KR100512479B1 - The method of consolidation for excavating tunnel and the lagging being in used in this method - Google Patents

Abstract

The present invention relates to a method of constructing an underground tunnel at a relatively shallow position from the ground surface, and more particularly, by inserting a consolidation earth plate into the space of the rear portion where a messer plate for excavating a tunnel is transferred to the upper base plate as a hydraulic cylinder. The voids between the two are consolidated by either cement or milk, and the cement filling grout is injected between the consolidation earth plate and the ground, thereby providing a compact and secure underground tunnel for the construction of underground tunnels without fear of ground subsidence. It relates to a consolidated earth plate used.

According to the present invention, after assembling the rigid beam 3 to the tunnel shape at the entrance of the tunnel, the step of making the oscillation base (1) by arranging the method plate (2) in parallel outside the rigid beam (3); After the step of making the oscillation base (1), the excavation step of advancing by pressing the method plate (2) with a hydraulic jack; After the excavation step, the step of installing a consolidation earth plate (4) between the exposed portion of the advanced method plate (2) and the upper end of the gangjibo (3); After the consolidation earth plate (4) installation step, the step of installing a consolidation material (5) between the consolidation earth plate (4) and the upper end of the rigid beam (3); After the consolidation material (5) installation step, the step of performing cement-filled grouting (7) to the remaining pores (fine overhang) formed on the consolidated earth plate (4); After the cement filling grouting step (7), the step of installing a new steel beam (3) to fit the shape of the tunnel; In the compaction excavation method of the underground tunnel, which proceeds repeatedly by repeating the excavation step of pressing the method plate 2 into the hydraulic jack and advancing it after the installation step of the new rigid beam 3, wherein the consolidation material 5 is installed. After the step, the hydraulic cylinder (6) is provided between the consolidation material (5) installed in the upper end of the rigid beam (3) and the other upper rigid beam (3) arranged spaced apart, the hydraulic cylinder (6) After the step of installing the) and the hydraulic cylinder (6) to operate the consolidation material (5) is pushed (forces the force to raise) by performing the step of raising the consolidation earth plate (4), after which the consolidation earth plate (4) The present invention relates to a compaction excavation method for underground tunnels in which cement filling grouting (7) is applied to the remaining voids (fine overhangs) formed at an upper portion thereof.

Description

The method of consolidation for excavating tunnel and the lagging being in used in this method}

The present invention relates to a method of constructing an underground tunnel at a relatively shallow position from the ground surface, and more particularly, by inserting a consolidation earth plate into the space of the rear portion where a messer plate for excavating a tunnel is transferred to the upper base plate as a hydraulic cylinder. The present invention relates to a compaction excavation method of underground tunnels and a compacted earth plate used for injecting cement-filled grouting between the consolidated earth plate and the ground, thereby enabling the construction of safe and secure underground tunnels without fear of subsidence.

The general method of constructing underground tunnels is to set up arbitrary tunnel structure cross sections and to excavate the required cross sections of underground structures in the axial direction of the tunnel on the upper and side surfaces of the tunnel. And the meser plate manufactured by using steel pipe and steel plate was placed in parallel to fit the tunnel cross section on the pre-installed steel beam, and using the hydraulic jack to inject each mesmer plate into the ground, excavating the membrane face, The tunnel is secured by installing a earth plate behind the tunnel.

At this time, if the upper ground soil is relatively soft ground, the interaction between the upper soil particles cannot be expected, and the voltage is applied to the tunnel type upper surface according to the total weight of the upper soil soil. If the load is caused by the vehicles and there is a voltage, even if there is a structure such as a box directly on top of it, the sedimentation or collapse of the ground soil is generated at that part and serious damage to the superstructure causes damage to the construction work. It will also cause major problems in major city functions.

Therefore, the shield method and the messer method are known as a method of maintaining the safety of the structure with less concern about surface subsidence due to the above-mentioned voltage. Such a method has more stability and workability than a general tunnel construction method. Although it is improved in terms of surface, voids, or spaces, are generated between the surrounding disks in contact with the earth plate, which cannot completely prevent ground subsidence or collapse, and due to the voltage caused by the load of roads, railways, or direct structures, Occurs and becomes unstable.

In addition, underground tunnel construction method (NRM method, registration number 10-0239590) has been developed, but this is advantageous for preventing surface settlement, but the frictional force with the steel beam is very large when press-fitting the connecting drilling panel of the rear end. It is difficult and it is difficult to pressurize the upper ground continuously during the press-in advance, which makes the original ground unstable, and there is no way to reinforce when the sinking occurs at the top after excavation. There is a dead end.

An object of the present invention is to control the voltage applied by the large load from the top of the base to the upper wall and the side wall in constructing the underground tunnel, to maintain stability without worrying about the upper settlement, and to establish a reliable underground tunnel. Another object is to endure the voltage caused by the heavy load of road, railway, etc. or heavy loads of the structure, and to sink the surrounding ground by immediately adhering the space between the mesmer plate digging the tunnel and the ground surface in contact with it. It is to provide a consolidation excavation method of underground tunnels and consolidation earth plate used therein, which can maintain underground safety and build underground tunnels at low cost.

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

Assembling the rigid beam 3 to the tunnel shape to fit the tunnel shape, and then forming the oscillation base 1 by arranging the method plates 2 in parallel outside the rigid beam 3; After the step of making the oscillation base (1), the excavation step of advancing by pressing the method plate (2) with a hydraulic jack; After the excavation step, the step of installing a consolidation earth plate (4) between the exposed portion of the advanced method plate (2) and the upper end of the gangjibo (3); After the consolidation earth plate (4) installation step, the step of installing a consolidation material (5) between the consolidation earth plate (4) and the upper end of the rigid beam (3); After the consolidation material (5) installation step, the step of performing cement-filled grouting (7) to the remaining pores (fine overhang) formed on the consolidated earth plate (4); After the cement filling grouting step (7), the step of installing a new steel beam (3) to fit the shape of the tunnel; In the compaction excavation method of underground tunnels to proceed repeatedly; the excavation step of advancing the method plate (2) by pressing the hydraulic jack to advance after the installation step of the new rigid beam (3),

After the step of installing the consolidation material (5), the step of installing the hydraulic cylinder (6) between the consolidation material (5) installed on the upper end of the other rigid steel beam (3) spaced apart from the upper end of the rigid beam (3) After the step of installing the hydraulic cylinder (6) to operate the hydraulic cylinder (6) so that the consolidation material (5) is pushed (forcing the lifting force) to the consolidation earth plate 4 to be raised After the step, the cement-filled grouting (7) is characterized in that the remaining pores (fine overhang) formed on the consolidated earth plate (4).

In addition, the consolidation earth plate 4 used in the present invention is bent downward while integrally extending on both sides of the upper surface 41 and the upper surface 41 forming the filling grouting hole 8 penetrated to the center portion. The side surface 42 is formed, wherein the support surface 43 in which the consolidation material 5 is located at the lower end of the side 42 is integrally extended to be bent inward, and the ribs are formed on the side 42. 44 is formed to protrude inward while being connected to the upper surface 41 and the support surface 43. When the consolidation earth plate 4 configured as described above is installed so that the blocking plate 9 protrudes at any one of a pair of corners of the upper surface edges that are joined, that is, the consolidation earth plate 4 facing each other. do.

In general, the method of excavating a tunnel is to assemble the steel beams (3) in accordance with the formation of the tunnel to be excavated at the shaft entrance, and then to arrange the steel plate called the mesa plate (2) in parallel to the outside of the steel beams (3) to make a strong oscillation base (1) Establishment and tunnel excavation work is carried out by injecting the Messer Plate (2) into the membrane using hydraulic jacks one by one. The newly formed curtain surface is stabilized by using a crutch, then install a new gangjibo (3) in this one step of the excavation is completed, the process is repeated to tunnel excavation.

When pushing the mesa plate 2 in the above, the excavation surface between the steel beams 3 is exposed in the rear of the mesa plate 2 in accordance with the forward movement of the mesa plate 2, in the present invention is supported by the consolidation earth plate (4) In particular, by inserting the wedge wood consolidation material (5) in the bottom of the consolidation earth plate (4) as close as possible to the consolidation earth plate (4) to the excavation surface.

That is, in the present invention, a high-strength consolidation material 5 to harden the ground as much as possible in the space formed by the thickness difference between the mesmer plate 2 and the consolidation earth plate 4 at the rear part of the presser-advanced mesmer plate 2. By lifting the consolidation earth plate 4 with the hydraulic cylinder (6) to the upper by using the reaction force of the rigid beam (3) to eliminate the space portion to prevent settlement. The above process is illustrated in FIGS. 2 to 4.

The conventional method of lifting the consolidation earth plate 4 upward using the consolidation material 5 tapping the consolidation material 5 like a wedge with a hammer to lift the consolidation earth plate 4. However, the above method results in an impact on the ground to promote collapse or to generate cracks in the ground, thereby increasing the possibility of ground collapse by rainwater. Therefore, in the present invention, this problem is solved by the hydraulic cylinder (6), the action of the hydraulic pressure can be applied to the gradual and large force to consolidate the consolidation earth plate 4 to the upper base without impact.

In this way, the excavation is sequentially carried out by pressing forward, and the steel beams 3 are installed at predetermined intervals in the tunnel space formed at the bottom thereof to excavate the tunnel having a desired length, and the space formed between the consolidation earth plate 4 and the steel beams 3. Cement-filled grouting should be performed immediately after excavation so that this is buried. In the present invention, the space between the base plate and the consolidation earth plate 4 is filled through the filling grouting hole 8 drilled in the consolidation earth plate 4.

For the cement-filled grouting as described above, in the present invention, a unique consolidation earth plate 4 is used, the structure of which is shown in FIG.

As shown in (b) of FIG. 7, the consolidation earth plate 4 has a filling grouting hole 8 penetrating up and down, and a blocking plate protrudes from the two upper edges. At the time of tunnel excavation of the consolidation earth plate 4 having the structure as described above, a plurality is installed in contact with each other as shown in Fig. 7 (a), wherein the blocking plate 9 is adjacent consolidation earth plate (4) By installing the blocking plate (9) of the non-attached portion to block the space between the consolidation earth plate (4).

Therefore, the soil and water are prevented from flowing down between the consolidation earth plate 4, and in particular, during the cement filling grouting process, the cement grout flows into the space between the consolidation earth plate 4 together with the water to halve the effect of the filling grouting or This will prevent future ground subsidence.

After the cement-filled grouting is constructed, the formwork 10 is installed at a lower portion of the consolidation earth plate 4 and the lining concrete is poured into the space therebetween to complete the tunnel construction.

Thus, in the present invention, the consolidation earth plate (4) is installed at the rear end of the Messer plate (2) and immediately consolidates the high-strength consolidation material (5) with the hydraulic cylinder (6) immediately consolidation to the upper portion before the initial displacement of the base. Since the earth plate 4 is lifted up, the upper ground layer surface and the consolidated earth plate 4 are in a state of being stuck, so unlike the conventional method, no space portion is generated and no ground subsidence occurs, and the consolidated earth plate 4 is press-fitted. Immediately after the grouting is injected through the filling grouting hole 8 of the consolidation earth plate 4, the ground is solidified, and the tunneling work can be stably performed by pouring the lining concrete 11 at the same time as the excavation work.

As described above, the present invention lifts the consolidation earth plate 4 with the hydraulic cylinder 6 to the upper portion so as not to form a space portion at the rear of the mesmer plate 2 so as to excavate in a state of being completely in contact with the base layer. It is possible to build a stable underground tunnel, and in particular, by controlling the voltage due to a large load from the top there is an effect that can build a stable and robust underground tunnel.

1 is an overall schematic view of the present invention

FIG. 2 is a partial detail view of FIG. 1

Figure 3 is a state diagram after the advance of the messer plate

Figure 4 is a state of consolidating the consolidated earth plate to the base plate as a hydraulic cylinder

5 is a cement filled grouting state diagram

6 is a state in which lining concrete is poured

7 is a perspective view of the consolidation earth plate used in the method of the present invention

※ Explanation of codes for main parts of drawing

1: oscillation base 2: Messer plate 3: Gangjibo

4: consolidation earth plate 5: consolidation material 6: hydraulic cylinder

7: cement filled grouting 8: filling grouting hole 9: blocking plate

DESCRIPTION OF SYMBOLS 10 Formwork 11: Lining concrete 41: Upper surface 42: Side 43: Support surface 44: Rib

Claims (4)

delete delete Assembling the rigid beam 3 to the tunnel shape to fit the tunnel shape, and then forming the oscillation base 1 by arranging the method plates 2 in parallel outside the rigid beam 3; After the step of making the oscillation base (1), the excavation step of advancing by pressing the method plate (2) with a hydraulic jack; Since the excavation step, between the upper portion 41 and the upper surface 41 having the filling grouting hole 8 formed between the exposed portion of the rear of the advanced method plate 2 and the upper end of the stiffening beam 3 Installing a consolidation earth plate (4) comprising a side (42) and a support surface (43) which are bent inwardly and integrally extended to the rib (44) formed on the side (42); After the consolidation earth plate (4) installation step, the step of installing a consolidation material (5) between the consolidation earth plate (4) and the upper end of the rigid beam (3); After the consolidation material (5) installation step, the step of performing cement filling grouting (7) to the remaining pores formed on the consolidation earth plate (4); After the cement filling grouting step (7), the step of installing a new steel beam (3) to fit the shape of the tunnel; In the compaction excavation method of underground tunnels to proceed repeatedly; the excavation step of advancing the method plate (2) by pressing the hydraulic jack to advance after the installation step of the new rigid beam (3), Between the step of installing the consolidation material (5) and the step of performing cement filling grouting (7) to the remaining void portion formed on the consolidation earth plate (4), Installing a hydraulic cylinder (6) between the consolidation material (5) installed at the upper end of the other rigid steel beam (3) spaced apart from the upper end of the rigid steel beam (3); After the step of installing the hydraulic cylinder (6) by operating the hydraulic cylinder (6) so that the consolidation material (5) is pushed to increase the consolidation earth plate (4); Consolidation excavation method. delete