SK278449B6 - The piping construction for creating anchor and/or for pumping of liquid in rock - Google Patents

Abstract

The piping construction is created based on the first segment (I) consisting of the tube (2) with the wall deformable as a result of liquid pressure acting and it is equipped with the longitudinal loop (1). The first end of the tube (2) is closed with the use of the closing element and the connecting element used for liquid supply is fixed to the second end of the tube (2), this connecting element is created based on the connecting bolt (20) with the first through-bore (6) outgoing to the tube (2) and with the outer thread (5) used for fixing of the peripheral device which is created based on the second segment (II), consisting of the pipe (2), to the second end of which is the connecting socked (30) fixed being equipped with the internal thread (9) together with the tightening ring (10) witch is able of screwing on the outer thread (5) closed to the first segment (I). The cavity (8) of the internal thread (9) is connected to the internal space of the tube (2), with the use of the second through-bore (18) created in the connecting socked (30). The closing socked (21) is fixed to the first end of the tube (2) and it is equipped with the filling hole for liquid outgoing to the internal space of the tube (2).

Description

Technical field

The invention relates to a pipe structure for forming an anchor and / or pumping liquid in a rock, in particular for reinforcing mine corridors or for securing other underground spaces, for securing equipment used in mines or for deep mining, or in tunnel construction, for draining water from mines cavities, and also in the reinforcement of cracked rocks, which is formed by a first member consisting of a pipe with a wall deformable by liquid pressure and equipped with a longitudinal loop. The first end of the pipe is closed by a closure element and the second end of the pipe is fastened to the fluid inlet.

BACKGROUND OF THE INVENTION

Various anchor designs are known in the mining industry or in the construction of tunnels. A closed profile anchor pipe is known in which liquid is supplied under high pressure by which the cross-sectional area of the anchor pipe is expanded such that a friction connection is formed between the outer wall of the anchor pipe and the rock to be secured to allow the anchor to be loaded. In the state prior to the anchor tube extension, the tube is provided with a longitudinal loop which is plastically extruded by the hydraulic pressure of the supplied liquid, whereby the anchor tube jacket bears against the wall of the pre-formed bore, stretches and adapts to bore unevenness. The fluid pressure is exerted by an external auxiliary device. The diameter of the borehole made in the rock before insertion of the anchor pipe must be large enough that the pipe can be inserted into the borehole without problems. The basic material of the anchor tube is a steel of medium toughness, which is able to deform plastically under the influence of a liquid pressure of 0.01 to 0.03 MPa. One end of the anchor pipe is equipped with a head adapted to be supplied with reinforcing liquid, the other end is provided with a fastening sleeve to prevent the anchor pipe from tearing. The described anchor pipe can be made in various dimensions between 1 and 3 m, but often it is necessary however, this is very time-consuming and labor-intensive due to the difficulty and complexity of joining the individual tubular parts.

A further disadvantage of the described anchor pipe is that it is unsuitable for draining the mine water from the rock cavities, or for supplying reinforcing liquid to cracked rocks, for example cement milk, by which the cracked rocks could be consolidated.

A further disadvantage of the known anchor pipe is that the filling head of the anchor pipe cannot be embedded in the mine corridor wall or in the front, i.e. the pipe cannot function as an embedded anchor, thereby largely restricting the use of rubber wheel vehicles.

SUMMARY OF THE INVENTION

These drawbacks are largely eliminated by a pipe structure for forming an anchor and / or pumping liquid in a rock formed by a first member consisting of a pipe with a wall deformable by liquid pressure and equipped with a longitudinal loop, the first end of the pipe being closed by a closure element and A fluid supply element, characterized in that the connecting element is formed by a connecting bolt with a straight through bore opening into the pipe and with an external thread for attaching the attachment.

According to a preferred embodiment, the ancillary device is formed by a second member consisting of a pipe to the other end of which a connecting sleeve is secured by an internal thread with a sealing ring for screwing onto the external thread of the first member. The female thread cavity is connected to the inner space of the pipe by means of a second through bore formed in the coupling sleeve. A fastening sleeve is secured to the first end of the pipe by a liquid filling opening opening into the interior of the pipe.

According to a further preferred embodiment, the additional device is formed by a filling device consisting of a filling tube when a fixed filling sleeve is provided to its first end with an internal thread with a sealing ring for screwing onto the external thread of the first member. The female thread cavity is connected to the interior of the filling tube by a second through bore 25 formed in the filling sleeve. The other end of the feed tube is closed by a pressure-resistant shut-off disk and surrounded by a cylindrical sleeve on the outside. A spacer ring is placed between it and the filling tube. The cylindrical sleeve, the spacer ring and the feed tube are equipped with a radial through hole opening into the interior of the feed tube.

According to a further preferred embodiment, the attachment device is formed by at least one intermediate piece consisting of a pipe, to the first end of which a connecting sleeve provided with an internal thread with a sealing ring is screwed onto the external thread of the first member. The female thread cavity is connected to the inner space of the pipe by means of a second through bore 40 formed in the coupling sleeve. A connecting bolt is secured to the second end of the pipe with a first through bore opening into the inner space of the pipe and with an external thread to screw in the internal thread of the second member or of the filling device. Both ends of the pipe are closed with a closure sleeve.

According to a further preferred embodiment, the first through holes of the connecting stud of the first portion and the intermediate member and the second through holes of the connecting sleeve of the second portion, the intermediate member and the filling device have the same cross-section and diameter.

According to a further preferred embodiment, the connecting bolt of the first link and the spacer is provided at the end facing the pipe with a disc whose outer diameter is equal to the outer diameter of the pipe. The disc is followed by a shoulder part, the outer surface of which is provided with an external thread, the inner diameter of which is smaller than the outer diameter. The first through bore extends through the shoulder portion and the disc, and its longitudinal 60 axes lie in the longitudinal axis of the pipe.

According to another preferred embodiment, the outer diameter of the sleeves is equal to the outer diameter of the pipe and the inner diameter of the sleeve thread is larger than the diameter of the second through bore of the sleeve. A sealing ring located in the cavity of the thread abuts the face of the collar formed in the sleeve. Longitudinal axis

The second through bore lies in the longitudinal axis of the pipe or the filling tube.

According to a further preferred embodiment, a first stiffening sleeve is slid and attached to the second end of the first portion tube and a second stiffening sleeve is slid and attached to the first end of the intermediate tube and to the second end of the second member. The outer diameter of the first reinforcing sleeve is equal to the outer diameter of the disc and the outer diameter of the second reinforcing sleeve is equal to the outer diameter of the coupling sleeve.

According to a further preferred embodiment, the inner diameter of the filling tube is larger than the diameter of the second through bore of the filling sleeve. The longitudinal axis of the cavity and the second through bore, which are formed in the filling sleeve, lies in the longitudinal axis of the filling tube.

According to a further preferred embodiment, the tubes of the first and second portions, the spacer and the filling tube are formed of a medium toughness steel material capable of plastic deformation under the pressure of the liquid in the range of 0.01 to 0.03 MPa. The sleeves and / or the connecting bolt are made of steel, the tube, the connecting bolt and the sleeves being joined together by welding.

The main advantage is that a piping structure is developed which, when expanded by hydraulic pressure, can be subjected to a high load due to friction connection with the surrounding rock, the reinforcing and reinforcing effect of which is extremely high, and the piping structure can be quickly and easily extend so that it can be created within practical limits of any length and whose use does not depend on the nature of the rock.

A further advantage is that the duct structure can be formed in a normal or embedded design, the duct structure being suitable for draining water from rocks and injecting reinforcing liquid into the rock.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows a first section partly in axial section and partly in side view, FIG. 2 is a section along line A - A in FIG. 1, FIG. Fig. 3 shows a second section partly in axial section and partly in side view; Fig. 4 shows a spacer partly in axial section in side view; 5 shows an axial section of the coupling sleeve on an enlarged scale, FIG. 6 shows an axial section of the connecting bolt on an enlarged scale, and FIG. 7 shows the filling device in axial section.

DETAILED DESCRIPTION OF THE INVENTION

The pipe structure can be assembled in four embodiments. In a first embodiment, a second article II is attached to the first article I. In a second embodiment, a filling device 14 is attached to the first article I. At least one intermediate III is attached to the first article I to which the second article II is attached. In a fourth embodiment, at least one intermediate III is attached to the first cell I to which the filling device 14 is attached.

As can be seen from FIG. 1 and 2, the pipe 2 of the first section I of the ductwork comprises a longitudinal loop 1 along its entire length. The pipe 2 has a longitudinal x-axis. To the first end of the pipe 2, which, when the inner end of the pipe 2 is embedded in the rock, is attached a closure 11 formed as a sleeve adapted to the first end of the pipe 2 and closing the pipe 2. The closure 11 is secured to the pipe 2 by fifth welds. 2, the connecting bolt 20 is attached to the pipe 2 by a first weld 15. The connecting bolt 20 comprises a shoulder portion 4 with a disc 16, which extends concentrically with the longitudinal axis x a first through bore 6 opening into the pipe 2. The shoulder portion 4 is provided with an external thread 5 The diameter d _{2 of the} first through bore 6 is smaller than the inner diameter of the pipe 2. A tightly fitted first reinforcing sleeve 3 surrounding the second end of the pipe 2 is attached to the disk 16 and also secured to the pipe 2 by a first weld 15 which provides an additional connection between the first reinforcing sleeve. 3 and pipe 2. The first weld 15 prevents leakage of pressure fluid from the interior of the pipes y 2.

The second cell II shown in Figure 3 also comprises a tube 2 with a longitudinal loop 1, the tube 2 corresponding to the tube 2 of the first cell I in the embodiment of FIG. 1 and 2. At the other end of the pipe 2 of the second member II, a connecting sleeve 30 is secured by a second weld 17, through which an inwardly extending collar 19 extends coaxially with the longitudinal axis x of the second through bore 18 opening into the pipe 2. The inner walls of the cavity 8 are provided with an internal thread 9. A sealing ring 10 is inserted into the cavity 8 abutting the front wall of the collar 19. The diameter d _{2 of the} second bore 18 is equal to the diameter d _{2 of the} first bore 6 formed in the connecting of the bolt 20 of FIG. I. The second end of the pipe 2 is surrounded by a second reinforcing sleeve 7, secured by a second weld 17 to the connecting sleeve 30. The purpose of the second weld 17 is to prevent pressure fluid from escaping from the interior of the pipe 2.

At the first end of the second cell II, as shown in FIG. 3, a closure sleeve 21 is provided on the first end of the pipe 2 to which it is connected by a sixth weld 32. The closure sleeve 21 is provided with a liquid filling opening opening into an opening in the wall of the tube 2 and serving to feed the interior of the tube 2 with pressure medium.

In FIG. 4 shows an intermediate section III, which again consists of a pipe 2 equipped with a longitudinal loop 1. At the other end of the pipe 2, a connecting bolt 20 is provided, identical to that of FIG. 1. At the first end of the pipe 2, a connecting sleeve 30 is provided, the same as in the embodiments of FIG. Third

FIG. 5 and 6, the diameter d _{2 of the} first through bore 6 of the connecting bolt 20 is equal to the diameter d _{2 of the} second through bore 18 of the coupling sleeve 30. The diameter d _{2 of} these through bores 6.18 may be, for example, 5 mm.

The outside diameter D of the coupling sleeve 30 is the same as the outside diameter D of the coupling bolt 20. The inside diameters d _{t of the} external thread 5 are also the same, which in the coupling bolt 20 indicate the diameter of the cavity 8 without the external thread 5. to the connecting bolts 20, whereby in some cases the mechanical loads loaded by the load are formed between the elements so connected, the fluid flow on the other side being free, for example a pressurized working fluid or injection fluid or water to be discharged

2786 from the rock between the connected elements.

In FIG. 7, an axial section of the filling device 14 is shown. At the first end of the filling tube 22, a filling sleeve 30a, the same as the connecting sleeve 30, is attached to the third end of the filling tube 22. A spacer ring 25 is attached to the other end. The other end of the filling tube 22 is closed by a pressure-resistant closing disc 24 attached to the filling tube 22 by a fourth weld 29. Pressure fluid is supplied to the filling tube 22 through a radial filler opening 28 passing through the cylindrical sleeve 27, the spacer ring 22 and the spacer 25. on the longitudinal axis x, the support 26 is welded to the feed tube 22, the spacer ring 25 and the cylindrical sleeve 27, as well as the cylindrical sleeve 27 to the spacer ring 25, the spacer 26 being welded at its outer end with a fourth weld 29 to the feed tube 22 pressure resistant closure disc 24. Internal the diameter d _{3 of the} feed tube 22 is greater than the diameter d _{2 of the} second through bore 18 of the feed sleeve 30a.

The basic material of the tubes 2 of the described cells I, II and of the intermediate device III or the filling device 14 is a medium toughness steel capable of withstanding a pressure of 0.01 to 0.03 MPa and the tube 2 equipped with a longitudinal loop 1 is capable of applying plastic deformation pressure. Breaking of the ends and rupture of the welds 15, 17, 23, 29, 31, 32 when the pipe 2 is expanded by the pressure of the liquid prevents the closure 11. As mentioned, the connecting bolt 20 and the coupling sleeve 30 are secured to the pipe 2 by the welds 15, 17. The threads 5, 9 are selected so as to be able to withstand the required load on the armature formed from the piping structure by piping or other metal structures suspended therein in the mines.

If a relatively shallow embedded anchor is to be used, for example in a wall or in the front of a mining corridor, a hole is drilled in a known manner into which the pipe structure of FIG. 1 so that its first end facing the closure 11 is mounted on the bottom of the hole where the connecting bolt 20 is near or inside the rock wall or shank.

The tubular structure is filled with pressure fluid or expanded, whereby the filling sleeve 30a of the filling device 14 of FIG. 7 is introduced into a borehole, screwed onto the connecting bolt 20 and the filling device 14 is connected to a known liquid compressor, its injection nozzle being inserted into a radial through-hole 28 of the filling device 14. Then, the liquid under pressure 0 is injected into the pipe 2. 01 to 0.03 MPa. In FIG. 1 and 7, the dough and liquids are indicated by arrows.

In the female threads 9, the sealing rings 10 without serrations provide a seal, which means that the pressure medium whose pressure is continuously rising cannot escape under any circumstances with threaded connections 5, 9. The liquid under high pressure forces the longitudinal loop 1 of the pipe 2 while the pipe 2 it changes, at least approximately, a shape into a circular cross-section which is tensioned on the wall of a hole drilled in the rock. When the filling device 14 is disconnected, the liquid pressure ceases to act on the pipe 2, which now functions as a recessed anchor. Of course, it is possible to use a pipeline structure embedded in the rock in the manner described to drain the liquid present in the rock block or to inject a reinforcing liquid such as cement milk into the rock. If the piping structure is to be used for conveying the liquid, the cap 11 must be removed, which can be achieved either by increasing the pressure of the liquid or by pulling off the cap 11.

The second cell II shown in FIG. 3 in conjunction with the first cell I shown in FIG. 1 can be made without using the filling device 14 of FIG. 7 a very effective mining anchor in the underground space, protruding, for example, from the wall or the front of the mining corridor. In the first phase of setting up the anchor, a hole is drilled in the rock wall, the length of which corresponds to the total length of the pipe structure, which is possibly 15 shorter by the length of the closure sleeve 21. The first member I of FIG. 1 and a second cell 11, which is screwed by a coupling sleeve 30 on the coupling bolt 20, wherein a closure sleeve 21 secured by a liquid filling opening protrudes from the borehole. In the next working phase, the closure sleeve 21 is connected to said liquid compressor by means of screws, then the pipe 2 of the cell I, II is changed by the flowing liquid in the direction of the road and the liquid (Fig. 1). slowly increases its shape to circular, thereby stretching the tubes 2 in the drilled holes. In this case too, the sealing ring 10 completely prevents leakage of the pressure medium. After the compressor has been disconnected, an anchor is formed on which ³ θ loads can be suspended, for example, pipelines, fittings and the like. It is understood that the pipe structure formed of the following articles I, II are applicable mutatis mutandis to remove water from the rock, and the injection of consolidating fluids, whereupon the Observations ³⁵ of the injection liquid is fed introduction opening.

The spacer III shown in FIG. 4, it is possible to connect pressure-tightly to the first element I of the pipeline construction or simultaneously to both elements I, II, since at one end there is a connecting bolt 20 and at the other end a connecting sleeve 30. With this spacer III it is possible to construct anchor of any length within practical limits , either in the normal embodiment 5, according to which one end protrudes from the wall, or in an embedded or liquid-carrying design, or for injecting a liquid, since a liquid flow is ensured along the entire length of the piping structure, the direction of flow of the pressurized fluid. At the same time, all threaded connections are secured with the sealing rings 10. In order to be able to transport liquids, the cap 11 (Fig. 1) must be either removed by liquid overpressure or burst as described after assembly of the anchor.

The pipeline construction can be easily and quickly assembled, making it easy to create. The duct structure can be manufactured in any length since its elements are simple and can be extended with the provided threads 5, 9, while at the same time perfectly sealing the joints.

The piping design satisfies all-round practical requirements. It can be used as a normal anchor in a rock with a protruding end or in an embodiment embedded in a wall or in the front of a mining corridor. However, it is also suitable for draining water contained in rocks or injecting any of the reinforcing liquid, for example cement milk, into the rock. Therefore, the pipe construction can be successfully used for a variety of mining applications.

The invention is not limited to the described embodiments, but may be used in various embodiments.

Claims (10)

A tubular structure for forming an anchor and / or for pumping liquid in a rock is formed by a first member consisting of a pipe with a wall deformable by liquid pressure and equipped with a longitudinal loop, the first end of the pipe being closed by a closure element and for a liquid supply, characterized in that the connecting element is formed by a connecting bolt (20) with a first through bore (6) opening into the pipe (2) and with an external thread (5) for attaching the attachment. Pipe structure according to claim 1, characterized in that the additional device is formed by a second link (II) consisting of a pipe (2) to the other end of which a connecting sleeve (30) is provided with an internal thread (9) with a sealing ring ( 10) for screwing onto the external thread (5) of the first link (I), the cavity (8) of the internal thread (9) being connected to the inner space of the pipe (2) by means of a second through bore (18) formed in the connecting sleeve (30); wherein a closure sleeve (21) is provided to the first end of the pipe (2) having a liquid filling opening opening into the interior of the pipe (2). Pipe structure according to claim 1, characterized in that the additional device is constituted by a filling device (14) consisting of a filling tube (22), to which a first filling sleeve (30a) equipped with an internal thread (9) with a sealing ring is attached. (10) for screwing onto the external thread (5) of the first link (I), the cavity (8) of the internal thread (9) being connected to the inner space of the filling tube (22) by a second through bore (18) formed in the filling sleeve (30a). ), wherein the other end of the filling tube (22) is also closed by a pressurized closure disc (24) and is externally surrounded by a cylindrical sleeve (27) between which a spacer ring (25) is arranged between the filling tube (22) and the cylindrical sleeve (27), the spacer ring (25) and the feed tube (22) are provided by a radial through hole (28) opening into the interior of the feed tube (22). Pipe structure according to claim 1, characterized in that the additional device is formed by at least one intermediate piece (III) consisting of a pipe (2), to whose first end a connecting sleeve (30) is secured by an internal thread (9) with a sealing ring. (10) for screwing onto the external thread (5) of the first link (I), the cavity (8) of the internal thread (9) being connected to the inner space of the pipe (2) by a second through bore (18) formed in the connecting sleeve (30) wherein a connecting bolt (20) is secured to the second end of the pipe (2) with a first through bore (6) opening into the interior of the pipe (2) and an external thread (5) to screw the female thread (9) of the second link (II); a filling device (14), wherein both ends of the pipe (2) are closed by a closure sleeve (21). Pipe structure according to one of Claims 1 to 4, characterized in that the first through bores (6) of the connecting bolt (20) of the first part (I) and the intermediate piece (III) and the second through bores (18) of the connecting sleeve (30) of the second part (II), intermediate (III) and filling device (14) have the same cross-section and diameter (d ₂ ). Pipe structure according to one of Claims 1 to 5, characterized in that the connecting bolt (20) of the first link (I) and the intermediate piece (III) is provided at the end facing the pipe (2) with a disc (16) whose outer diameter (D) ) is equal to the outer diameter of the pipe (2), the disc (16) being adjoined by a shoulder (4), the outer surface of which is provided with an external thread (5) whose inner diameter (d ^ is less than the outer diameter (D)); the first through bore (6) passes through the shoulder portion (4) and the disc (16) and its longitudinal axis lies in the longitudinal axis (x) of the pipe (2). Pipe structure according to one of Claims 1 to 6, characterized in that the outer diameter (D) of the sleeves (30, 30a) equals the outer diameter of the pipe (2) and the inner diameter (d) of the inner thread (9) of the sleeve (30). 30a) is larger than the diameter (d ₂ ) of the second through bore (18) of the sleeve (30, 30a), wherein a sealing ring (10) located in the cavity (8) of the female thread (9) abuts the face of the collar (19) formed in the sleeve (30, 30a), wherein the longitudinal axis of the second through bore (18) lies in the longitudinal axis (x) of the tube (2) or of the feed tube (22). Pipe structure according to one of Claims 1 to 7, characterized in that a first reinforcement sleeve (3) and a first end of the pipe (2) of the intermediate member (III) are slid and attached to the second end of the pipe (2) of the first part (I). and a second reinforcing sleeve (7) is slid and attached to the second end of the second link (II), the outer diameter of the first reinforcing sleeve (3) being equal to the outer diameter (D) of the disc (16) and the outer diameter of the second reinforcing sleeve (7). equal to the outer diameter (D) of the coupling sleeve (30). Pipe structure according to any one of claims 1 to 8, characterized in that the inner diameter (d ₃ ) of the filling tube (22) is larger than the diameter (d ₂ ) of the second through bore (18) of the filling sleeve (30a), (8) and the second through bore (18) formed in the filling sleeve (30a) lie in the longitudinal axis (x) of the filling tube (22). Pipe structure according to one of Claims 1 to 9, characterized in that the tube (2) of the part (I, II), the spacer (III) and the filling tube (22) are formed of a medium toughness steel material capable of plastic deformation under pressure liquids in the range of 0.01 to 0.03 MPa, the sleeves (30, 30a) and / or the connecting bolt (20) being formed of steel, the pipe (2), the connecting bolt (20) and the sleeve (3, 7, 30, 30a) are welded together (15, 17, 23, 29, 31, 32).