KR101199514B1 - Apparatus for preventing tunnel-caving in - Google Patents

Abstract

In the tunnel collapse prevention device for preventing the collapse of the side wall of the tunnel excavation work, Rock bolt screw 211 is formed at the end of the lock bolt 210 is inserted into the tunnel side wall; And a support part 231 for supporting the end face of the rigid retainer formed in a semicircle shape (tunnel cross-sectional shape) to support the tunnel excavation surface and from the both sides of the support part 231 to accommodate the lock bolt 210. Support 230 consisting of the bent portion 232 bent upward; And a guide plate hole 221 communicating with the inside of the bent portion 232 to accommodate the lock bolt 210 as the guide plate hole 221, and a portion where the guide plate hole 221 is formed is bent. A lock bolt guide plate 220 formed to be drawn into the bent portion 232 of the support 230; And a tunnel side wall fixing part 240 which is coupled to one end of the lock bolt 210 and is an end part which is inserted into the tunnel side wall; And a nut 205 fastened to the other end of the lock bolt 210 and fixing the lock bolt 210 to the lock bolt guide plate 220.

Description

Tunnel collapse prevention device {APPARATUS FOR PREVENTING TUNNEL-CAVING IN}

The present invention relates to a tunnel collapse prevention tool and a tunnel construction method using the same to support the lower end of the stiff ground for preventing the collapse of the tunnel rig in tunnel excavation work, and to withstand the side pressure applied to the stiff ground from the tunnel sidewall. will be.

In the tunnel excavation work, in order to secure the stability of the tunnel face, a secondary method such as steel pipe multistage grouting or poa pooling is usually applied, and after the tunnel is excavated, primary shotcrete, wire mesh installation, and rigid ground construction are installed. Second shotcrete pouring is performed sequentially.

In this process, if the ground fault or over excavation causes a lack of bearing capacity of the stiff ground, or the lateral pressure applied from the side of the tunnel is excessive, the side surface of the tunnel is pushed into the tunnel excavation space, and the top and side walls of the tunnel collapse. Frequent accidents used to occur frequently.

In order to prevent such a phenomenon, it has conventionally been a general method to cope with the side pressure applied on the tunnel sidewall by placing a 'temporary inverter concrete' on the excavation bottom surface of the upper half of the tunnel.

However, there have been various problems in placing the temporary inverter concrete.

That is, after placing the temporary inverter concrete, it cannot endure the tunnel side pressure until the concrete is hardened. Even after the concrete is hardened, the temporary inverted concrete must be destroyed and removed to excavate the lower half of the tunnel. There was a problem in that the tunnel sidewall portion again behaved by the tunnel side pressure.

The present invention has been made to solve the problems in the conventional tunnel excavation work, the object of the present invention is as follows.

First, in contrast to the conventional tunnel side pressure is to provide a tunnel collapse prevention tool and the tunnel construction method using the temporary inverted concrete concrete installation itself, which is constructed over a large area on the tunnel bottom surface.

In addition, it is an object of the present invention to reduce the time loss and the economic cost associated with the temporary inverter concrete pouring work.

Secondly, while providing an effective tunnel collapse prevention tool and a tunnel construction method using the same, while effectively coping with the side pressure applied from the tunnel side wall.

The present invention has been made to achieve the above object, looking at the configuration as follows.

In the tunnel collapse prevention device for preventing the collapse of the side wall of the tunnel excavation work,

A rock bolt 210 having a rock bolt screw 211 formed at an end thereof; Wow

A support portion 231 for supporting the end surface of the rigid support formed in a semi-circle shape (tunnel cross-section) to support the tunnel excavation surface and upward from both sides of the support portion 231 to accommodate the lock bolt 210. Support 230 consisting of the bent portion 232 bent to; Wow

A guide plate hole 221 communicating with the bent portion 232 is formed, and accommodates the lock bolt 210 as a guide plate hole 221, and a portion where the guide plate hole 221 is formed is bent. Lock bolt guide plate 220 formed to be drawn into the bent portion 232 of the support 230; and

A tunnel side wall fixing part 240 which is fastened to one end of the lock bolt 210 and is a distal end which is inserted into the tunnel side wall; And

The lock bolt 210 is fastened with the other end, the tunnel collapse prevention device, characterized in that it comprises a nut (205) for fixing the lock bolt 210 to the lock bolt guide plate (220).

When explaining the structure of the bent portion 232 in more detail, the shape is bent to the letter 'c', the bent portion of the portion where the guide plate hole 221 of the lock bolt guide plate 220 is formed 'c' In addition to being formed in the shape of a child, the 'c' is characterized in that it is formed in a size corresponding to the internal size of the bent portion 232 of the shape.

In addition, the tunnel side wall fixing portion 240, the one side receives the lock bolt screw 211, the end is a piston head (243) formed with a conical surface 244; Wow,

In contact with the piston head conical surface 244, the force applied from the piston head conical surface 244 is transmitted through the bit conical surface 246, through which the tunnel side wall fixing portion 240 through the protruding bit hole 242 Protruding bit 241 protruding perpendicular to the longitudinal direction

Characterized in that it comprises a.

In addition, to provide a tunnel construction method using the tunnel collapse prevention tool.

Other details are described in the section titled 'Details on the invention'.

According to the present invention, the following effects can be expected.

In other words, since the construction of the temporary inverter concrete that was performed on the excavated bottom surface of the upper half of the existing tunnel is unnecessary, it is possible to solve the time and cost problems required for the work at once.

In particular, it was not possible to dispel the fear of tunnel collapse by tunnel side pressure until the temporary inverter concrete solidified, but the risk of tunnel collapse was greatly reduced by the present invention.

In addition, in order to excavate the lower half of the tunnel, the problem of having to break the temporary inverter concrete to be removed also can be solved by the present invention.

Tunnel collapse prevention tool of the present invention and the tunnel construction method using the same, the structure and the construction method is simple, but can effectively cope with the side pressure of the tunnel, it is very easy to install it can obtain a remarkable effect in reducing the construction period and construction cost.

1 is a view for explaining the construction method of the construction of the conventional temporary inverter concrete;
Figure 2 is a view for explaining the position where the tunnel collapse prevention apparatus of the present invention is installed,
Figure 3 is a perspective view of the tunnel collapse prevention apparatus of the present invention is coupled,
FIG. 4 is an exploded perspective view of FIG. 3,
5 is a view showing a detailed structure of the tunnel side wall fixing portion,
6 to 10 are views for explaining the construction method using the tunnel decay prevention device of the present invention.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings.

However, the technical idea of the present invention is not limited to the following examples, and any inventions of equivalent invention level grasped from the claims will be clarified in advance that they all belong to the scope of the present invention.

1 is a view for explaining the construction method of the conventional construction of the inverter concrete pouring and FIG. 2 is a view for explaining the position where the tunnel collapse prevention device of the present invention is installed and Figure 3 is a tunnel collapse prevention device of the present invention is combined 4 is an exploded perspective view of FIG. 3 and FIG. 5 is a view illustrating a detailed structure of the tunnel side wall fixing part.

If you look briefly at the conventional tunnel excavation and steel plate installation process, first perform the multi-stage grouting work for the membrane stability, then excavate the upper half of the tunnel, and then install the primary shotcrete and wire mesh (not shown).

Then, as shown in Figure 1, along the tunnel excavation surface 100 to install the retaining material (110, see Figure 2) at regular intervals. In FIG. 2, the H-shaped steel retainer is illustrated, but a lattice-shaped retainer may be installed.

After the installation of the retaining material 110, the secondary shotcrete is installed, and then the temporary inverter concrete 150 as shown in FIG. 1 is placed.

At the lower end of the side wall of the tunnel, side pressures in the direction A and A 'of FIG. 1 are applied to the rigid holding material 110, and the temporary inverter concrete 150 exerts a force that resists the side pressure, and thus the rigid holding material 110 is This is to prevent the tunnel collapse caused by being pushed into the tunnel.

However, as described above, after placing the temporary inverter concrete 150, until the concrete is hardened, the tunnel side pressure cannot be tolerated, and there is a fear of tunnel collapse. Even after the concrete is hardened, excavation at the lower half of the tunnel is performed. In order to destroy and remove the temporary inverted concrete 150, there is a problem that the tunnel sidewall portion again behaves by the tunnel side pressure after this point.

In addition, since the temporary inverter concrete 150 is carried out over a wide area of the tunnel bottom surface 155, there is a problem that a lot of time and economic cost is generated.

Tunnel decay protection 200 according to a preferred embodiment of the present invention is shown in detail in Figures 3 and 4 and Figure 2 is a tunnel decay prevention device 200 is installed on each of the lower end of each side of the retaining material 110 I can grasp that.

First, looking at the structure and function of the general tunnel decay prevention device 200 of the present invention as follows (see Figs. 2 to 4).

That is, the tunnel collapse prevention device 200, as shown in Figure 4, the lock bolt 210 and the support bolt 230 and the rock bolt to hold the rigid retainer is coupled to one side of the rock bolt to the support 230 The lock bolt guide plate 220 to guide and the tunnel side wall fixing part 240 of the rightmost.

As shown in FIG. 2, the end of the rigid retainer 110 is supported by being mounted on the supporting part 231, and the lock bolt 210 penetrates into the tunnel sidewall and protrudes a bit 241 at the sidewall fixing part 240. This prevents the lock bolt from escaping from the tunnel sidewall.

The structure of the tunnel decay prevention apparatus 200 of the present invention is summarized again.

A lock bolt screw 211 is formed at one end thereof, and a lock bolt 210 inserted into the tunnel sidewall; Wow

Support portion 231 for supporting the end surface of the rigid retaining member 110 is formed in a semi-circular form (tunnel cross-sectional shape) to support the tunnel excavation surface and the support portion 231 to accommodate the lock bolt 210 Support 230 consisting of the bent portion 232 bent upwards from both sides; Wow

A guide plate hole 221 communicating with the bent portion 232 is formed, and accommodates the lock bolt 210 as a guide plate hole 221, and a portion where the guide plate hole 221 is formed is bent. Lock bolt guide plate 220 formed to be drawn into the bent portion 232 of the support 230; and

A tunnel side wall fixing part 240 which is fastened to one end of the lock bolt 210 and is a distal end which is inserted into the tunnel side wall; And

It is fastened to the other end of the lock bolt 210, characterized in that it comprises a nut 205 for fixing the lock bolt 210 to the lock bolt guide plate 220.

Referring to the principle of enduring the tunnel side pressure, as shown in Figure 2, after the rigid support 110 is placed on the support 231, the pressure is received from the tunnel side wall, wherein the lock bolt guide plate 220 is a portion of the tunnel side wall Will correspond to the side pressure.

The bent portion 232 is bent in a semicircular or polygonal shape (triangular, square, etc.) covered with an upper portion, and the bent portion of the portion where the guide plate hole 221 of the rock bolt guide plate 220 is formed is also bent portion ( It is formed in a shape and size corresponding to 232, it is characterized in that the clearance is minimized by being embedded in the bent portion 232.

In FIG. 4, the bent portion 232 is bent in a 'c' shape, and a bent portion of a body (rock bolt guide plate body) portion in which the guide plate hole 221 of the lock bolt guide plate 220 is formed is also illustrated. It is formed in a 'c' shape, and is formed in a size corresponding to the inside of the bent portion 232 of the 'c' shape. As described above, the bent portion of the rock bolt guide plate 220 is inserted into the bent portion 232 of the support 230 so as to minimize shaking.

As described above, the structure of the bent portion is not necessarily limited to the 'c' shape will be possible in various forms of deformation that can accommodate the lock bolt 210 inside.

The tunnel side wall fixing part 240 accommodates the lock bolt screw 211 in one direction. The designation of the tunnel side wall fixing part 240 means that the lock bolt is fixed to the tunnel side wall so that the lock bolt 210 does not easily fall out of the tunnel side wall.

The end portion of the tunnel side wall fixing part 240 may be manufactured to have a flat, pointed or other shape.

Inside the tunnel side wall fixing part 240, a piston head 243 and a protruding bit 241 having a conical surface 244 on one side are formed.

The principle that the protruding bit 241 protrudes is as follows (see FIG. 5).

That is, in contact with the conical surface 244 of the piston head, the force applied from the piston head conical surface 244 is transmitted through the bit conical surface 246, through which the tunnel side wall fixing portion through the protruding bit hole 242 240, the protruding bit 241 perpendicularly to the longitudinal direction is to come out. By this protruding bit, it is possible to effectively prevent the lock bolt 210 from being drawn out of the tunnel side wall.

The structure of the protruding bit 241 is described in detail in the applicant's patent (Registration No .: 10-0820642, filing date: September 15, 2007) and is applied to the present invention as a tunnel sidewall decay prevention device.

On the other hand, the outer surface of the lock bolt 210 is preferably formed in a concave-convex shape in order to exhibit a resistance, preferably made of a length of about 30 to 80 centimeters, but is not necessarily limited thereto.

A process of installing the tunnel collapse prevention apparatus 200 of the present invention on the tunnel sidewall will be described with reference to FIGS. 6 to 10.

First, as shown in FIG. 6, the boring hole (see FIG. 6) into which the lock bolt 210 may be inserted into the tunnel sidewall is drilled in a semicircular shape with a stiff retaining material installed in parallel with the tunnel wall.

Next, the lock bolt is inserted into the drilling hole as shown in FIG. 7, and the space around the lock bolt is filled by grouting in FIG. 8.

Next, in Fig. 9, the support and the lock bolt guide plate are installed in turn, and finally, the nut and the lock bolt are firmly fastened. (The lock bolt portion embedded in the tunnel sidewall is not shown.)

The following effects can be expected by the construction method described above.

In other words, since the construction of the temporary inverter concrete that was performed on the excavated bottom surface of the upper half of the existing tunnel is unnecessary, it is possible to solve the time and cost problems required for the work at once.

In particular, it was not possible to dispel the fear of tunnel collapse by tunnel side pressure until the temporary inverter concrete solidified, but the risk of tunnel collapse was greatly reduced by the present invention.

In addition, in order to excavate the lower half of the tunnel, the problem of having to break the temporary inverter concrete to be removed also can be solved by the present invention.

Tunnel collapse prevention tool of the present invention and the tunnel construction method using the same, the structure and the construction method is simple, but can effectively cope with the side pressure of the tunnel, it is very easy to install it can obtain a remarkable effect in reducing the construction period and construction cost.

As described above, the scope of the present invention is not limited to the above embodiments, and all equivalent levels of invention that can be understood by those skilled in the art belong to the scope of the present invention.

A, A ': Tunnel sidewall pressure (side pressure)
100: tunnel excavation surface 110: steel plate
150: Hypothetical inverter concrete
155: tunnel bottom
200: collapse prevention 205: nut
210: Lock bolt 211: Lock bolt screw
220: Lock bolt guide plate
221: guide plate hole 230: support
231: base 240: tunnel side wall fixing
241: protrusion bit 242: protrusion bit hole
243: piston head 244: piston head conical surface
245: lock bolt thread
246: bit conical

Claims (4)

In the tunnel collapse prevention device for preventing the collapse of the side wall of the tunnel excavation work,
A lock bolt screw 211 is formed at an end thereof and is inserted into the tunnel side wall; Wow
A support portion 231 for supporting the end surface of the rigid support formed in a semi-circle shape (tunnel cross-section) to support the tunnel excavation surface and upward from both sides of the support portion 231 to accommodate the lock bolt 210. Support 230 consisting of the bent portion 232 bent to; Wow
A guide plate hole 221 communicating with the bent portion 232 is formed, and accommodates the lock bolt 210 as a guide plate hole 221, and a portion where the guide plate hole 221 is formed is bent. Lock bolt guide plate 220 formed to be drawn into the bent portion 232 of the support 230; and
A tunnel side wall fixing part 240 which is fastened to one end of the lock bolt 210 and is a distal end which is inserted into the tunnel side wall; And
Is coupled to the other end of the lock bolt 210, and includes a nut 205 for fixing the lock bolt 210 to the lock bolt guide plate 220,

The bent portion 232 is bent in a semicircular or polygonal shape covered with an upper portion,
The bent portion of the portion where the guide plate hole 221 of the rock bolt guide plate 220 is formed is also formed in the shape and size corresponding to the bent portion 232, it can be embedded in the bent portion 232 Tunnel collapse prevention device characterized in that the. delete delete delete

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