KR20050031861A - Method of constructing a tunnel - Google Patents

Abstract

The present invention relates to a tunnel construction method for constructing an approach portion from the ground which leads to a tunnel, comprising: an oscillation portion construction step of constructing an oscillation portion for oscillating a shield oscillator; and the shield oscillator configured to open and close the ceiling of the shield oscillator. Excavate at an angle from the top of the shield excavator, excavate from the ground above, install a segment having a rectangular cross section and open at the top through a ceiling opening of the shield excavator, and cross section at a predetermined depth or more. This shield is constructed while opening the ceiling of the shield excavator, by constructing an approach part initial construction step of installing a rectangular segment and closing the opening part and extending from the approach part constructed in the approach part initial construction step, and opening the ceiling of the shield excavator. Seg installed excavator at the bottom The upper part of the upper part up to a predetermined depth is excavated along the cement, and the upper part of the upper part or more including the approach part is constructed by extruding the shielded excavator which closes the opening part.

Description

Method of constructing a tunnel}

The present invention relates to a tunnel construction method for constructing an approach portion from the ground through the tunnel.

In the case of constructing a tunnel underground, an opening method is carried out in which a retaining wall is formed along both sides of the tunnel along the tunnel axis, the inside of the tunnel is excavated to build a tunnel enclosure, and then filled up again to remove the retaining wall.

On the other hand, in the case of constructing an underground three-dimensional cross tunnel under a road or a railway, construction by a shield method or a propulsion method is common in order to avoid obstacles in the ground traffic according to the above-described opening method.

Shield excavators are classified into sealed shield excavators and open shield excavators. The hermetic shield excavator assembles a segment at its tail, excavates with a cutter disk, and builds a tunnel while using a shield jack to advance reaction force from the existing segment. On the other hand, the open shield excavator is a shield excavator used when constructing a tunnel with a shallow soil cover, and removes soil in front by using a back hoe, and installs a segment on the tail by a crane. And, to gain a reaction force in the segment to move forward to build a tunnel. Japanese Laid-Open Patent Publication No. 2002-70481 discloses an invention relating to an open shield excavator and an open shield construction method using the shield excavator.

By the way, in the conventional tunnel construction, the method which oscillates a shield excavator from the vertical shaft which dug to the predetermined depth, and builds the approach part which goes from the underground core part to the ground is implemented.

The conventional tunnel construction method has the following problems.

First, when constructing a tunnel using a shield excavator, it is necessary to build a vertical shaft to a predetermined depth. In this case, the construction cost and air required for the vertical shaft construction affect the construction cost and air of the whole construction.

Second, in the case of building vertical shafts from the ground, there may be a need to secure construction yards on the ground. If the vertical gang construction site interferes with the traffic route, it may cause traffic trouble.

In order to solve the above problems, the tunnel construction method of the present invention is a tunnel construction method for constructing an approach portion from the ground through the tunnel, oscillation part construction step of constructing an oscillation part for oscillating the shield excavator, the shield of the excavator The shield excavator configured to open and close the ceiling is inclined from the oscillating part so that the ceiling of the shield excavator is excavated above the ground, and the segment is open in a rectangular section at an upper end up to a predetermined depth, and the ceiling of the shield excavator is opened. An approach part initial construction step of installing through the opening part and installing a segment having a rectangular cross section at a predetermined depth or more, and a lower part of the approach part extending from the approach part constructed in the initial part construction step of the approach part by closing the opening part; The ceiling of the shield excavator While the shield excavator is excavated along the segment installed at the lower end, the upper end is built up to a predetermined depth, and the upper part of the upper part of the predetermined depth or more includes a subsequent construction step of constructing the extruding the shield excavator which closed the opening. Tunnel construction method characterized in that.

Further, the tunnel construction method of the present invention is a tunnel construction method for constructing an approach portion from the ground leading to a tunnel, comprising: an oscillation portion construction step of constructing an oscillation portion for oscillating a shield excavator, and a ceiling configured to open and close the ceiling of the shield excavator. Excavate the shield excavator inclined from the oscillation unit, and excavate from the ground above the shield excavator, install a segment through the ceiling opening of the shield excavator, having a rectangular cross section up to a predetermined depth, and opening the upper portion. Above the depth, the approach part initial construction step of installing a segment having a rectangular cross section, and the lower end of the approach part extending from the approach part constructed in the approach part initial construction step by closing the opening part are constructed, and the ceiling of the shield excavator is constructed. Open the shield excavator while By drilling along the upper segment is provided at the bottom of the tunnel construction method comprising the approach portion subsequent building step for building the top.

Further, in the above-described tunnel construction method, a tunnel construction method may be used in which a subsequent shield construction step is performed using a separate shield excavator in parallel with the approach construction step initial construction step.

Further, in the above tunnel construction method, the ceiling plate of the shield excavator is detachably provided, and when the excavation to the predetermined depth of the initial construction step of the approach part is provided, the barrier plate is provided. The tunnel construction method may be used to install the retaining plate at the time of constructing the upper end of the subsequent construction process of the approach part.

Further, a tunnel construction method can be used, in which a plurality of approach portions arranged substantially parallel to the above-mentioned tunnel construction method are arranged, and a large cross-sectional approach portion is constructed by excavating the gap. .

Further, in the above tunnel construction method, after installing the segment having a rectangular cross section and having an open top, a support beam is provided on each of the recess portions provided at the upper ends of the left and right side walls constituting the segment, and in the extending direction of the approach portion. A tunnel construction method can be used, in which the segment having a rectangular cross section is provided above the predetermined depth while installing the porous plate on the support beam in substantially parallel.

Hereinafter, a tunnel construction method according to the present invention will be described in detail with reference to the accompanying drawings.

① Overall composition

The present invention relates to a method of constructing the approach part 6 connected to the tunnel 5 underground from the ground, especially during the construction of the tunnel 5 by the shield excavator 1.

As the shield excavator 1 to be used, it is preferable to use the sealed shield excavator 1 for rectangular cross-section cutting (refer FIG. 1). It is also possible to use the hermetic shield excavator 1 and the open shield excavator together.

The sealed shield excavator 1 is preferably provided with an opening / closing mechanism 13 that can open or close part or all of its ceiling. In the construction of the approach part 6, in the case of drilling a relatively shallow depth (a range shallower than the height of the shield excavator 1) in the vicinity of the ground surface, the opening part 11 generated by opening the opening / closing mechanism 13 provided in the ceiling. Is installed while hanging the segment 4 from the ground using, for example, a heavy machine 3 such as a crane.

The ceiling of the shield excavator 1 can be equipped with the retaining plate 12 (refer FIG. 2). That is, the two retaining boards 12 and 12 are erected so as to be substantially parallel to each other at about the width of the shield excavator 1, and are disposed on the ceiling of the shield excavator 1, and a plurality of gap support members are provided at the intervals. (121, 121) is installed by connecting to each of the retaining plate (12, 12) vertically.

By placing the retaining plate 12 on the ceiling of the shield excavator 1, even if the excavation depth is greater than or equal to the height of the shield excavator 1, the segment 4 is removed from the ground via the opening 11 to a certain depth. Suspension installation becomes possible.

The depth of the sealed shield excavator 1 is greater than the height of the shield excavator 1 (in the case where the shield plate 12 is placed on the ceiling of the shield excavator 1, the height of the shield plate 12 is added. ), The opening / closing mechanism 13 is closed, and after that, the segment 4 can be installed from the inside of the shield excavator 1 in a conventional manner. Here, it is preferable to divide the approach part 6 into the lower part 62 and the upper part 63, and to implement.

Hereinafter, the tunnel construction method of the present invention will be described in detail.

② Construction part of oscillation part (Fig. 3)

The oscillation part 2 is an excavation part which penetrated shallowly with the inclination of the approach part 6 from the surface or the surface. A reaction force wall 91 for oscillating the shield excavator 1 is provided at the surface or the excavated end. Here, the reaction wall 91 may be constructed by assembling a steel material or may be a concrete wall.

Even when the oscillation part 2 is dug in shallow, a wide range of construction yards are not required as compared with the case of constructing a normal vertical shaft.

③ Initial construction process of approach part (FIG. 4)

The shield excavator 1 oscillated obliquely downward from the oscillation unit 2 is excavated to a depth about the height thereof. In the shield excavator 1 which is provided with the opening / closing mechanism 13 which can be opened and closed on a ceiling, since the segment 4 is suspended from the ground with the heavy machinery 3, such as a crane, through the opening part 11, it installs. The depth (predetermined depth) is about the height of the shield excavator 1. Here, in the case of installing the retaining plates 12 and 12 on the ceiling of the shield excavator 1, the height of the shielding excavator 1 plus the height of the retaining plate 12 is set to a predetermined depth. Can be. In this case, it is good to excavate the ground below the fabric of the shield excavator 1 using the shield excavator 1, and the ground above the fabric of the cloth using the heavy machinery 3 such as a backhoe from the ground.

The approach portion 61 is provided with a U-shaped segment 41 having a rectangular cross section from the oscillation portion 6 to a predetermined extension (see Fig. 5), and the depth of the segment 42 having a rectangular cross section. Install (see Figure 6).

After the above-described U-shaped segment 41 is provided, it is preferable to provide a perforated plate 82 for the purpose of temporarily opening to ground transportation, securing ground construction yards, or the like. That is, the support beams 81, such as H-shaped steel, are attached to the groove portions 411 and 411 respectively provided on the upper ends of the left and right side walls constituting the U-shaped segment 41, and in the extending direction of the approach portion 61. The porous plate 82 is provided on the some support beams 81 and 81 which were substantially parallel (refer FIG. 10).

④ Follow-up construction process of approach part

After the approach part 61 is built up to a predetermined depth by the approach part initial construction process, the approach part 6 further extending from the approach part 61 is separated into two stages of the lower end 62 and the upper end 63. Do construction. Here, a segment 42 having a rectangular cross section is provided while the shield excavator 1 is extended by a predetermined extension while the opening / closing mechanism 13 of the shield excavator 1 is closed (see FIG. 7). Thereafter, using the shield excavator 1 having the lower end 62 formed thereon, the upper end 63 is formed while the shield excavator 1 is driven along the segment 42 forming the lower end 62. Segment 42 is installed on the lower end (see FIGS. 8 and 9).

Although not shown, a protrusion extending in the extending direction of the approach portion 6 is provided in advance on the ceiling of the segment 42 provided at the lower end 62, and the shield is excavated prior to the construction of the upper end 63. The lower surface of the machine 1 may be configured to include a groove that fits into the protrusion (the shield excavator 1 having such a configuration may be produced from the beginning). In this case, the segment 42 of the lower end 62 can guide the shield excavator 1 at the time of constructing the upper end 63, and furthermore, the construction precision can be improved.

In the construction of the upper end 63, as far as the depth (predetermined depth) of the height of the shield excavator (1), as in the initial construction process of the approach part, the drilling of the shield excavator (1) with the opening / closing mechanism (13) opened is performed. good. When installing the retaining plates 12 and 12 on the ceiling of the shield excavator 1, the height of the shielding excavator 1 plus the height of the retaining plate 12 can be set to a predetermined depth. . In this case, the ground below the fabric information of the shield excavator 1 can be excavated using the shield excavator 1, and the ground above the fabric information can be excavated from the ground using heavy machinery 3 such as a backhoe.

When constructing the upper end 63 of the predetermined depth or more, the segment 42 is provided while closing the opening 11 and driving the shield excavator 1.

On the other hand, when building the upper end 63, it is also possible to excavate the excavator 1 in the state which opened the opening part 11 (without closing it). For example, when the soil cover is relatively shallow, such as 1.5m at the intersection portion, the approach portion 6 of this section is because there is no need to close the opening (11).

As for the extension of the construction, after constructing the lower end 62 at once to the general portion (approximately horizontally extending section) of the tunnel 5, the shield excavator 1 which constructed the lower end 62 is connected to the upper end 63. Can be used for construction, after the lower end 62 to some extent of the construction of the construction, the shield 63 may also be constructed by the upper end 63 with a separate shield excavator (1). In this case, at least two shield excavators 1 are required, but lead to air shortening.

After the installation of the segments 42 of the lower end 62 and the upper end 63 is completed, the upper bottom plate constituting the lower end 62 and the lower bottom constituting the upper end 63 are removed. 63) The approach part 6 may be completed by combining the side wall of the segment 42 and the side wall of the lower part 62 segment 42.

EXAMPLE

This embodiment relates to a method for constructing a large cross-section approach portion 7 leading to a large cross-section tunnel according to the above-described tunnel construction method.

The approach part 6 of a row is constructed through an oscillation part construction process, an initial construction process of an approach part, and a follow-up construction process of an approach part. Here, two shield excavators 1 may be used, and the subsequent construction of the approach portion may be performed in parallel with the initial construction of the approach portion.

Next, using the shield excavator 1 which built the existing approach part 6, the approach part 6 which parallels the existing approach part 6 with the predetermined | prescribed space | interval 100 in the existing approach part 6 is carried out. ) (See FIG. 11). Depending on the size of the large cross-section approach portion 7 to be formed and the excavation cross section of the shield excavator 1 to be used, it is also necessary to construct three or more rows of the approach portions 6 in parallel.

Here, two or more shield excavators 1 can be used, and several approach parts 6 and 6 can also be constructed in parallel.

Next, the gap 100 is excavated, for example, by bucket excavation from the ground (see FIG. 12). When digging, the side walls of each of the approach portions 6 and 6 of the gap 100 play a role of a retaining wall, and thus excavation of the ground is possible without the collapse of the soil.

After the excavation of the space | interval 100 is completed over the extension direction of the approach part 6, or after the excavation of the space | interval 100 is completed, the side wall, the ceiling, and the floor which comprise the approach parts 6 and 6 are sequentially performed. Among the plates and the like, the large cross-section approach portion 7 of the present invention is constructed while dismantling and removing members other than the structural members of the present structure.

As mentioned above, although this invention was demonstrated by the limited embodiment and drawing, this invention is not limited by this and is within the equal range of a common technical idea in the technical field to which this invention belongs, and a claim to be described below. Of course, various modifications and variations are possible.

The tunnel construction method of the present invention can achieve at least one of the following effects.

First, when constructing a tunnel, it is not necessary to construct a vertical shaft that has been dug to a predetermined depth, so that construction cost can be reduced and air can be shortened.

Second, there is no need to build a deep vertical shaft, so there is no need to secure extensive construction yards. In addition, even when the construction site of the vertical shaft interferes with the traffic line, the traffic obstacle can be minimized.

Third, since a large cross section can be secured by constructing a plurality of approach portions using the tunnel construction method of the present invention, a large cross section tunnel can be constructed without having to construct a large vertical shaft.

1 is a longitudinal cross-sectional view showing shield excavators having different diameters used in the present invention.

Figure 2 is a longitudinal cross-sectional view showing a shield excavator of a different diameter cross section with a retaining plate.

3 is a longitudinal cross-sectional view illustrating the oscillation part construction process.

4 is a longitudinal cross-sectional view illustrating the initial construction process of the approach part.

5 is a view along the line A-A of FIG.

FIG. 6 is a view along line B-B in FIG. 4; FIG.

Figure 7 is a longitudinal cross-sectional view illustrating the construction of the bottom of the subsequent construction of the approach portion.

8 is a longitudinal cross-sectional view illustrating the construction of the upper stage in the subsequent construction process of the approach part;

Figure 9 is a longitudinal cross-sectional view illustrating the construction of the upper part in the subsequent construction process of the approach portion.

10 is a perspective view illustrating a situation in which a support beam and a perforated plate are installed in a segment having a rectangular cross section and having an open top portion;

11 is a cross-sectional view illustrating a method of constructing a large cross-sectional approach portion.

12 is a cross-sectional view illustrating a method of constructing a large cross-sectional approach portion.

<Short description of the main reference symbols>

1..Shield Excavator 11..Open Section 12.Stainplate

2 .. Oscillator 3 .. Medium 4. Segment

411. Groove 5. Tunnel 6. Approach

62. Bottom 63. Top 7. Large section approach

81 .. 82 .. Reinforcement plate 100 .. Spacing

Claims (6)

As a tunnel construction method for establishing an approach portion from the ground through the tunnel, An oscillator construction step of constructing an oscillator for oscillating the shield excavator; The shield excavator configured to open and close the ceiling of the shield excavator is inclined from the oscillator to be inclined, and the upper portion of the shield excavator is excavated from the ground, and a segment having a rectangular cross section and an open upper portion to a predetermined depth. An initial construction step of installing the approach portion through the ceiling opening of the shield excavator, and installing a segment having a rectangular cross section at a predetermined depth or more; And By closing the opening part to build a lower end of the approach part extending from the approach part constructed in the initial part of the approach part, while opening the ceiling of the shield excavator, the shield excavator is excavated along the segment installed at the lower end, And a follow-up step of constructing the upper end to a predetermined depth, and the upper end of the predetermined depth or more to approach and construct the shield excavator which closed the opening. As a tunnel construction method for establishing an approach portion from the ground through the tunnel, An oscillator construction step of constructing an oscillator for oscillating the shield excavator; The shield excavator configured to open and close the ceiling of the shield excavator is inclined from the oscillator to be inclined, and the upper portion of the shield excavator is excavated from the ground, and a segment having a rectangular cross section and an open upper portion to a predetermined depth. An initial construction step of installing the approach portion through the ceiling opening of the shield excavator, and installing a segment having a rectangular cross section at a predetermined depth or more; And The lower end of the approach part extending from the approach part constructed in the initial part of the approach of the approach part was constructed by closing the opening part, and the shield excavator was excavated along the segment provided at the lower end while opening the ceiling of the shield excavator. Follow-up construction step of the approach to build the tunnel construction method comprising a. The method according to claim 1 or 2, And a step of constructing the approach part after the approach part using a separate shield excavator in parallel with the initial part of the approach part. The method according to any one of claims 1 to 3, And a detachable plate provided on the ceiling of the shield excavator, At the time of excavation to the predetermined depth of the approach portion initial construction step, install the retaining plate, Tunnel construction method characterized in that to install the retaining plate at the time of building the upper end of the subsequent construction step of the approach portion According to the tunnel construction method of any one of Claims 1-4, The several approach part arrange | positioned substantially parallel and spaced apart is constructed, A tunnel construction method, wherein the gap is excavated to build a large cross-section approach. In the tunnel construction method according to any one of claims 1 to 5, After installing the segment having a rectangular cross section and having an open upper portion, the support beam is placed on the groove portions respectively provided at the upper end of the left and right side walls constituting the segment, and the support plate is disposed on the support beam in substantially parallel direction in the extending direction of the approach portion. And installing the segment having a rectangular cross section at or above the predetermined depth.