CS274416B2 - Method of rocky structure stabilization and stabilizer for its realization - Google Patents

Abstract

A closed tubular preferably circulary cylindrical rock stabilizer is made of expansible mild steel and given a perimeter equal to pi D. After being inserted in a drill hole of a diameter slightly larger than D, the stabilizer is expanded radially by hydraulic high pressure fluid past the value D to such an extent that the irregularities of the drill hole are filled and the rock widened elastically around the stabilizer to provide an anchoring shrinkage fit therefor.

Description

The invention relates to a method for stabilizing a rock structure and a stabilizer for carrying out the method.

It is known that when working in rock structures it is necessary to stabilize them. For this purpose, stabilizers are inserted into the holes drilled into the rock. The stabilizer then opens in the radial direction and is fixed in the borehole. This prevents the rock from falling apart and collapsing due to the fact that the force along the axis of the stabilizer keeps the individual parts of the rock structure together. Existing cracks, which often occur as a result of blasting operations, cannot increase. The density of the boreholes of the intermediate stabilizers depends on how much force has to be introduced into the rock structure. Different rock types have different tendencies to crack.

U.S. Pat. No. 4,423,986 discloses a stabilizer comprising a longitudinally folded tube which is pressurized to expand the pleats and anchor into a borehole. The stabilizer ensures very good anchoring and the achievable range of bore diameters is very wide. However, such a stabilizer is relatively very expensive.

Swedish Patent Publication No. 8502981-7 shows a tubular rock structure stabilizer that extends beyond the borehole size by an expansive body inserted into the stabilizer. Thus, the stabilizer is anchored in the borehole by elastically compressing the rock surrounding the expanded stabilizer. This allows the use of cheap stabilizers, but the expansive body has a limited working life due to the necessarily high pressures.

U.S. Pat. No. 3,349,567 discloses a rock stabilizer comprising a tube for insertion into a borehole and subsequent expansion at various points by pulsating magnetic fields generated by high voltage surges in a coil on a probe that is temporarily inserted into the stabilizer. The stabilizer is inexpensive, but the equipment required is very expensive, and the use of high voltages entails occupational safety risks.

[0008] The invention eliminates these drawbacks by a method of stabilizing a rock structure by means of boreholes in which expanding stabilizers in the form of blind tubes are inserted, the open end of which is connected to an external source of hydraulic pressure fluid, the tubes having a smaller diameter than the borehole. that the outer end of the tube, when inserted into the borehole, connects to an external source of pressurized fluid and the inner cavity of the stabilizer body is placed under controlled pressure, which deforms the walls of the stabilizer body plastically and expands in close contact with the borehole wall, around the borehole, after which the inner cavity of the stabilizer is depressurized and the stabilizer is anchored in the borehole by shrinking the wall of its expanded tube with the elastically deformed surface of the scaled structure along the periphery of the borehole.

The solution provides an efficient method of stabilizing the rock structure using simple means. Stabilization can be carried out simply, quickly, at low cost and the effect achieved is reliable. Compared with the prior art, it makes it possible to reduce costs.

According to a preferred embodiment of the invention, cylindrical partial tubular expansion sections of the stabilizer are inserted successively into the borehole, which are hydraulically interconnected by interconnection and the assembly of the interconnected sections is expanded and anchored as a whole by bringing the internal cavities under pressure together. Radially rigid sections may be inserted between the expandable tubular sections of the stabilizer, with an internal cavity at both ends hydraulically connected to the cavities of adjacent expandable sections. For carrying out the invention, a tubular stabilizer consisting of a blinded cylindrical tube and a soft metal sheath, closed at the front end by a rigid bottom and provided at the other end with a connection head with an inlet channel for connecting the stabilizer cavity to a hydraulic fluid source, is preferably used. The stabilizer preferably comprises an end-capped, cylindrical tube with a soft metal sheath,

CS 274 416 B2 closed at the front end with a rigid bottom and provided at the other end with a threaded nozzle and through-passage for connection to the adjoining stabilizer section, and at least one through-section formed of a soft-shell cylindrical tube with a front head with an internal thread for screwing onto the threaded sleeve of the blinded end section and a rear head with a threaded sleeve, whereby a passageway is formed in the front head and in the rear head following the inner cavity of the passage section.

The threaded nozzle may be a separate coupling screwed into the internal thread of the rear head of one of the joined stabilizer sections and the front head of the other of the joined stabilizer sections, the threaded nozzle passing through a continuous channel connecting the cavities of the two adjacent stabilizer sections.

According to a further feature of the invention, a radially rigid thick-walled section is provided between the at least two expandable sections of the soft-metal cylindrical wall stabilizer, provided with threaded fittings at its ends, the body of the thick-walled section extending through a channel adjoining the channel of the threaded sleeve screwed at at least one end.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a longitudinal cross-sectional view of the stabilizer inserted into the borehole prior to its opening; FIG. 2 is a cross-sectional view taken along line 2-2 of FIG. 1; FIG. 4 is an axial cross-sectional view of the alternative outer end portion of the stabilizer of FIG. 1; FIG. 5 is a side view of an expandable stabilizer section intended for a stabilizer assembly comprising one or more interconnected such sections; 4 is a side view of the front end end plug of the stabilizer assembly of FIG. 5; and FIG. 7 is a side view of the non-extensible stabilizer section forming an alternative to one or more of the sections of FIG. 5.

As can be seen from FIG. 1, an expandable stabilizer in the form of a blinded cylindrical tube 11 is inserted into the borehole 20 in the rock rock 21. The open end of the stabilizer is connected via an inlet channel 16 to an external source of hydraulic pressure fluid. The tube 11 has a smaller diameter than the diameter of the borehole 20.

When connected to an external source of pressurized fluid, the inner cavity 10 of the stabilizer body is brought under controlled pressure, by which the stabilizer walls plastically deform and expand into intimate contact with the well wall, including irregularities thereof, and resiliently expand the rock around the well. Thereafter, the inner cavity of the stabilizer is depressurized and the stabilizer is anchored in the well by shrinking the wall of its expanded tube 11 with the elastically deformed surface of the rock structure along the periphery of the well 20. This is shown in Fig. 3.

The cylindrical partial tubular expansion sections of the stabilizer can be inserted successively into the borehole, which are hydraulically interconnected by interconnection and the system of the interconnected sections is expanded and anchored as a whole by jointly putting the internal cavities under pressure. Radially rigid sections can also be inserted between the expansible tubular sections of the stabilizer, with an internal cavity at both ends hydraulically connected to the cavities of adjacent expansive sections. Thereby, it is possible to locate the places of the application of radial force on the surface of the borehole along the length of the borehole as required and to save the expansive sections and the application of the expansion pressure to the necessary extent.

The details of the stabilizer as a means for performing the described stabilization method will now be explained.

The rock stabilizer shown in Fig. 1 comprises a closed elongated cylindrical body formed from a blinded steel cylindrical tube 11 having properties such that it permits uniform expansion under the effect of an expansive load. Suitable steels for this purpose are, for example, mild steel with a yield strength lower than 350 MPa. If the outer diameter of the cylindrical tube 11 is D, its circumference will have a length. No changes in length3

The tube may have a slightly undulating or otherwise somewhat irregular cross-sectional shape to increase rigidity. The front end of the cylindrical tube 11 is tightly closed by a rigid bottom 12, connected to the cylindrical tube 11, preferably by friction weld. A flange 13 with a cylindrical extension 14 extending outwardly is similarly tightly connected to the outer end. In the extension 14 an inlet 15 is formed into an inlet channel 16 leading into the interior of the tube.

The blinded cylindrical tube 11 has, on the side opposite to the rigid bottom 12, a connecting head 40 with a threaded nozzle 34 and a through channel 41 for connecting the adjoining section of the stabilizer. This downstream section may be of various designs, as will be seen below.

The stabilizer is freely inserted into the borehole 20 drilled in the rock structure 21 with a diameter having a slightly larger diameter than the diameter 0. After insertion, the stabilizer retains with its flange 13 a support plate 22 surrounding the cylindrical tube 11 near the rock surface 21 into which veden vrt.

Before or after insertion of the tube, a schematically indicated coupling 25, preferably of the type described in U.S. Pat. No. 4,423,986, FIGS. 1, 10, is tightly pushed onto the adapter 14 and the bore 15 is fed via a hydraulic high-pressure fluid at 50 This pressure fluid will bring the stabilizer cavity 10 under pressure and cause it to expand radially. This radial expansion fills the still existing irregularities of the borehole and flexibly expands the surrounding rock, as shown in FIG. 3. The pressure is then released and the coupling 25 is removed so that the fluid is finally drained from the stabilizer cavity 10. Although some shrinkage may occur by release, the stabilizer remains firmly anchored in the borehole 20 due to the substantially greater shrinkage of the storage rock 21 around the expanded stabilizer. It is possible to use a suitable manometer or other suitable tool for increased control of the radial hydraulic expansion of the stabilizer.

As an alternative, the stabilizer may be provided with a connector 28 of the type shown in Fig. 4 instead of the attachment 14. In such a case, a quick-release coupling may be used to connect the source of hydraulic pressure fluid.

In order to accommodate the long boreholes with the short lengths of the expandable stabilizers, it is possible to use the expandable through sections 30 of the tubular stabilizer of Fig. 5, which are optionally combined with the non-expandable thick-walled sections 31 with the through channel 36 of Fig. 7.

Sections 30, 31 have an internally threaded front head 42 for screwing onto the threaded sleeve 34 of an adjacent section previously inserted into the borehole, and the rear head 43 with threaded sleeve 34. This allows the individual passage sections 30 to be aligned one after another, as well as the insertion of thick-walled non-extensible sections 31 and their tight connection. The threaded nozzle 38 may be a separate coupling screwed into the internal thread 35 of the rear head 43 of one of the stabilizer sections to be joined, the threaded nozzle 38 passing through a continuous channel connecting the cavities of the adjacent stabilizer sections. The outer end of the assembled stabilizer is formed by the head 32 with the coupling means formed by the threaded hole χχ as shown in FIG. 4. One or more non-extensible thick-walled sections XX can be tightly connected to this head 32 by a sleeve 34 and female thread 35 and assembly. terminate in the borehole with one or more expandable through sections 30 connected to the head assembly 32 and the non-expandable thick-walled section or χχ section. The last expandable through section 30 is then closed with a χβ plug as shown in FIG. 6.

Claims (7)

Method for stabilizing a rock structure by means of boreholes in which expandable stabilizers are inserted, in the form of blind tubes, the open end of which is connected to an external source of hydraulic pressure fluid, said tubes having a smaller diameter than the borehole diameter, characterized in the end of the tube, when inserted into the borehole, connects to an external source of pressurized fluid, and the inner cavity of the stabilizer body is placed under controlled pressure by which the walls of the stabilizer body plastically deform and expand into close contact with the borehole wall, including its irregularities; thereafter the inner cavity of the stabilizer is depressurized and the stabilizer is anchored in the well by shrinking the wall of its expanded tube with the elastically deformed surface of the rock structure along the periphery of the well. 2. Method for stabilizing the rock structure according to claim 1, characterized in that cylindrical partial tubular expansion sections of the stabilizer are inserted successively into the borehole, which are hydraulically interconnected by interconnection and the system of the interconnected sections is expanded and anchored as a whole by placing the internal cavities under pressure. Method according to claim 2, characterized in that radially rigid sections are inserted between the expansible tubular sections of the stabilizer, with an internal cavity at both ends hydraulically connected to the cavities of adjacent expansive sections. and. A tubular rock stabilizer for stabilization by the method of item 1, characterized in that it consists of a blinded cylindrical tube (11) and a soft metal sheath closed at the front end by a rigid bottom (12) and provided at the other end with a connecting head (14). an inlet channel (16) for connecting the stabilizer cavity (10) to the hydraulic fluid source. Tube stabilizer for stabilization by the method according to claim 2 or 3, characterized in that it comprises an end-capped cylindrical tube (11) with a soft-metal sheath closed at the front end by a rigid bottom (12) and provided with a connecting head ( 40) with a threaded nozzle (34, 38) and a through channel (41) for connection to the adjoining section of the stabilizer, and at least one through section (30) formed of a cylindrical tube with a soft metal sheath provided with a front head (42) with inner a thread (35) for screwing onto the threaded socket (34, 38) of the blinded end section and a rear head (43) with a threaded socket (34, 38), whereby a passageway is formed in the front head (42) and the rear head (43) adjoining the inner cavity (44) of the through section (30). 6. Rock stabilizer according to claim 5, characterized in that the threaded nozzle (38) forms a separate coupling screwable into the internal thread (35) of the rear head (43) of one of the joined sections of the stabilizer and the front head (42) of the other of the joined sections. a continuous channel (45) connecting the cavities of the two adjacent stabilizer sections through the threaded nozzle (38). Tube rock stabilizer according to claim 5 or 6, characterized in that a radially rigid thick-walled section (31) provided with threaded connection parts at the ends is inserted between the at least two expandable sections of the soft-metal cylindrical wall stabilizer (31), the body of the thick-walled section ( 31) extends through a channel (36) adjoining the channel (45) of the connecting threaded nozzle (34, 38) screwed on at least one end thereof.