DE4323766A1 - Process for applying binder suspension - Google Patents

Abstract

Method of producing consolidated or sealed bodies in the soil, in particular in the form of columns or laminations, in which a drill and injecting rod is sunk and is withdrawn again while placing binder suspension, the rod being sunk by the auger drilling method, and excess material being drawn off via the interior of the drill and injecting rod during the withdrawal of the rod and during the placing of the binder suspension. <IMAGE>

Description

The invention relates to a method for producing solidified or sealing bodies in the ground, in particular others in the form of columns or lamellas, with one Drilled and injected rods sunk and spreading of binder suspension is pulled again. The Erfin dung also relates to a drill and injection rod for Implementation of the method according to the invention.

Procedures of the type described above are of low Injection pressure of around 10 bar as a simple injection process and with a high pressure of 200 to 600 bar performed as a high pressure injection process; latter are known by the applicant under the Soilcrete brand name (VDI-Lexikon Bauingenieurwesen, Düsseldorf 1991, p. 270). It is common for a smooth, double-walled Pipe rod, which is provided with a drill bit, also serves as a drill and injection rod. To when the boom is lowered, it becomes a bandage during pulling medium suspension via nozzles near the drill bit brings that over supply channels between the walls of the boom. It is known here that Binder suspension in a high pressure cutting jet to bring out or instead the binder with relative low pressure and also water to be used in a high pressure cutting jet. For verb The effect can be increased by the high pressure cutting jet to be compressed air jacketed, with inside the double walls of the boom another feeder channel for compressed air is to be formed.  

If the injection rod is not pulled in a rotating manner, ent are lamellar solidified bodies from a mixture from binder suspension and soil material; will Injection boom pulled rotating, the speed of rotation is to be matched to the drawing speed, so columnar, solid ground bodies are created from a bandage medium suspension mixed with soil material.

In the case of heavy soils, this is relatively slim multi-walled rods for injecting for bringing down the hole is not usable. If you try the injection Using rods for drilling can lead to drilling or damage to the boom. At that is not acceptable. So in these cases it was Previously required, first the hole with a welding bring down the other drill rods to pull this again hen and then the special double-walled injection bring down the rod, when pulling it then the bin medium suspension as low pressure injection alone or in addition to a high-pressure cutting jet or yourself was applied as a high pressure cutting jet.

The need to sink two different poles and pulling again is extremely disadvantageous and undesirable; it must be taken into account here that greater depth of the drill rods from several longitudinal sections are used, their assembly and disassembly especially time consuming when it comes to double or multi-walled rods.

From DE 37 18 480 C1 a drilling device for a High pressure injection process known in which a walled rod for a high pressure suspension jet longitudinally displaceable in another double-walled Ge rods for the supply of flushing medium is arranged. Both  Rods have their own drill bits. Through this training particularly complicated drive means are required. The proposed procedure is extraordinary complex, being in the annulus between the two rods a backflow of excess suspension to the surface should be done. The risk of clogging this annulus is addressed and not to be neglected.

Proceeding from this, the present invention is the Task based on a method and an apparatus for Implementation of the procedure of the type mentioned at the beginning provide that even in the presence of heavy soils the execution of the drilling and injection described above procedure in one operation.

The solution lies in a process that involves this distinguishes that the rod in the auger drilling process is brought down and that when pulling the boom and excess material when applying the binder suspension al abge on the inside of the drill and injection rod leads.

With the auger drilling process, in itself known way drill holes in dense soils. This will rise in the borehole when the suspension is applied de Excess material raised by a auger Lich is hampered according to the invention by the interior of the linkage, so that despite using the Auger drilling method injecting according to a norma len injection process with a pressure of about 10 bar or the injection with the high pressure injection method with Pressures from 200 to 600 bar can be carried out easily the one without the snail of the boom reversing material hindered. This increases through the interior of the Rods instead of, as in known injection methods the way in the borehole outside the pipe to have to search.  

The method is particularly advantageous in this way performed that compressed air to the interior of the boom is fed so that the rate of climb of Material in the interior is increased significantly. Here the return material is loosened and even at solid soil consistency a clogging inside the Ge always avoided. It is particularly advantageous if Compressed air to the interior of the boom in various Highs is fed.

As known as such, a high pressure injection can procedures are modified so that the used Cutting jet is compressed air jacketed by ring nozzles for Compressed air arranged concentrically to the cutting jet nozzles are not. Here, the cutting beam can pass through under high Pressure supplied binder suspension or through under high pressure water are formed, being in in the latter case, the binder suspension again lower pressure is supplied.

It is according to the different task possible to apply the compressed air to the inside of the tubular body set a different pressure level than the compressed air to the Ring nozzles that coat the cutting beams.

The linkage can vary depending on the consistency of the soil be pulled non-rotating, whereby by increasing the Borehole anticipates part of the job of the cutting beam is taken; in the case of particularly hard floors, it can material against excessive stress Linkage rotating in the opposite direction to the direction of rotation when To be sunk.

One for performing the above procedure suitable drill and injection rods with a double  walled tubular body that has a central interior and forms an annular space that is used to guide binders Suspension is provided and at least one nozzle enters the environment at the bottom of the boom, is characterized in that the outside on Tubular body at least one helical worm gear is attached and the tubular body at least one man opening at the lower end of the boom, which the connects the central interior with the surroundings. These The jacket opening forms a passage channel through the two walls of the tubular body, the against the annular space, which is used to supply binder suspension, Water or compressed air is used, is sealed. The coat Opening can be designed in such a way that the return of material from the environment to the inside space and the upward flow is favored; esp special when a certain direction of rotation of the boom is provided when pulling.

In this case, the at least one man is preferred tel Opening with a flap that can be covered by Open pressurization of the interior of the tubular body cash or removable. This effectively prevents that already when the boom was lowered, the interior of the tubular body with soil material that does not through Binder suspension is loosened or suspended.

Further advantageous embodiments of the invention Linkage are described in the dependent claims, wherein the type of division of the annulus for the supply of Binder suspension, water or air as well as the arrangement ring nozzles for compressed air, which are the nozzles for the Essentially surrounded by high-pressure cutting beams in a ring is known.  

A particularly preferred and new design is there out that at least one air nozzle to the interior of the tube body is arranged in the linkage, preferably even several air vents to the interior at different heights are arranged to Ver drive to loosen the return material in the interior to be able to apply.

As far as compressed air to the ring nozzles that the cutting jets sheath and compressed air to the interior of the tubular body for Loosening of the return material are also provided, can either use two different compressed air supplies be provided in the annulus to under one another to generate different pressure levels, or it can - preferably in association with the nozzles - means for printing reduction provided in front of at least one type of nozzle his.

A preferred embodiment of the lower end of a drill and injection rod according to the invention is in of the figure.

Fig. 1 shows a longitudinal section through a fiction, contemporary linkage with a view of the worm gear;

FIG. 2 shows a cross section through a linkage according to the invention according to FIG. 1.

The figures are described together below, same details in the figures with the same Numbers are occupied.

The lower end of a drilling and injection rod 1 can be seen , which comprises a double-walled tubular body 2 , which forms an annular space 3 and a central interior 4 . On the outside of the tubular body, a worm gear 5 shown in view is attached. Near the lower end, a jacket opening 6 is provided in the tubular body, which ends with a drill tip. The annular space 3 is formed in a longitudinal channel 8 for suspension and a longitudinal channel 9 for compressed air. Two radial nozzles 10 , 11 extend from the longitudinal channel 8 and deliver the suspension in particular in the high-pressure jet. These nozzles are encased by ring nozzles 12 , 13 for compressed air. From the longitudinal channel 9 for compressed air, another nozzle 14 goes into the interior 4 for the return material. The linkage according to the invention can be composed of individual longitudinal sections. As already mentioned above, in addition to the longitudinal channels 8 and 9 , a further longitudinal channel for cutting water can be provided, in which case its outlet nozzles are then preferably encased by ring nozzles for compressed air.

Claims (14)

1. A process for the production of solidified or sealing bodies in the ground, in particular in the form of columns or lamellae, in which a drilling and injecting rod ( 1 ) is sunk and pulled out again by means of a suspension using a bandage, characterized in that
that the rod ( 1 ) is brought down in the auger drilling process and
that when pulling the rod and when applying the binder suspension, excess material is removed via the inside of the drilling and injection rod ( 1 ). 2. The method according to claim 1, characterized in that
that compressed air is introduced into the interior of the rod ( 1 ) when the binder suspension is applied. 3. The method according to claim 1 or 2, characterized in
that the binder suspension is applied in at least one substantially radial cutting jet from the drilling and injecting rod ( 1 ), which preferably emerges compressed air jacketed from the drilling and injecting rod. 4. The method according to claim 1 or 2, characterized in
that water is discharged from the drilling and injecting rod ( 1 ) in at least one essentially radial cutting jet, which preferably emerges from the drilling and injecting rod ( 1 ) with a compressed air jacket. 5. The method according to claims 2 and 3 or 2 and 4, characterized in
that the pressure level of the inside of the linkage ( 1 ) and the outside of the linkage ( 1 ) exiting air pressure is different. 6. The method according to any one of claims 1 to 5, characterized in
that the rod ( 1 ) is rotated - especially in the opposite sense to the direction of rotation when drilling - is pulled. 7. The method according to any one of claims 1 to 6, characterized in
that the linkage ( 1 ) is pulled non-rotating. 8. drilling and injection rods ( 1 ) with a central tubular body ( 2 ) which forms a central interior ( 4 ) and an annular space ( 3 ) which is provided for guiding the bandage by means of a suspension and at least one nozzle outlet ( 10-13 ) on lower end of the linkage ( 1 ) to the environment, characterized in that
that at least one helical worm gear ( 5 ) is attached to the outside of the tubular body ( 2 ), and that the tubular body ( 2 ) has at least one jacket opening ( 6 ) at the lower end of the rod ( 1 ), which has the central interior ( 4 ) connects with the environment. 9. linkage according to claim 8, characterized in
that the annular space ( 3 ) for guiding binder suspension and compressed air and possibly water is divided into at least two longitudinal channels ( 8 , 9 ), each of which has nozzle outlets ( 10 , 11 ; 12 , 13 ) to the environment. 10. drill pipe according to claim 9, characterized in
that the nozzle outlets ( 12 , 13 ) for compressed air surround the nozzle outlets ( 10 , 11 ) for a cutting jet of binder suspension or water in a concentric ring. 11. drill pipe according to one of claims 9 or 10, characterized in
that at least one nozzle outlet ( 14 ) for compressed air to the interior ( 4 ) of the tubular body ( 2 ) is arranged in the linkage ( 1 ). 12. drill pipe according to claim 11, characterized in that
that several nozzle outlets for compressed air to the interior ( 4 ) of the tubular body ( 2 ) are arranged at different heights in the linkage ( 1 ). 13. drill pipe according to one of claims 8 to 12, characterized in
that the at least one jacket opening ( 6 ) can be covered with a sealing cap which can be opened or removed by pressurizing the interior ( 14 ) of the tubular body ( 2 ). 14. Linkage according to one of claims 11 or 12, characterized in
that means for acting on the nozzle outlets ( 12 , 13 ; 14 ) for compressed air to the interior and to the environment are provided with different pressure levels, in particular separate longitudinal channels or a single longitudinal channel with different pressure reducing valves.