the case of point contamination, a special pipe 12 with a heating or fuel rod can also be inserted into the soil 3 , by means of which the point contamination is eliminated on the spot.

In the exemplary embodiment in FIG. 4, the suction shaft 1 is formed by two or more tubes 2 running obliquely downwards. Each tube 2 can be shut off separately in its upper area, so that individual areas of the contaminated earth area, which are more heavily loaded, are decontaminated with different outputs. In addition, special drainage nozzles 13 are provided here, via which a detergent or cleaning agent in the surface area can be flushed into the contaminated soil area 3 .

In all embodiments, a liquid washing or cleaning agent is added via the diffusion shafts 6 , which is processed in special containers and introduced via the pressure line 8 . The exiting via the suction line 5 of the suction shaft 1 can be collected in special containers and then cleaned in a manner known per se. Escaping exhaust air is pre-cleaned using normal filters and decontaminated using special biofilters. Metallic substances that are present in the extracted washing or cleaning agent can be bound by complexing agents and, if necessary, washed out. Through the above-described method, a kind of artificial groundwater flow is achieved even where there is no groundwater, which enables complete decontamination and thus complete remediation of the contaminated soil. The area around the redevelopment area is only slightly exposed to water, with the majority of the water being pressed in the artificially created direction of flow. The stratification of the contaminated soil area determines the number and arrangement of the suction shafts and diffusion shafts.

If necessary, special flushing around the redevelopment area pipes are inserted into the soil, the rinse water too lead and thus the flow direction of the supplied washing or Influence detergent. Of course it is too possible, the suction shafts outside and the diffusion shafts in Arrange the center of the contaminated earth area. In addition tion to the above-described embodiments, it is Support the effect of the washing or cleaning process possible to vibrate in the contaminated earth area conditions, e.g. Vibrating or sounding, to bring in through their energy input, here vibration, the washing or Intensify cleaning activity.

Claims (34)

1. A method for decontamination of an earth region contaminated in particular with oil, oil- or hydrocarbon-containing substances, characterized in that at least one suction shaft is produced in the contaminated earth region via which a liquid present in the contaminated earth region, such as groundwater, and / or with Distance from the suction chimney added Waschflüs liquid and / or a washing gas, which (s) is loaded with the impurities, deducted and then cleaned in a conventional manner. 2. The method according to claim 1, characterized, that generates a slight negative pressure in the suction shaft becomes. 3. The method according to claim 1, characterized, that a slight excess pressure is generated in the suction shaft. 4. The method according to claim 1, characterized, that in the suction shaft alternately a vacuum and a Overpressure is generated.   5. The method according to at least one of claims 1 to 4, characterized, that the liquid or the washing liquid or the Washing gas (steam) by means of air in the suction supplied below shaft is promoted upwards. 6. The method according to at least one of claims 1 to 5, characterized, that the washing liquid and / or the washing gas over with Ab stood around the suction shaft in the soil is discharged. 7. The method according to at least one of claims 1 to 6, characterized, that the washing liquid and / or the washing gas via Drai rod end is introduced into the ground. 8. The method according to at least one of claims 1 to 6, characterized, that the washing liquid and / or the washing gas via lances is introduced into the ground. 9. The method according to at least one of claims 1 to 8, characterized, that the washing liquid and / or the washing gas over min at least a vertical shaft with at least one itself at its lower end adjoining, transverse Canal is introduced into the ground. 10. The method according to at least one of claims 6 to 9, characterized, that the washing liquid and / or the washing gas under pressure is introduced into the ground.   11. The method according to at least one of claims 6-9, characterized, that the washing liquid together with the soil in contaminated earth is vibrated. 12. Plant for decontamination of an earth region contaminated in particular with oil, oil- or hydrocarbon-containing substances, in particular for carrying out the method according to at least one of claims 1 to 11, characterized by at least one suction shaft ( 1 ) formed in the contaminated earth region, which at its upper end End absorbs a direction that is connected to a known cleaning and / or separating device. 13. Plant according to claim 12, characterized in that the suction shaft ( 1 ) is arranged vertically. 14. Plant according to claim 12, characterized in that the suction shaft ( 1 ) is arranged obliquely. 15. Plant according to at least one of claims 12 to 14, characterized in that the suction shaft ( 1 ) is formed by a tube ( 2 ) which has at least one inlet opening at least in its lower region. 16. Plant according to claim 15, characterized in that the tube ( 2 ) is designed at least at its lower end as a sieve. 17. Plant according to at least one of claims 12 to 14, characterized in that the suction shaft ( 1 ) is designed as a lance. 18. Plant according to claim 15 or 16, characterized in that the tube ( 2 ) at least over part of its length of a bed of large pore-forming filler material, such as clay balls, clay tubes, gravel, activated carbon or the like, is surrounded. 19. Plant according to one of claims 15, 16 or 18, characterized in that in the lower region of the tube ( 2 ) a ge injected air injection device is arranged. 20. Plant according to at least one of claims 12 to 19, characterized in that the suction shaft ( 1 ) is arranged in the center of the contaminated earth area and at a distance around the suction shaft ( 1 ) at least three diffusion shafts ( 6 ) are easily seen. 21. Plant according to at least one of claims 12 to 19, characterized in that at least one diffusion shaft ( 6 ) is arranged in the center of the contaminated earth region and several suction shafts ( 1 ) is seen at a distance around the diffusion shaft ( 6 ). 22. Plant according to claim 20 or 21, characterized in that each diffusion shaft ( 6 ) is formed from a tube provided with radial outflow openings ( 7 ). 23. Plant according to claim 22, characterized in that the outflow openings are arranged only in one sector of the tube ( 7 ). 24. Plant according to claim 22 or 23, characterized in that the tube ( 7 ) is surrounded at least over part of its length by a bed of large pore-forming filler material, such as clay balls, clay tubes, gravel, activated carbon or the like. 25. Plant according to at least one of claims 20 to 24, characterized in that at least the outer diffusion shafts ( 6 ) is formed from a half pipe ( 7 ). 26. Plant according to at least one of claims 20 to 25, characterized in that at the bottom of at least one diffusion shaft ( 6 ) is followed by at least one transverse channel ( 10 ). 27. Plant according to claim 26, characterized in that the channel ( 10 ) is arranged horizontally. 28. Plant according to claim 26, characterized in that the channel ( 10 ) is arranged inclined. 29. Plant according to at least one of claims 26 to 28, characterized in that in the channel ( 10 ) and optionally in the diffusion shaft ( 6 ) a plastic tube provided with outflow openings is arranged. 30. Plant according to at least one of claims 26 to 28, characterized in that the channel ( 10 ) is filled with a large pore-forming material such as clay balls, clay tubes, gravel, activated carbon or the like. 31. Plant according to at least one of claims 26 to 30, characterized in that a diffusion shaft ( 6 ) is assigned a plurality of channels ( 10 ). 32. Plant according to claim 31, characterized in that each channel ( 10 ) is equipped with a shut-off device. 33. System according to at least one of claims 12 to 32, characterized in that a plurality of suction shafts ( 1 ) are connected to a common suction line. 34. System according to claim 33, characterized in that each suction shaft ( 1 ) is equipped with a shut-off device.