KR101196889B1 - Rockbolt and construction method for the same - Google Patents

Abstract

PURPOSE: A rock bolt and a construction method thereof are provided to improve supporting force by only fixing a hollow body using an expansion force forming unit. CONSTITUTION: A rock bolt comprises a hollow body(110) and an expansion force forming unit(130). The hollow body has a hollow(112). Portions of the hollow body are pressed. After the hollow body is inserted into the ground, the pressed portions of the hollow body are expanded. The expansion force forming unit comprises a pack bag(132) and a pipe for an expansion material. The pack bag is expanded by an expansion material injected into the hollow of the hollow body. The pipe is inserted into the pack bag and guides the supply and discharge of the expansion material. The pipe has an adjustable length.

Description

Rock bolt and construction method {ROCKBOLT AND CONSTRUCTION METHOD FOR THE SAME}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the field of civil engineering, and relates to a rock bolt installed in a rock or the like for support and a construction method thereof.

Rock bolt is a support used for ground (2), such as rock, and supports the tunnel, and is used by inserting it into a hole drilled in the ground (2), such as rock.

There are several structures of rock bolts, one of which is an expandable structure.

As shown in FIG. 1, the expandable rock bolt 10 is installed in the perforation in a state in which a part of the circumference of the hollow body 12 is pressed 12B (see 'R1' in FIG. 1), and then hollow. The high pressure water is supplied to the hollow 12A of the body 12 to expand the hollow body 12 so that the expanded hollow body 12 can be fixed to the ground 2 such as a rock. (See 'R2' in Figure 1).

The front end and the end of the hollow body 12 are respectively provided with a front end cap 14 and an end cap 16 to prevent both ends of the hollow body 12, sealing to prevent leakage, etc. . Packing is also installed. The tip cap and the end cap are fixed to the hollow body 12 by welding.

However, the following problems are pointed out in the rock bolt according to the prior art.

First, in order to maintain the airtightness of the hollow 12A of the hollow body 12, a cap for a tip, a cap for a termination, and sealing. Since many components, such as packing, are required, high costs are inevitably high.

In addition, there is a fear that the airtightness of the hollow body 12 cannot be maintained.

In addition, since the structure of the rock bolt is complex and heavy weight as described above, a high degree of skill is required in construction, and dedicated equipment is required.

In addition, a lot of research has to be continued for the airtightness of the hollow 12A of the hollow body 12.

In addition, the end cap and the end cap, the sealing (sealing) in the hollow body (12). After packing and the like are assembled, since the hollow body 12 cannot be arbitrarily cut in accordance with the embedding depth of the perforation 1, many difficulties are encountered in construction.

In addition, since the high pressure water is directly supplied to the hollow body 12, treatment and research for preventing corrosion of the hollow body 12 are required, and the corrosion of the hollow body 12 is completely prevented. Is difficult.

In addition, after the expansion of the hollow body 12, a large amount of time and dedicated equipment are required to re-discharge the high pressure water supplied to the hollow body 12, and completely discharge the water supplied to the hollow body 12. And it is not easy to completely remove the moisture in the hollow body 12.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a rock bolt and its construction method improved the expansion method of the hollow body.

In order to solve the above problems, the present invention has a hollow 112, inserted into the perforation (1) formed in the ground (2) in a state in which at least one portion is pressed in a concave shape along the circumferential direction (arrow C) A hollow body 110 in which the pressed part is unfolded so as to be installed in close contact with the ground 2 around the perforation 1; It is inserted into the hollow 112 of the hollow body 110, after the fixing of the hollow body 110, the expansion force forming unit 130 is separated from the hollow body 110; includes; The unit 130 is expanded by the inflating material 120 inserted into the hollow 112 of the hollow body 110 and injected therein so that the hollow body 110 can be unfolded therein (inflated material). A pack pouch 132 that can be inflated by ejection of 120; The lock bolt is inserted into the pack pocket 132 has an expansion material passage to guide the supply, discharge of the expansion material 120, the length of the lock bolt characterized in that it comprises an expansion tube made to be adjustable Can present

The hollow body 110 may be made of a steel pipe.

The hollow body 110 in the depressed state may be formed to secure a space into which the expansion force forming unit 130 may be inserted before expansion in the center of the hollow 112 of the hollow body 110. .

The pressure plate 140 is integrally coupled to the hollow body 110 and in close contact with the ground 2 outside the perforation 1, and is formed to correspond to the hollow body 110 in the pressed state. The hollow body 110 may have a fitting hole 142 into which the hollow body 110 is fitted.

The fitting hole 142 of the acupressure plate 140 may be gradually expanded in size along the direction toward the inside of the perforation 1 outside the perforation 1.

The pressure plate 140 is integrally coupled to the hollow body 110 and tightly attached to the ground 2 outside the perforation 1, and the fitting hole 142 into which the hollow body 110 is fitted is pressed. The hollow body 110 in a state may be fitted and may be formed to correspond to a reduced shape of the cross section of the hollow body 110B after the fixing.

The pressure plate 140 is integrally coupled with the hollow body 110 and in close contact with the ground 2 outside the perforation 1, and is formed to correspond to the hollow body 110B after the fixing. It may have a fitting hole 142 is fitted.

The inflator tube 136 includes a plurality of hollow tubes 135 arranged in a longitudinal direction of the inflator tube 136 and having a hollow shape having a hollow 135A; Each of the hollow tube 135 is formed so that the adjacent hollow tube 135 is inserted or inserted into the adjacent hollow tube 135 along the longitudinal direction of the expandable tube 136, the adjacent hollow tube ( A stopper may be provided to be movable along a predetermined length along the 135 and may be prevented from being separated.

The fastening member 138 is provided at the end along the longitudinal direction of the expandable tube 136 so that the pack pocket 132 can be detachably coupled to the expandable tube 136 by the fastening member 138. The fastening part 136A is detachably fastened along the longitudinal direction, and the pack pocket 132 may have a through hole 132A to allow the fastening member 138 to pass therethrough.

The inflator tube 136 has a coupling part 136B which is detachably coupled to the inflator supply unit 200 for supplying an inflating material to the inflator tube 136, and the pack bag 132 has the inflator supply unit ( The through hole 132B may be formed to penetrate the 200.

The inflator pipe 136 may be connected to a hydraulic force supply unit 200A for supplying hydraulic pressure as the inflator 120 so that the pack bag 132 may be inflated by the hydraulic force.

In addition, in the present invention, the hollow body 110 into which the expansion force forming unit 130 is inserted is inserted into the perforation 1, or the expansion force forming unit 130 is inserted into the hollow body 110 inserted into the perforation 1. A boring insertion step of inserting; After the drilling insertion step, by supplying the expansion material 120 to the pack pocket 132 through the expansion pipe 136 so that the hollow body 110 is fixed to the expansion force forming unit 130 A fixing step for forming support force; After the fixing step, by discharging the expansion bag supplied to the pack bag 132 through the expansion pipe 136 to release the pack bag 132, the expansion force forming unit 130 is hollow It can be presented together with a rock bolt construction method comprising a; the step of recovering the expansion force forming unit to recover the separation from the body (110).

The present invention proposes a rock bolt and a construction method thereof that can form a support by fixing only the hollow body by the expansion force forming portion expanded by the expansion material.

In addition, the present invention provides a rock bolt and its construction method that can freely reduce or increase the length of the tube for the expansion material, as the expansion force forming unit includes a pack bag and the length of the expandable tube.

1 is an application example of a lock bolt according to the prior art.
2 or less relates to the rock bolt according to the present invention,
2 is a perspective view of a first embodiment;
3 is an exploded perspective view of Fig.
4 is a cross-sectional view taken along line AA of Fig.
5 is a view corresponding to 4, the second embodiment;
FIG. 6 is a view corresponding to FIG. 4 and shows a third embodiment. FIG.
FIG. 7A is a view corresponding to FIG. 4 and shows a fourth embodiment.
FIG. 7B is a view corresponding to FIG. 7A and shows a state after fixing. FIG.
8 is a cross-sectional view taken along line BB of FIG. 3.
FIG. 9 is a view corresponding to FIG. 8 and still another embodiment.
10 is a cross-sectional view before the expansion force forming portion of the expansion force forming portion.
FIG. 11 is a view corresponding to FIG. 10, and is a cross-sectional view of the expansion force forming unit after the expansion force is formed; FIG.
12 is a cross-sectional view taken along line CC of FIG. 11.
13A is an example of construction in a state before fixing.
14B is a cross-sectional view taken along the line DD of FIG. 13A.
14A is a construction example of a state after fixing.
FIG. 15B is a sectional view along the EE line of FIG. 14A;
Figure 15a is an example of the installation state of the expansion force forming unit separated after fixing.
FIG. 15B is a sectional view along the FF line of FIG. 15A; FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown below in FIG. 2, the rock bolt according to the present invention has a hollow 112 and is formed in the ground 2 in a state in which at least one portion is pressed in a recessed shape along the circumferential direction (arrow C). A hollow body (110) inserted into the perforation (1) and then the pressed portion unfolded to be installed in close contact with the ground (2) around the perforation (1); It is expanded by the expansion material 120 is inserted into the hollow 112 of the hollow body 110 and injected into the hollow body 110 to unfold the hollow body 110 inserted into the perforation 1 of the ground (2), hollow It may include; an expansion force forming unit 130 that can be released to be separated from the hollow body 110 after the mold body 110 is unfolded. For reference, the hollow body 110 in the pressed state for convenience of the description below is referred to as a 'hollow body before settlement 110', and is unfolded by the expansion of the expansion force forming unit 130 to perforate (1) The hollow body 110 in a state of being fixed to is referred to as a 'hollow body 110B after fixing')

That is, since the inflator 120 is not directly injected into the hollow body 110, it is injected into the expansion force forming unit 130, so that the hollow body 110 may be inflated by the expansion force of the expansion force forming unit 130.

Therefore, the hollow body 110, even if both ends of the hollow 112 of the hollow body 110 is inserted and installed in the perforated (1), so there is no fear that problems such as leakage of the expansion material 120 occurs. The both ends of the hollow 112 of the hollow body 110 do not need to be sealed or hermetically sealed by a cap, a stopper, sealing, packing, or the like.

Therefore, since the elements for sealing, maintaining the airtightness, etc. of the hollow body 110 can be omitted, the structure of the hollow body 110 can be simplified, so that the design of the hollow body 110 is more free It can be lowered and construction cost can be greatly reduced.

In addition, since the hollow body 110 is lighter, a high level of skill and dedicated equipment due to weight are not required.

In addition, since the elements for sealing and maintaining the airtightness are not configured together in the hollow body 110, the construction site after the hollow body 110 is manufactured to an arbitrary size without being limited by the depth of the drilling 1 to be constructed. Since the length of the hollow body 110 can be arbitrarily freely cut in accordance with the depth of perforation (1), the production of the hollow body 110 can be more easily and standardized, and the construction can be easier.

In addition, since the hollow body 110 may be separated and recovered from the hollow body 110 and reused, since only the hollow body 110 is embedded in the ground 2, the construction cost may be reduced. It can be greatly reduced.

In addition, since the inflator 120 does not directly contact the hollow body 110, it is possible to use a fluid or the like that can promote corrosion of the hollow body 110 as the inflator 120. Constraints of the expander 120 due to 110 can be eliminated, and also post-treatment and processing for preventing corrosion due to contact with the expander 120 in the hollow body 110 can be omitted and the expander Constraints, such as the material of the hollow body 110 due to the 120 can be eliminated, and as described above the corrosion of the hollow body 110 due to the expansion material 120 can be prevented bar hollow Durability of the mold body 110 may be improved.

In particular, the hollow body 110 is easily inserted into the perforation 1, and then at least one part is concaved along the circumferential direction (arrow C) so that the hollow body 110 can be expanded and settled in a circular shape by the expander 120. It can be formed to be inserted into the perforation (1) in a pressed state.

The hollow body 110 before the fixing may be made in various shapes as follows. That is, as shown in FIGS. 7B, 14A, and 14B, the hollow body 110B after fixing is formed to have a circular cross section, and the hollow body 110 before fixing is a circumference of the circular hollow body 110. Four, three, and one positions are pressed along the direction (arrow C) in a concave shape, such that the longitudinal cross-section is four-leaf shape (see FIGS. 2-4, 7A), three-leaf shape (see FIG. 5), approximately C It may take the shape of a child (see FIG. 6). However, before fixing the hollow body 110, the expansion force forming unit 130 is inserted into the center of the hollow 112 of the hollow body 110 to form a concentric with the hollow body 110, three or more places It may be more desirable to be pressed in this recessed form. In this case, in the state where the expansion force forming unit 130 is concentric with the hollow body 110, the hollow body 110 may be uniformly spread along the circumferential direction (arrow C) of the hollow body 110. In addition, it may be more advantageous for uniform expansion as described above that the hollow body 110 before being fixed is pressed in a uniformly concave shape along the circumferential direction (arrow C) of the hollow body 110. In addition, the hollow body 110 before the fixing is formed in the center of the hollow 112, the expansion force forming unit 130 is inserted similar to the expansion force forming unit 130 before expansion, the circumference of the central portion of the hollow 112 The width 112A of the opening portion along the direction (arrow C) is formed to be in a range in which the separation of the expansion force forming unit 130 before expansion can be prevented. The expansion force forming unit 130 is the hollow body 110. It may be desirable in that it can be installed to be concentric with.

The hollow body 110 before fixing as described above is bent (flat) the plate-like plate to form a circular tube (tube) or pipe (pipe) and then one side of the outer peripheral surface by folding (rolling) or rolling (rolling) processing It can be produced by pressing inward.

The hollow body 110 may be formed of a variety of materials, in particular, for rigidity, while being excellent in rigidity, is easily formed as the hollow body 110 before fixing as described above, and is expanded by the expansion force forming unit 130. It can be made of steel pipe so that it can be easily unfolded.

The expansion force forming unit 130 may be any one as long as it can be expanded by the inflator 120 to expand the hollow body 110 before fixing to the hollow body 110B after fixing, but it is more preferable to make the following. can do.

That is, the expansion force forming unit 130 is inflated by the expansion material 120 is inserted into the hollow 112, the central portion of the hollow body 110 is injected into the interior, to the discharge of the expansion material 120 injected therein It may include a pack bag 132 that can be inflated by. The pack pouch 132 is easy to inflate / unexpand, and also easy to insert / separate into the hollow 112 of the hollow body 110, to maintain airtightness, and to easily inflow / outlet of the expandable material 120. In that respect, it may be more advantageous.

The pack pouch 132 may be made of an elastic material such as geosynthetic fiber or rubber with elasticity of the material itself, and there is no fear that the pack pouch 132 may be burst by being restrained and supported by the hollow body 110 even when the expansion force by the expander 120 is high pressure. Therefore, any material or shape may be used as long as there is no leakage of the expansion material 120 supplied to the pack bag 132.

However, various media may be used as the expander 120, and among them, hydraulic pressure is preferable as the expander 120 in view of providing sufficient expansion force and easy release and easy handling for the lock bolt. Accordingly, the pack bag 132 may be made of a material, a shape that is connected to the hydraulic power supply unit 200A supplying the hydraulic pressure as the expansion material 200 as the expansion material supply unit 200 and expandable by the hydraulic force.

Such a pack pocket 132 may be more advantageously bundled with a wire or the like in the pre-expansion state so that it can be easily inserted into the hollow body 110 before the fixation. Of course, the wire and the like bound to the pack bag 132 may be made to be easily broken so that the binding of the pack bag 132 due to the wire or the like when the expansion material 120 is supplied.

Further, the expansion force forming unit 130 is inserted into the inside of the pack bag 132 long along the pack bag 132, the inflator pipe 136 is formed with an inflator passage for guiding supply and discharge of the inflating material 120 It may further include. Therefore, it is easy to supply and discharge the expander 120 to the pack bag 132 by the expander tube 136. In addition, before the expansion of the pack pocket 132 to maintain the shape corresponding to the shape of the tube 136 for the expansion material, because the expansion tube 136 can serve as a core material of the pack bag 132, the expansion force forming unit ( It may be easy to insert or separate the 130 into the hollow 112 of the hollow body 110, the hollow body so as to form the expansion force forming unit 130 concentric with the hollow body 110 as described above It can be inserted into the hollow 112 of (110). In this case, the expandable pipe 136 may be both a hard material such as a steel pipe or a soft material such as a rubber hose, and preferably may be made of a hard material such as metal.

In addition, the expansion pipe 136 may be made to be adjustable in length. To this end, the expandable pipe 136 may be implemented in various ways, and may be made as follows.

That is, the expansion pipe 136 is multi-coupled to be movable along the longitudinal direction of the mutual expansion pipe 136, and made of a hollow having a hollow (135A) so that the expansion material 120 can be supplied, discharged The circumferential surface may include a plurality of hollow tubes 135 having a plurality of holes 135B through which the expansion material 120 is supplied and discharged. Therefore, the expansion material 120 is supplied and discharged through the expansion pipe 136 by the expansion material passage through which the expansion material is supplied and discharged by the hollow 135A and the plurality of holes 135B of the plurality of hollow tubes 135. Can be. And, as shown in Figures 10 to 12 when the plurality of hollow tube 135 is pulled out of the adjacent hollow tube 135 along the longitudinal direction can be elongated tube 136 for elongation, shown in Figure 12 As described above, when the plurality of hollow tubes 135 are put in the hollows 135A of the neighboring hollow tubes 135 and overlap with each other, the expandable tubes 136 may be shortened. When the expansion force forming unit 130 is used, the expansion pipe 136 is elongated to be used, and when the expansion force forming unit 130 is not used, the expansion pipe 136 is shortened to be easily stored, moved, and transported. Can be. In addition, the length of the inflator tube 136 can be easily adjusted to correspond to the length of the hollow body 110, and thus the inflator tube 136 is not affected by the change in the length of the hollow body (110) Of course, the expansion force forming unit 130 may be standardized.

In addition, the expansion pipe 136 is a predetermined length of each hollow pipe 135 is moved in a state inserted into the hollow (135A) of the adjacent hollow pipe 135, a stopper (stopper) is provided to prevent separation Can be. The stopper may be implemented in various ways. As a preferred example, the stopper may be formed into a protrusion or a ring shape so as to be inserted into the hollow 135A of the hollow tube 135 adjacent to one end along the longitudinal direction of each hollow tube 135. An inner flange (135C) is formed, it is possible to insert and protrude the neighboring hollow tube 135 at the other end of the hollow tube 135 so that the inner flange (135C) of the neighboring hollow tube 135 can be caught The ring-shaped outer flange 135D may be formed.

In addition, the fastening member 138 has a length in the end along the longitudinal direction in the tube for expansion material 136 so that the pack pocket 132 can be detachably coupled to the tube for expansion material 136 by the fastening member 138. It has a fastening portion 136A is fastened so as to be detachable along the direction, the pack pocket 132 is a through-hole (hereinafter, referred to as a first through-hole 136A for convenience of description) so that the fastening member 138 can be penetrated. May be formed). That is, the fastening part 136A may be integrally formed in the hollow pipe 135 arranged at the end of the plurality of hollow pipes 135 in the longitudinal direction. The fastening member 138 is capable of various implementations, and for example, is made of a bolt to be screwed with the fastening portion 136A of the pipe for expansion material 136 as shown, wherein the fastening portion of the pipe for expansion material 136 136A may be formed of a screw-shaped groove or hole structure so that the fastening member 138 made of bolts can be screwed. At this time, the first through-hole 136A portion of the pack bag 132 is expanded tube 136 as shown in Figure 10 so that the pack bag 132 and the tube 136 for expansion material can be firmly bound to each other. The fastening member 138 may be fastened to the fastening portion 136A of the tube 136 for the expansion material in a state of being fitted to the fastening portion 136A.

In addition, the expander tube 136 may have a coupling portion 136B coupled to the expandable material supply unit 200 for supplying the expandable material to the expandable tube 136. For example, as shown, the expansion material supply part 200 is inserted into the hollow tube 135 arranged at the opposite end to the hollow tube 135 in which the fastening part 136A is formed along the longitudinal direction of the plurality of hollow tubes 135. The coupling part 136B may be integrally formed to be coupled along the direction. The coupling portion 136B of the expansion pipe 136 may be implemented in various ways, and for example, may be formed in a groove or hole structure in which a screw is formed so as to be screwed into the expansion supply supply 200. In addition, the pack pocket 132 is a through hole (hereinafter, referred to as a 'second through hole 132B' for convenience of description) to allow the inlet and outlet of the expandable tube 136 to pass through. May be formed). Thus, the pack bag 132 can be detachably coupled with the expander tube 136.

The expansion force forming unit 130 as described above may act as shown in FIGS. 10 and 11. That is, as shown in Figure 10, each of the hollow tube 135 is inserted into the hollow (135A) of the adjacent hollow tube 135, the length of the tube 136 for the expansion material is short and the pack bag 132 When the inflator 120 is supplied from the inflator supply unit 200 in the folded state, the inflator 120 packs in the order of the hollow 135A of the hollow tube 135 and the hole 135B of the hollow tube 135. 132 is supplied. The pack bag 132 expands as the expander 120 is supplied and expands, and as the pack bag 132 is expanded as shown in FIG. 11, the pack bag 132 is pulled by the pack bag 132 to expand the tube 136 for the expandable material. Gradually longer. Then, the pressed portion of the hollow body 110 is unfolded by the action of the expansion force forming unit 130 may be in close contact with the ground body.

Meanwhile, the rock bolt according to the present invention may further include a pressure plate 140 coupled integrally with the hollow body 110 and in close contact with the ground 2 outside the perforation 1.

The pressure plate 140 may be implemented in various ways as follows.

First, as shown in FIGS. 2 to 6 and 9 to 15b, the pressure plate 140 has a fitting hole 142 into which the hollow body 110 is fitted, and the hollow body 110 is fitted before fixing. It may be formed so as to correspond to the longitudinal cross-sectional shape of the hollow body 110 before fixing. That is, the fitting hole 142 of the pressure plate 140 may have a four-leaf, three-leaf shape, and approximately C-shape corresponding to the shape of the longitudinal section of the hollow body 110 before fixing.

In this case, the acupressure plate 140 is mounted on the hollow body 110 before fixing so that the hollow body 110 is not separated from the hollow body 110 as it is unfolded by the expansion of the expansion force forming unit 130. It may be desirable to be integrally joined after welding by welding or the like.

Secondly, as shown in FIGS. 7A and 7B, the fitting hole 142 of the pressure plate 140 may be fitted with the hollow body 110 before fixing and may correspond to the longitudinal section of the hollow body 110B after fixing. It may be formed to. For example, the fitting hole 142 of the pressure plate 140 may be formed in a substantially circular shape in response to the longitudinal section of the hollow body 110B being substantially circular after fixing. At this time, the fitting hole 142 of the pressure plate 140 may be the same size as the hollow body 110B after fixing, or may be made of a reduced size of a predetermined ratio of the hollow body 110B after fixing. In the latter case, the hollow body 110 can be strongly adhered to the pressure plate 140 while being expanded by the expansion of the expansion force forming unit 130, and the pressure plate 140 and the hollow body 110 are firmly mutually. Can be combined.

In this case, the fitting hole 142 of the acupressure plate 140 is formed to correspond to the hollow body 110B after fixing, it is only fitted to the hollow body 110 before the hollow body 110 is fixed. After the hollow body 110 is fixed, the hollow body 110 may be integrally bonded to the hollow body 110 by welding or the like. Here, the acupressure plate 140 is integrally bonded to the hollow body 110 after the expansion force forming unit 130 is separated from the hollow body 110B after the fixing, interference with the expansion force forming unit 130 It may be more desirable in that it can be prevented.

Meanwhile, the fitting hole 142 of the pressure plate 140 may be formed to have a constant size, as shown in FIG. 8, in a direction toward the inside of the hole 1 outside the hole 1. As described above, the overall size may be gradually expanded. That is, in the latter case, the circumferential surface of the fitting hole 142 of the pressure plate 140 is formed to be inclined at a predetermined angle θ, whereby the fitting hole of the pressure plate 140 is shown in FIGS. 2 to 6. When 142 is formed to correspond to the hollow body 110 before fixing, when the hollow body 110 is unfolded by the expansion of the expansion force forming unit 130, the pressure plate 140 of the hollow body 110, the binding portion This can be guided to smoothly and gradually unfold.

Such a construction method of the rock bolt according to the present invention may be preferably made as follows.

As shown in FIGS. 13A and 13B, the hollow body 110 before insertion is inserted into the perforations 1 formed in the ground 2.

At this time, the hollow body 110 before fixing, as well as other additional elements such as a cap, sealing is not coupled at all, and both ends of the hollow 112 of the hollow body 110 may be installed as it is open.

Then, the expansion force forming unit 130 is inserted into the hollow 112 of the hollow body 110, the expansion force forming unit 130 is hollow before or after the hollow body 110 is inserted into the perforation (1). Insertable into the hollow 112 of the hollow body 110 is inserted into the hollow 112 of the hollow body 110 before the hollow body 110 is inserted into the perforation 1 for easier construction. More preferred.

In addition, the pressure plate 140 is fitted to the hollow body 110, the pressure plate 140 is the hollow body 110 or the fixing before fixing according to the shape of the fitting hole 142 of the pressure plate 140 as described above It can then be integrally bonded to the hollow body (110B).

Next, as shown in FIGS. 14A and 14B, the inflating member 120 is supplied to the pack pocket 132 of the expanding force forming unit 130 through the expandable tube 136 to pack the expanding force forming unit 130. Inflate pocket 132.

Then, the hollow body 110 is unfolded by the expansion of the expansion force forming unit 130 while being fixed in close contact with the periphery (1), the support force can be formed by the lock bolt.

After the hollow body 110 is fixed as described above, as shown in FIGS. 15A and 15B, the pack pocket 132 of the expansion force forming unit 130 is released by releasing the expansion of the pack pocket 132 of the expansion force forming force. After being contracted again, the inflated expansion force forming unit 130 is separated from the fixed hollow body 110. Then, the expansion force forming unit 130 is recovered, and only the hollow body 110 may be embedded in the ground 2 to form the holding force.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

110; Hollow body 120; Inflating material
130; Expansion force forming unit 132; Pack pouch
136; Inflatable tube 140; Acupressure plate

Claims (12)

A ground 112 having a hollow 112 and inserted into a perforation 1 formed in the ground 2 in a state in which at least one portion is pressed in a concave direction along the circumferential direction (arrow C) and then the ground 2 around the perforation 1. A hollow body 110 in which the pressed part is unfolded so as to be installed and fixed in close contact;
It is inserted into the hollow 112 of the hollow body 110, after the fixing of the hollow body 110, the expansion force forming unit 130 is separated from the hollow body 110;
The expansion force forming unit 130 is expanded by the expansion material 120 is inserted into the hollow 112 of the hollow body 110 and injected therein so that the hollow body 110 can be unfolded and injected therein A pack pouch 132 that can be inflated by the discharge of the expanded inflatable material 120;
Lock bolts, characterized in that it comprises an inflator tube 136 inserted into the pack pocket 132 having an inflating passage so as to guide the supply and discharge of the inflating member 120 and adjustable in length. The method according to claim 1,
The hollow body 110 is a rock bolt, characterized in that consisting of a steel pipe. The method according to claim 1,
The hollow body 110 in the pressed state is formed to ensure a space in which the expansion force forming unit 130 before the expansion can be inserted in the central portion of the hollow 112 of the hollow body 110 Rock bolt. The method according to claim 1,
The pressure plate 140 is integrally coupled to the hollow body 110 and in close contact with the ground 2 outside the perforation 1, and is formed to correspond to the hollow body 110 in the pressed state. The lock bolt, characterized in that it has a fitting hole 142, the hollow body 110 is fitted. The method of claim 4,
The fitting hole 142 of the acupressure plate 140 is a lock bolt, characterized in that the overall size is gradually expanded in the direction toward the inside of the perforation (1) outside the perforation (1). The method according to claim 1,
The pressure plate 140 is integrally coupled to the hollow body 110 and tightly attached to the ground 2 outside the perforation 1, and the fitting hole 142 into which the hollow body 110 is fitted is pressed. Rock bolt, characterized in that the hollow body 110 can be fitted and formed to correspond to the reduced shape of the cross-section of the hollow body (110B) after the fixing. The method according to claim 1,
The pressure plate 140 is integrally coupled with the hollow body 110 and in close contact with the ground 2 outside the perforation 1, and is formed to correspond to the hollow body 110B after the fixing. Lock bolt, characterized in that it has a fitting hole 142 is fitted. The method according to any one of claims 1 to 7,
The inflator tube 136 comprises a plurality of hollow tubes 135 arranged in a longitudinal direction of the inflator tube 136 and having a hollow shape having a hollow 135A so as to be multi-coupled with each other;
Each of the hollow tube 135 is formed so that the adjacent hollow tube 135 is inserted or inserted into the adjacent hollow tube 135 along the longitudinal direction of the expandable tube 136, the adjacent hollow tube ( 135) A lock bolt, characterized in that the stopper is provided so as to be movable along a predetermined length and prevented from being separated. The method according to any one of claims 1 to 7,
The fastening member 138 is provided at the end along the longitudinal direction of the expandable tube 136 so that the pack pocket 132 can be detachably coupled to the expandable tube 136 by the fastening member 138. Lock bolt having a fastening portion (136A) to be detachably fastened along the longitudinal direction, the pack pocket 132 is formed with a through hole (132A) so that the fastening member (138). The method according to any one of claims 1 to 7,
The inflator tube 136 has a coupling portion 136B coupled to the inflatable material supply unit 200 for supplying the inflating material to the inflator tube 136 and detachably coupled thereto.
The pack pocket 132 is a lock bolt, characterized in that the through-hole 132B is formed so that the expansion material supply portion 200 can pass through. The method according to any one of claims 1 to 7,
The expansion pipe 136 is a lock bolt, characterized in that connected to the hydraulic pressure supply unit (200A) for supplying the hydraulic pressure as the expansion material 120, so that the pack bag 132 can be expanded by the hydraulic force. As a method of constructing the rock bolt of any one of claims 1 to 7,
Inserting the hollow body 110 into which the expansion force forming unit 130 is inserted into the perforation 1, or inserting the perforation inserting the expansion force forming unit 130 into the hollow body 110 inserted into the perforation 1. step;
After the drilling insertion step, by supplying the expansion material 120 to the pack pocket 132 through the expansion pipe 136 so that the hollow body 110 is fixed to the expansion force forming unit 130 A fixing step for forming support force;
After the fixing step, by discharging the expansion bag supplied to the pack bag 132 through the expansion pipe 136 to release the pack bag 132, the expansion force forming unit 130 is hollow An expansion force forming unit recovery step of separating and recovering from the body 110;
Rock bolt construction method comprising a.

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