RU2129191C1 - Method for isolation of ground volumes and remotely controlled drilling head for realization of method - Google Patents

Abstract

FIELD: construction engineering. SUBSTANCE: method can be used for waterproofing of dead storages of waste, dumping sites, pipelines, and also for waterproofing of construction basins. According to method, use is made of consolidating materials which are injected into ground. For this purpose, at least one bore-hole is drilled from ground surface beyond ground volume to be waterproofed. Bore-hole is drilled below aforesaid ground volume. Consolidating material is injected into ground area which surrounds bore-hole. Remotely controlled and directed drilling head is provided with nozzles for injecting consolidating material into ground. This allows for creation of simple method for complete waterproofing of substantial volumes of ground including sources of fouling such as dead storages of radioactive waste, also of pipelines and construction basins being erected. EFFECT: higher efficiency. 26 cl, 18 dwg

Description

 The invention relates to a method for isolating bulk soil, sprinkled naturally or artificially, from an available or potentially gaseous, liquid, emitting and / or solid source of contamination, for example, in landfill sites (old landfills, old storage facilities, etc.) , landfills, pipelines or the like, as well as in construction pits, using liquid, viscous-plastic and finely divided solid sealing materials or eluates.

 At present, various methods for subsequent encapsulation of foci of pollution, in particular random dumps of garbage, so that the harmful substances contained in them cannot penetrate the environment, are already known.

 From German Patent Application Laid-Open DE-A 3407382, there is known a method for subsequent underground isolation, mainly waste disposal, in which working pipes from an area outside the disposal body are introduced under the disposal body without passing through the disposal body. These working pipes are installed by a mining method from a previously created vertical mine under burial. From these working tubes, the sealing material is pumped into the soil using a special device. With this method, very high technical costs are required, and a mining tunnel for mounting working pipes can only be used in special cases.

 German patent application DE-A 3439858 discloses that from two vertical, located outside the soil mass to be enclosed in the shell, reinforced supports of the walls with slots, a completely insulating substrate passing through through the soil mass under the waterproofing is made using a cutting and pumping device and connected tight in the form of a trough with vertical walls with slots. The vertical walls with slots reinforced by the supports, which are necessary with this method, again require high technical costs and are very expensive.

 Another method for the subsequent processing of landfills for environmental protection is described in German Patent Application Laid-Open DE-A 3330897. In this method, the surface of the landfill is divided into surface sections located immediately adjacent to each other. In the places of their joints, control wells are performed as regulatory end wells from the initial shafts to respectively opposite end shafts. Guide elements are then introduced into these control wells, the start and end of which are in opposite start or end shafts. In the annular space between the guide elements there is a device for cleaning and pumping, which with the help of a cleaning element loosens the soil of the surface area and prepares it for processing with sealing material. Also, with this method, the initial and final shafts are needed to introduce devices for cleaning and pumping. Further, it is possible to carry out the sealing of the burial body in accordance with its contours, since a direct stroke of the pilot wells is necessary for the operation of the device for cleaning and injection.

 EP-A 0317369 discloses a method for isolating bulk sections of soil, in particular landfills, an old landfill, etc., using sealing materials, in which a drilling method with completely controlled penetration from a surface located outside the bulk section of soil passes at least one well beneath the bulk soil and the sealing material are injected into the soil zone surrounding the well.

 In the known method we are talking about an electrokinetic method in which the injection of the corresponding insulating means, such as asphalt or the like, is carried out using an electrode, which is then used as an injection pipe, which is removed before heating the insulating means for heating from the surrounding soil . The insulating agent is injected through the perforated holes made in the electrode at low pressure, so that the soil is impregnated.

 The technical problem underlying the invention is to create a simple way to completely seal bulk areas of soil, in particular foci of contamination, such as waste dumps (including radioactive ones), pipelines or construction pits created as well, in which there is no the need for tunneling, flat spatial underground workings or mines manufactured with the help of mining;

 This technical problem is solved by the fact that in the method of isolation of bulk soil, in particular landfill, old landfill, etc., using sealing materials, in which through a drilling method with a completely controlled penetration from a surface located outside the bulk soil at least one well passes under a volumetric area of soil and the sealing material is pumped into the soil zone surrounding the well, according to the invention, a fully controllable, remote-controlled direction is used th drill bit, the sealing material is continuously injected into the wellbore zone during soil head while the longitudinal motion of the drill in the borehole, wherein the sealing material out of the outlet openings or nozzles formed in the drill bit.

 Using the controlled-direction drilling method, all operations can be performed starting from the surface, so that there is no longer a need for costly initial and final mines or the like constructed by the mining method.

 In this case, it is particularly preferred that the wells can be adapted to the contour of the contaminated area in accordance with the need, so that only a minimal amount of sealing material is required for injection in the base area. The number and length of required wells for the complete enclosure [of the shell] of contaminated land or the construction pit being created is thereby reduced.

 Depending on the characteristics of the soil and on preliminary or available preliminary data on the lower contour of the source of pollution, it is preferable, for safety reasons, to remove the entered wells in relation to the contaminated land and / or below the deepest points of the exploration wells by at least a few decimeters in order to achieve absolutely reliable sealing of the polluted site.

 In order to advance the wells, the well-known, however, modified, fully controllable, remotely deflectable drill head is used in a preferred way, which allows you to pass ahead of the well in any desired direction and at any depth.

 The method according to the invention is particularly simple and effective if the sealing material is continuously pumped into the soil region surrounding the well during the movement of the drill head in the longitudinal direction of the well. This can be done, firstly, already when the well passes ahead and / or also when the drill head or a special treatment device moves backward in the direction of the inlet. In this case, the sealing material is pumped through nozzles or outlet openings located on the drill head into the soil area.

 In order to create a flat locking layer by means of wells with a controlled direction, it is preferable that the sealing material exited in the form of at least one side stream (additional direct streams are possible) from the rotating drill rod to obtain cylinder-shaped, pumped adjacent to each other (intersecting) overlapping each other bodies or using at least two lateral and / or frontal jets with a non-rotating drill rod to obtain a blade-like shape in contact with each other until cheniya body discharge or other geometric arrangement of the nozzles, nozzles obtained from them forms injected bodies. The aim is the manufacture as a whole, for example, in the form of bathtubs or bowls, acting mainly horizontally locking layers.

The location (of these layers) obtained using the injection options described above is multifaceted in its capabilities. Preferably obtained with a non-rotating stave of drill rods using at least two injection outlets, adjacent to each other or on top of each other injection paths of respectively one well extend at an angle of from about 90 to 180 ^° . Due to this, for example, infiltration water can drain into the grooves formed as a result of this, to the deepest points and through the microtunnels with the built-in filter pipe obtained using the same drilling technique and mounted on the inside, they can be trapped and lifted.

 In order to completely block the source of contamination with the barrier layer, it is preferable to lay a number of wells ahead of each other parallel to each other in the ground, and in each case the neighboring wells injected by the sealing material should touch or cut into a prefabricated site, i.e. e. a piece of soil with injected sealing material so that no infiltration seeping water can no longer pass through these locking layers and their overlapping sections into the deeper layers of the soil.

 It is also possible to make several such locking layers on the sides and under the source of contamination to ensure absolutely reliable sealing of the source of contamination. For this, it is preferable to go through a certain number of wells ahead of a certain distance relative to each other at, for example, a right angle with respect to the first number of wells that pass under the source of contamination, and again pressurize the sealing material from these wells into neighboring soil areas. Due to this, two or more completely enclosed, covering layers of pollution are formed which provide an absolutely reliable shutter.

 In order to achieve reliable isolation of the source of soil contamination, for example, it is also possible to draw a well network corresponding to the contour ahead of the source of pollution, so that in each case the sealing material can be injected repeatedly into adjacent areas of the soil through the well, which ensures that there are no leaks in the formed blocking layer.

When multiple locking layers pass ahead of wells of adjacent, stacked tiers parallel to each other at an angle of 20 - 160 ^o C with respect to the first number of wells of an adjacent plane parallel to each other under the source of contamination.

 It turned out that, among others, the use of ozokerite emulsion as a liquid sealing material provides outstanding properties. Also very high properties are possessed by polymersilicates, resins, other waxes or other, chemically resistant and plastic injected materials remaining plastic.

 The locking layer formed, for example, by the ozokerite emulsion, is very elastic with respect to subsequent settling of landfills and possible elastic deformations of the locking layer (s).

 In addition, the barrier layer formed by the ozokerite emulsion is resistant to liquid and gaseous substances acting as a barrier in infiltration, capillary and ground water.

 It turned out that the locking layer with a thickness of 30 to 60 cm is quite enough to achieve reliable sealing.

 In addition, with the method according to the invention, other materials can be mixed in or, with a multilayer structure, layers with other injected, absorbent and / or sealing materials can also be introduced in order to achieve high sealing depending on the properties of the soil.

 The high adhesion resistance (sliding ability) of the ozokerite emulsion is especially valuable with the method according to the invention, since the high sliding ability also allows good movement of other substances and, for example, causes very little wear on the nozzles, and thereby increases the service life of the drill head.

 The injection of sealing materials in the method according to the invention is also possible below the Fral-Druches depending on the permeability of the structure of the area surrounding the well. Thanks to injection at low pressure, an optimal fit of the manufactured locking layers to the soil properties is possible.

 Depending on the properties of the soil or the expected infiltration substances, it is preferable with several locking layers formed one after another or one above the other according to the method according to the invention, each locking layer made of various sealing or injection means.

 The device for carrying out the method preferably has nozzles on a fully deflectable, remotely guided drill head, which supply liquid sealing material to the soil at elevated (sensible) or high pressure to a distance of 2 to 3 m from the borehole walls.

For example, it is preferable to arrange the first pair of nozzles with respect to the second pair of nozzles with an offset of 5-180 ^° relative to the longitudinal axis of the drill head. Each pair of nozzles includes two nozzles located opposite each other, which in each case are directed so that in each case with a longitudinal axis of the drill head make an angle from 30 to 90 ^o . Due to this, it is possible to create sections of soil saturated with injected materials of various geometric shapes.

 It is preferable if these nozzles are surrounded by outlets for compressed air, which give a strong preliminary or parallel passage of air, which allows you to form a stream of sealing material of any shape, and it is preferable to introduce the sealing means into the ground with a flat stream. In principle, it is possible to inject in one phase (one way) up to several phases (multiphase method). By means of an appropriate arrangement of the locking layers forming, for example, flat grooves under the contaminated soil, it is possible to direct the infiltration water in certain directions. It goes without saying that it is also possible to produce cylindrical insulating bodies included in one another.

 Further, in order to further clarify and better understand the invention, several examples of the invention are described and explained with reference to the accompanying drawings.

In FIG. 1 shows a schematic illustration of an insulating layer made by the method according to the invention along the contour of a waste storage,
in FIG. 2 is a schematic illustration of a drill head during sinking ahead of a well under an old landfill,
in FIG. 2a is a schematic illustration of the formation of a locking layer by injection of sealing means during the reverse stroke of the drill head,
in FIG. 3 is a cross section of a number of wells under the waste storage,
in FIG. 4 - 10 - in each case, a schematic representation of a cross section extending across a number of wells, in which the location of the wells relative to each other, as well as the corresponding injection areas are made differently,
in FIG. 11 is a schematic front view of a drill head with nozzles having a direction,
in FIG. 12 is a schematic side view of the drill head of FIG. eleven,
in FIG. 13 is a schematic representation of the directions of the wells and injection sections for sealing the construction pit,
in FIG. 14 is a schematic cross-sectional view of a pipeline with wells and injection areas located parallel to it,
in FIG. 15 is a schematic cross-sectional view of a pipeline with a leak that is sealed through a well,
in FIG. 16 is another schematic representation of the complete sealing of the pipeline,
in FIG. 17 is a schematic cross-sectional view of a pipeline surrounded by contaminated fragments of a destroyed pipe, which is protected by a well beneath it and by injection (sealing material),
in FIG. 18 is another schematic cross-sectional view according to FIG. 17, in which the (pipeline) is completely enclosed by wells and injection (medium) according to the method according to the invention.

 As shown in FIG. 1 - 3, the repository 1 of the landfill in the underground part does not have a specific shape. A certain number of wells 2 extend outside the body of the waste storage, starting from the outer surface, using a known drilling method with a controlled direction, respectively, of a contour under the contaminated soil section to the opposite side of the waste storage 1.

 Starting from each well 2, the sealing material is pumped into the surrounding soil areas of the corresponding well 2, the adjacent sections of the corresponding well 2 being in contact or overlapping, thereby creating a dense locking layer 3 that extends along the contour of the waste storage 1.

From FIG. 2 that forms the second barrier layer 4 below the first barrier layer 3 is rotated through 90 ^o network located at some distance from each other in parallel wells 5 and extending from the portions 4 are compacted soil.

 In FIG. 2 shows a fully controllable, remotely guided drill head 6 as it passes under the waste disposal repository 1.

For the formation of the locking layer corresponding to the contour of the burial, various locations of the wells are possible. An example is shown in FIG. 3. So, the wells 2 are located at a distance from each other parallel to each other with some vertical displacement relative to each other, and the flat locking layers 4 emanating from one well 2, respectively, overlap and form an angle of about 120 ^° .

 After the course of the contour of the landfill 1 is determined based on map materials, previously captured images, geophysical surveys, preliminary drilling, etc., a well network 2 is created (passed) ahead of it, which passes under the body (storage) of the landfill accordingly, its contour is completely controlled with respect to the direction of the drilling method, and in the process of it or during the reverse movement (drill), the liquid sealing means, preferably ozokerite, is pumped into the surrounding soil th hole. In each case, these soil sections 4 mixed by means of a sealing means overlap and thereby form a barrier layer 3, which completely surrounds the waste storage with the seal.

 In the method according to the invention, it is not necessary to draw wells 2 to another hole opposite the inlet. You can also enter the locking layers 3 only in a partial area of the soil layer.

 In FIG. 4 to 10 show other examples of location of well-ahead paved wells according to the method of the invention in a schematic representation. In the illustrated exemplary embodiments, the wells pass in each case horizontally or also vertically. They can be carried out, proceeding from the surface to any desired place for sealing the bulk soil.

As shown in FIG. 4, the first row of boreholes 2a, one above the other at equal distance from each other, is introduced into the ground. In addition, the second row of wells 2b, which are also located one above the other and are equally spaced from each other, are displaced relative to the first row of wells 2a. In each case, two slightly expanded injection regions extend from each well 2a, 2b, and the injection regions emanating from one well form an angle of about 130 ^° . In each case, adjacent injection areas intersect. In each case, the injection sections emanating from the first row of wells 2a and from the second row of wells 2b intersect in such a way that completely closed sections are formed, in which, for example, other fully directional wells 10 are located that serve as control wells. This arrangement of boreholes 2a, 2b facilitates some kind of double wall sealing.

 When shown in FIG. 5, the location of wells 2a, 2b, 2c between the first row of wells 2a and the second row 2b introduces a different number of wells 2c between these wells 2a, 2b, and in each case four separate, slightly flattened injection regions extend from the wells 2c. They again cross two outgoing in each case - from the first row of wells 2a and from the second row of wells 2b of the injection area. This ensures a very good plexus of the individual discharge areas and, thereby, a very effective sealing of the bulk soil.

 Another image of an example well system, similar to the well locations of FIG. 4 is shown in FIG. 6. Compared to the embodiment of FIG. 4, separate injection sections extend even further into the final region and form intersecting injection regions or passing along individual wells 2a, 2b of the injection site.

In the exemplary embodiment of the well system 2a, 2b, 2c shown in FIG. 7, some kind of triple wall is formed. To this end, the first row of boreholes 2a running parallel to each other is introduced into the ground. In each case, based on one well, there are two injection areas, the angle between which is approximately 130 ^o . Two adjacent injection regions of two adjacent wells 2a intersect, thereby forming a first sealing wall. The row of wells 2c constructed in this way is located with a parallel displacement relative to the first row of wells 2a. The third row of wells 2b with their respective injection regions is located vertically with respect to the second row with a parallel offset relative to it, so that the injection regions passing from the individual wells 2b, 2c intersect each other and form a rhomboid-shaped arrangement of the injection sites in cross section. Reliable sealing of the bulk soil is again ensured.

 The slightly simplified formation of the discharge areas shown in FIG. 4 - 7, it is obtained due to the fact that during the reverse movement of the drill head, no rotation is performed and the injected material is pumped through the various nozzle systems into the surrounding soil area. Schematically presented injection areas are in fact barrier layers or sites filled with injection material and extending from the wells. It goes without saying that the wells can go horizontally, as well as vertically or with any inclination, since they are made from the surface and pass ahead of the sealed body of waste disposal in a fully controlled passage process (wells).

 In further examples of execution 8 to 10, others are shown, shown schematically as an example of the location of wells, which, however, the drill head in a given angular range deviates back and forth or constantly rotates around its longitudinal axis.

 In FIG. Figure 8 shows a cross-section passing through wells 2a, 2b in which during the reverse movement of the drill head or even when passing ahead of the individual wells 2a, the injected material is constantly injected into the surrounding area of the soil during rotation of the drill head. Due to this, columnar injection regions are formed around the corresponding well 2a. Wells 2a are spaced from each other such that the injection regions respectively of the neighboring well intersect. Other wells 2b run parallel to them, from which separate soil layers filled with injected material depart, which again intersect the column-shaped injection regions around well 2a.

As shown schematically in FIG. 9 and 10 cross sections of the wells, the head 6 of the drill during the reverse movement oscillates back and forth at a given angle. Opposite nozzles are installed on the drill head, which inject the sealing agent into the surrounding area of the well at various depths. Due to this, in the region of respectively one well 2, two pairs of injection regions appear, one pair having a larger radius and a pair located perpendicular to it — a smaller radius. Wells 2 again run parallel to each other and are located at such a distance from each other that the injection areas intersect with a large radius. Due to this, effective sealing is again achieved, in which the soil area lying closer to the well is absolutely densely filled with the pumped medium. As shown in FIG. 9 example, the angle of oscillation is approximately 45 ^o , and in the example shown in FIG. 10, the drill head oscillates back and forth at an angle of about 90 - 100 ^o .

 FIG. 11 and 12 show a schematic illustration of the location of the nozzles on the drill head 6, which is preferably used for these examples. FIG. 11 is a front view and shows pairwise opposing nozzles with injection angles 15 and 16.

In FIG. 12 is a side view of the drill head 6 of FIG. 11, in which the front pair of nozzles is directed forward, and the rear pair of nozzles rotated 90 ^° with respect to it is directed somewhat backward.

 FIG. 13 shows another field of application of the method according to the invention, in which a construction pit is sealed in order to protect it from water breakthrough or leakage of harmful substances. Wells 2 are laid from a place outside this building pit 25 to the desired depth. Depending on the conditions, taking into account the previously described example of the location of the wells and injection of the sealing material, a waterproofing bath is created. Since using the drilling method according to the invention, various wells 2 can be advanced ahead of time from one place to seal the schematically represented construction pit 25, only the location of the drilling unit needs to be changed. Lay from the first location ahead of the well 2 under the provided construction pit 25 and, accordingly, pump the injected material so that an insulating bath is obtained. From a different location, horizontal wells 2 are laid ahead of the curve with intersecting injection areas relative to the already manufactured wells in such a way that the first bath of the base intersects and densely surrounds the bulk soil or the provided construction pit 25. Now the construction pit 25 can be excavated without being exposed dangers of groundwater or harmful substances containing harmful substances.

 FIG. 14-18 show another field of application of the drilling method according to the invention.

 FIG. 14 shows a cross-section through a pipe 20 located in the ground, which, for example, serves to drain infiltration water containing harmful substances. Since in many cases these pipelines 20 are porous and have survived their service life, subsequent isolation of the soil layers below them is often required. As shown in FIG. 14, for this purpose, a certain number of wells 2 parallel to the pipeline 20, starting from the surface, are advanced ahead of time. During the reverse movement of the drill head, the injected material is uniformly, in a flat form, injected into the surrounding soil. In this case, individual wells 2 run parallel to each other on a surface covering the pipeline 20 and located around its center. The injection areas of neighboring wells 2 intersect again. Thus, under the pipe 20, a capture channel is formed, which, in case of possible leaks, captures and removes leachable harmful substances.

 In FIG. 15 shows the location of damage 20a in the conduit 20 through which harmful substances seep into the soil layers below it. To repair these damaged areas using the method according to the invention, it is necessary to draw a well 2 from the surface to the localized place of damage 20a and from the well 2 to pump the insulating material into the soil area so that it reaches the pipeline 20 and surrounds the place of damage 20a, isolating it.

 FIG. 16 shows a cross section of a conduit 20, which, with the help of two parallel wells 2, is enclosed in the lower part and the vertical injection areas extending from each well 2.

 FIG. 17 and 18 show another application of the method according to the invention. In many cases, the pipeline 20, which serves to drain the infiltration water under the landfill, is chosen too small in size and therefore there is a need for large cross sections. As you know, for this, obsolete pipelines are destroyed by the Bersting-Verfahren or Pipe-Eating-Verfahren method and new larger pipelines are laid. With these known methods, however, there is a problem that the fragments of 21 old pipelines contain harmful substances that can penetrate the underlying soil layers. For safety reasons, for these layers below them, a well 2 is laid ahead of the surface and the sealing material is pumped into the surrounding soil, so that either, as shown in FIG. 17, a half-bowl is formed, which is a channel for discharging these infiltration waters, or, as shown in FIG. 18, create several wells 2 ahead of schedule, the injection areas of which completely surround the new pipeline and the fragments 21 of the old pipeline and form a dense shell.

Claims (26)

 1. The method of isolation of bulk soil, in particular landfills, old landfills, etc., using sealing materials, in which at least one pass through a drilling method with completely controlled penetration from a surface located outside the bulk soil a well beneath a volumetric area of soil and a sealing material are injected into the soil zone surrounding the well, characterized in that they use a fully controllable, remotely guided drill head, the compacting material is continuous yvno injected into the wellbore zone during soil head while the longitudinal motion of the drill in the borehole, wherein the sealing material out of the outlet openings or nozzles formed in the drill bit.  2. The method according to claim 1, characterized in that the well passes, respectively, the contour of the bulk soil.  3. The method according to claim 2, characterized in that the well passes at a certain safe distance from the contour of the bulk soil, under which it is laid.  4. The method according to claim 3, characterized in that the safety distance is at least a few decimeters.  5. The method according to claim 1, characterized in that the sealing material is pumped during penetration ahead of and / or reverse movement of the drill head in adjacent areas of the wellbore.  6. The method according to one of the preceding paragraphs, characterized in that the sealing material is pumped into the soil through nozzles located on the head of the drill.  7. The method according to one of the preceding paragraphs, characterized in that the sealing material is injected into the ground with at least one flat-shaped stream.  8. The method according to one of the preceding paragraphs, characterized in that the sealing material is injected into the ground with two or more flat jets. 9. The method according to claim 8, characterized in that two planes formed by having flat jets are located at an angle of 90 - 180 ^{o to} each other.  10. The method according to one of the preceding paragraphs, characterized in that the sealing material is injected into the soil also in the longitudinal direction of the well.  11. The method according to claim 1, characterized in that a certain number of wells pass under the bulk soil parallel to each other at a certain distance from each other, and parallelism can also be achieved from a plane-shaped location.  12. The method according to claim 11, characterized in that the neighboring, filled with sealing material, the soil area, respectively, of one well in contact with each other.  13. The method according to claim 11, characterized in that neighboring, filled with a sealing material, the area, respectively, of one well intersect.  14. The method according to one or more of the preceding paragraphs, characterized in that the neighboring soil sections filled with sealing material are so positioned relative to each other that they form a closed locking layer that forms grooves spaced apart from each other.  15. The method according to claim 11, characterized in that some other number of wells is laid under a bulk soil at a certain distance from each other parallel to each other and at a certain distance from the vertical from the first number of wells.  16. The method according to one of the preceding paragraphs, characterized in that the sealing material is continuously pumped into the soil area only on a part of the site along the well.  17. The method according to one or more of the preceding paragraphs, characterized in that at least one well extends from the surface outside the bulk soil and goes to the surface in another place outside the source of contamination. 18. The method according to one or more of the preceding paragraphs, characterized in that some other number of wells passes under a bulk soil at a certain distance from each other parallel to each other at an angle of 20 - 160 ^o , ideally 90 ^o relative to the first number of wells.  19. The method according to claim 1, characterized in that the sealing material may be an emulsion of ozokerite, polymer silicate, water glass, resin, emulsion of cement mixed with one of these sealing materials or another wax.  20. The method according to one or more of the preceding paragraphs, characterized in that the insulating layers formed from filled sealing material and increased in the volume of the soil together completely completely surround the bulk soil.  21. The method according to any one of claims 1 to 20, characterized in that after the seal is created, the formed seal is controlled by laying by means of fully controlled penetration of the wells in or under the formed locking layers, while the control elements are introduced into these wells and signalized by the control elements are transmitted values to ground processing devices.  22. The method according to claim 1, characterized in that the diameter of the drill is up to one meter.  23. The method according to claim 1, characterized in that the sealing materials are pumped into the ground for one or more injections.  24. A controlled, fully guided drill head for implementing the method according to claim 1, characterized in that nozzles are arranged on the drill head for injecting the sealing material into the soil.  25. The drill head according to paragraph 24, characterized in that on the drill head around the nozzles are made holes for air jets that direct the stream of sealing material in the desired shape or support the process of its penetration. 26. The drill head according to paragraph 24, wherein the nozzles are arranged in pairs, the first pair of nozzles being located relative to the longitudinal axis of the drill head with an offset of 5-180 ^° compared to the second pair of nozzles and each pair of nozzles has two opposing nozzles, moreover, each of the nozzles with the longitudinal axis of the drill head makes an angle of 30 - 90 ^o . Priority on points:
04/28/93 - according to claims 1 - 18, 20 - 24;
10/15/93 - according to PP.19, 25, 26.

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