KR102155767B1 - Falling-off prevention apparatus for rock bolt - Google Patents

Abstract

The present invention includes a body 110 having an insertion hole 111 formed along the upper and lower direction in the core portion so that the rock bolt 10 is inserted, and a coupling hole 112 formed along the side direction; A through hole 121 is formed along the vertical direction in the deep portion so that the rock bolt 10 penetrates, and coupled to the coupling hole 112 so as to flow in the lateral direction, and to be supported by contacting the inner wall of the perforated hole. A flow member 120 having a support part 122 formed thereon and having a weight part 123 formed on the other side to generate a centrifugal force during rotation; Including; an elastic member 130 coupled between the main body 110 and the moving member 120 so as to maintain a state in which the support part 122 of the moving member 120 protrudes from the main body 110 to one side. And, in normal times, due to the elastic force of the elastic member 130, the support part 122 of the movable member 120 protrudes from the main body 110 to one side, so that the support part 122 is in contact with the inner wall of the perforated hole. Thus, the lock bolt 10 is fixed to a certain position, and when the lock bolt 10 is rotated, the main body 110 and the moving member 120 rotate together, and the centrifugal force of the weight part 123 , The weight part 123 of the flow member 120 protrudes from the main body 110 to the other side, so that the contact between the support part 122 and the inner wall of the perforated hole is released. ), so that the rock bolt does not come off from the perforated hole until the adhesive exerts adhesion, and does not interfere with the removal operation when the rock bolt needs to be removed.

Description

Rock bolt dropout prevention device {FALLING-OFF PREVENTION APPARATUS FOR ROCK BOLT}

The present invention relates to the field of construction, and more particularly, to a device for preventing the falling off of a rock bolt.

NATM construction method is mainly applied to domestic tunnel construction, and in this construction method, rock bolts are used as the main support.

1 shows the construction process of a conventional rock bolt.

① Form a hole in the rock, ② Insert the resin capsule into the hole, and ③ Insert the rock bolt into the hole while rotating it. ⑤ Finish by installing a plate and a nut at the tip of the rock bolt.

The support pattern is different depending on the strength of the rock, but unless the rock is very good, rock bolts must be installed in a direction perpendicular to the ceiling or in a direction close to the vertical.

In the case of rock bolts installed in the vertical direction or in a direction close to the vertical as described above, the adhesive (resin, cement mortar) does not harden quickly, and the rock bolts are often dropped out of the perforated hole.

In this case, it is not possible to install the next rock bolt, and the worker holds the rock bolt until the adhesive hardens, or the worker picks up a stone nearby and temporarily fixes it by inserting it between the rock malt and the drilled hole.

In more severe cases, unlike the blueprint, the vertical direction is abandoned, and a rock bolt is installed in a direction close to the horizontal to prevent dropout, which is a violation of regulations and poses a risk to the stability of the tunnel.

On the other hand, there are cases in which the rock bolts are not properly inserted into the drilled hole due to the presence of rock mass protruding inside the drilled hole, or narrowing (or clogging) inside the drilled hole due to the passage of time during the insertion operation. Remove the lock bolt from the hole, re-drill and install the lock bolt again.

In the case of applying a simple wedge-structured drop-out prevention device to the rock bolt to prevent the rock bolt from falling off, there is a problem that the removal operation is hindered when the rock bolt is removed as described above.

Therefore, in the case of rock bolts that are installed in the vertical or near-vertical direction, the lock bolts do not come off from the drilled holes until the adhesive exerts adhesion, and if the lock bolts need to be removed, the removal work is not disturbed. There was an urgent need to develop a device to do it.

The present invention was derived to solve the above problems, and prevents the rock bolt from falling out of the perforated hole until the adhesive exerts adhesive force, and prevents the removal of the rock bolt from interfering with the removal operation if necessary. Its purpose is to present a lock bolt drop-out prevention device.

In order to solve the above problems, the present invention includes a main body 110 having an insertion hole 111 formed along an up-down direction in the core portion so that the rock bolt 10 is inserted, and a coupling hole 112 formed along the side direction; A through hole 121 is formed along the vertical direction in the deep portion so that the rock bolt 10 penetrates, and coupled to the coupling hole 112 so as to flow in the lateral direction, and to be supported by contacting the inner wall of the perforated hole. A flow member 120 having a support part 122 formed thereon and having a weight part 123 formed on the other side to generate a centrifugal force during rotation; Including; an elastic member 130 coupled between the main body 110 and the moving member 120 so that the support part 122 of the moving member 120 protrudes from the main body 110 to one side. And, in normal times, due to the elastic force of the elastic member 130, the support part 122 of the movable member 120 protrudes from the main body 110 to one side, so that the support part 122 is in contact with the inner wall of the perforated hole. Thus, the lock bolt 10 is fixed to a certain position, and when the lock bolt 10 is rotated, the main body 110 and the moving member 120 rotate together, and the centrifugal force of the weight part 123 , The weight part 123 of the flow member 120 protrudes from the main body 110 to the other side, so that the contact between the support part 122 and the inner wall of the perforated hole is released. ).

It is preferable that the flow member 120 has a plate-shaped structure, and the main body 110 has a structure in which a pair of plates are combined at intervals and the coupling holes 112 are formed therebetween.

It is preferable that the support part 122 has a pointed structure toward one side.

It is preferable that the support part 122 bends toward the entrance of the perforation hole.

In spite of the flow of the movable member 120, the movable member compared to the diameter of the insertion hole 111 of the main body 110 so that the rock bolt 10 maintains the through-hole 121 through the through-hole 121 It is preferable that the diameter of the through hole 121 of 120 is formed large.

It is preferable that the insertion hole 111 and the through hole 121 have an elliptical structure.

It is preferable that the elliptical structure has a long axis along the direction in which the support part 122 and the weight part 123 are formed.

The elastic member 130 is installed in a portion adjacent to the weight part 123 of the edge region of the insertion hole 111 of the main body 110 and the edge region of the through hole 121 of the flow member 120 It is desirable.

The present invention provides a device for preventing the rock bolt from falling off from the perforated hole until the adhesive exerts adhesive force and preventing the rock bolt from falling out of the removal operation when it is necessary to remove the rock bolt.

1 is a process diagram of a conventional rock bolt method.
2 or less shows an embodiment of the present invention,
2 is a perspective view of the main body.
3 is a perspective view of a flow member.
4 is a perspective view of a first use state.
Figure 5 is a perspective view of a second use state.
6 is a cross-sectional view of a first use state.
7 is a cross-sectional view of a second use state.
Figure 8 is a side view of a third use state.

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

As shown in Figure 2 below, the lock bolt drop-out prevention device 100 according to the present invention basically includes a main body 110, a flow member 120, and an elastic member 130, and a fall-out prevention device (100) One or more is installed and used on the rock bolt 10 at intervals (Fig. 8).

In the main body 110, an insertion hole 111 is formed along the vertical direction in the core portion so that the rock bolt 10 is inserted, and a coupling hole 112 is formed along the side direction (FIG. 2).

The flow member 120 has a through hole 121 formed in the upper and lower direction in the deep portion so that the rock bolt 10 penetrates, is coupled to the coupling hole 112 so that it can flow in the lateral direction, and contacts the inner wall of the perforated hole. Thus, a support part 122 is formed on one side to be supported, and a weight part 123 is formed on the other side to generate a centrifugal force during rotation (FIG. 3).

The elastic member 130 is coupled between the main body 110 and the moving member 120 so that the support part 122 of the moving member 120 protrudes from the main body 110 to one side (Figs. 6 and 7 ).

Normally, when the rock bolt 10 is inserted into the perforated hole, by the elastic force of the elastic member 130, the support part 122 of the flow member 120 protrudes from the main body 110 to one side, and the support part 122 and The rock bolt 10 is fixed at a predetermined position by contacting the inner wall of the perforated hole (Figs. 4 and 6).

When the lock bolt needs to be removed, the lock bolt 10 is rotated and removed to the outside of the perforated hole. When the lock bolt 10 is rotated, the main body 110 and the moving member 120 rotate together. In addition, by the centrifugal force of the weight portion 123, the weight portion 123 of the flow member 120 protrudes from the main body 110 to the other side, so that the contact between the support portion 122 and the inner wall of the perforated hole is released, the lock bolt It does not interfere with the removal operation of (Figs. 5, 7).

Therefore, there is a peculiar effect of preventing the rock bolt from falling out of the perforated hole until the adhesive exerts adhesive force, and preventing interference with the removal operation when the rock bolt is required to be removed.

The flow member 120 has a plate-shaped structure, and it is preferable for the main body 110 to have a structure in which a pair of plates are joined at intervals and a coupling hole 112 is formed therebetween for ease of manufacture and convenience of construction ( Fig. 2,3).

Since the support part 122 of the flow member 120 contacts the inner wall of the perforated hole and serves to fix the rock bolt 10 at a certain position when the rock bolt is inserted, the support part 122 has a pointed structure toward one side. It is preferable to take (Figs. 3 to 5).

Furthermore, when the support part 122 has a curved structure toward the entrance of the perforated hole, it is possible to more stably prevent the rock bolt 10 from falling off (departing toward the entrance direction) (FIGS. 6 and 7).

The lock bolt 10 is inserted into the insertion hole 111 of the main body 110, and since the device for preventing dropping 100 must also rotate when the lock bolt 10 is rotated, the insertion hole 111 of the main body 110 It is preferable to take the same shape as the outer periphery of the silver rock bolt (10).

In this case, in spite of the flow of the flow member 120 (protruding from one side of the support part 122 in normal times, and protruding from the other side of the weight part 123 when rotating), the rock bolt 10 is a through hole of the flow member 120 ( In order to maintain the penetrating state for 121, it is preferable that the diameter of the through hole 121 of the moving member 120 is formed larger than the diameter of the insertion hole 111 of the main body 110 (FIGS. 3 to 7 ).

There is a case where the cross section of the rock bolt 10 is formed in an elliptical shape. In this case, it is preferable that the insertion hole 111 and the through hole 121 also have an elliptical structure to fit this.

In this elliptical structure, it is preferable that the long axis is formed along the direction in which the support part 122 and the weight part 123 are formed (flow direction of the flow member 120).

The elastic member 130 is a general spring structure if the structure is coupled between the main body 110 and the moving member 120 so that the support part 122 of the moving member 120 protrudes from the main body 110 to one side. , Leaf spring structure, etc.

However, in the case where the elastic member 130 is installed in a portion adjacent to the weight part 123 of the edge region of the insertion hole 111 of the main body 110 and the edge region of the through hole 121 of the flow member 120, There are advantages such as that it stably prevents the protrusion of the weight part 123 in normal times, and that it is easy to secure a spare space for installation of the elastic member (FIGS. 6 and 7 ).

Since the above is only described with respect to some of the preferred embodiments that can be implemented by the present invention, as well known, the scope of the present invention should not be limited to the above embodiments and should not be interpreted. It will be said that both the technical idea and the technical idea together with the fundamental are included in the scope of the present invention.

10: lock bolt 100: lock bolt dropout prevention device
110: main body 111: insertion hole
112: coupling hole 120: moving member
121: through hole 122: support
123: weight part 130: elastic member

Claims (8)

delete The body 110 is formed with an insertion hole 111 along the vertical direction in the core so that the rock bolt 10 is inserted, and the coupling hole 112 is formed along the lateral direction;
A through hole 121 is formed along the vertical direction in the deep portion so that the rock bolt 10 penetrates, and coupled to the coupling hole 112 so as to flow in the lateral direction, and to be supported by contacting the inner wall of the perforated hole. A flow member 120 having a support part 122 formed thereon and having a weight part 123 formed on the other side to generate a centrifugal force during rotation;
Including; an elastic member 130 coupled between the main body 110 and the moving member 120 so as to maintain a state in which the support part 122 of the moving member 120 protrudes from the main body 110 to one side. and,
Normally, by the elastic force of the elastic member 130, the support part 122 of the flow member 120 protrudes from the main body 110 to one side, and is locked by contact between the support part 122 and the inner wall of the perforated hole. Fix the bolt (10) in a certain position,
When the rock bolt 10 is rotated, the main body 110 and the moving member 120 rotate together, and by the centrifugal force of the weight part 123, the moving member 120 from the main body 110 The weight part 123 of is protruded to the other side, so that the contact between the support part 122 and the inner wall of the perforated hole is released,
The movable member 120 has a plate-shaped structure, and the main body 110 has a structure in which a pair of plates are combined at intervals and the coupling hole 112 is formed therebetween. ). The body 110 is formed with an insertion hole 111 along the vertical direction in the core so that the rock bolt 10 is inserted, and the coupling hole 112 is formed along the lateral direction;
A through hole 121 is formed along the vertical direction in the deep portion so that the rock bolt 10 penetrates, and coupled to the coupling hole 112 so as to flow in the lateral direction, and to be supported by contacting the inner wall of the perforated hole. A flow member 120 having a support part 122 formed thereon and having a weight part 123 formed on the other side to generate a centrifugal force during rotation;
Including; an elastic member 130 coupled between the main body 110 and the moving member 120 so as to maintain a state in which the support part 122 of the moving member 120 protrudes from the main body 110 to one side. and,
Normally, by the elastic force of the elastic member 130, the support part 122 of the flow member 120 protrudes from the main body 110 to one side, and is locked by contact between the support part 122 and the inner wall of the perforated hole. Fix the bolt (10) in a certain position,
When the rock bolt 10 is rotated, the main body 110 and the moving member 120 rotate together, and by the centrifugal force of the weight part 123, the moving member 120 from the main body 110 The weight part 123 of is protruded to the other side, so that the contact between the support part 122 and the inner wall of the perforated hole is released,
The support part 122 is a rock bolt drop-out prevention device 100, characterized in that it has a pointed structure toward one side. The method of claim 3,
The support part 122 is a rock bolt drop-out prevention device 100, characterized in that the structure bent toward the entrance of the perforated hole. The body 110 is formed with an insertion hole 111 along the vertical direction in the core so that the rock bolt 10 is inserted, and the coupling hole 112 is formed along the lateral direction;
A through hole 121 is formed along the vertical direction in the deep portion so that the rock bolt 10 penetrates, and coupled to the coupling hole 112 so as to flow in the lateral direction, and to be supported by contacting the inner wall of the perforated hole. A flow member 120 having a support part 122 formed thereon and having a weight part 123 formed on the other side to generate a centrifugal force during rotation;
Including; an elastic member 130 coupled between the main body 110 and the moving member 120 so as to maintain a state in which the support part 122 of the moving member 120 protrudes from the main body 110 to one side. and,
Normally, by the elastic force of the elastic member 130, the support part 122 of the flow member 120 protrudes from the main body 110 to one side, and is locked by contact between the support part 122 and the inner wall of the perforated hole. Fix the bolt (10) in a certain position,
When the rock bolt 10 is rotated, the main body 110 and the moving member 120 rotate together, and by the centrifugal force of the weight part 123, the moving member 120 from the main body 110 The weight part 123 of is protruded to the other side, so that the contact between the support part 122 and the inner wall of the perforated hole is released,
In spite of the flow of the movable member 120, the movable member compared to the diameter of the insertion hole 111 of the main body 110 so that the rock bolt 10 maintains the through-hole 121 through the through-hole 121 Rock bolt drop-out prevention device 100, characterized in that the diameter of the through hole 121 of 120 is formed large. The method of claim 5,
The insertion hole 111 and the through hole 121 is a rock bolt drop-out prevention device 100, characterized in that the oval structure. The method of claim 6,
The elliptical structure has a long axis formed along a direction in which the support part 122 and the weight part 123 are formed. The body 110 is formed with an insertion hole 111 along the vertical direction in the core so that the rock bolt 10 is inserted, and the coupling hole 112 is formed along the lateral direction;
A through hole 121 is formed in the upper and lower direction in the deep portion so that the rock bolt 10 penetrates, coupled to the coupling hole 112 so as to flow along the lateral direction, and being supported by contacting the inner wall of the perforated hole. A flow member 120 having a support part 122 formed thereon and having a weight part 123 formed on the other side to generate a centrifugal force during rotation;
Including; an elastic member 130 coupled between the main body 110 and the moving member 120 so that the support part 122 of the moving member 120 protrudes from the main body 110 to one side. and,
Normally, by the elastic force of the elastic member 130, the support part 122 of the movable member 120 protrudes from the main body 110 to one side, and is locked by contact between the support part 122 and the inner wall of the perforated hole. Fix the bolt (10) in a certain position,
When the rock bolt 10 rotates, the main body 110 and the moving member 120 rotate together, and by the centrifugal force of the weight part 123, the moving member 120 from the main body 110 The weight part 123 of is protruded to the other side, so that the contact between the support part 122 and the inner wall of the perforated hole is released,
The elastic member 130,
A rock bolt to prevent falling off, characterized in that it is installed in a portion adjacent to the weight part 123 of the edge region of the insertion hole 111 of the main body 110 and the edge region of the through hole 121 of the flow member 120 Device 100.

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