JP2018155020A - Invert pier and tunnel invert construction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an invert pier and a tunnel invert construction method with high construction efficiency.SOLUTION: An invert pier 1 includes a work platform 10 having a casting space S1 for casting invert concrete downward, a front oblique path 20 stretched between the front end of the work platform 10 and the ground, a rear oblique path 30 stretched between the rear end of the work platform 10 and the ground, and a plurality of support legs 40 attached to the lower portion of the work platform 10 to support the work platform 10 away from the ground. The width of the front oblique path 20 is less than half the width of the work platform 10 and the front oblique path 20 can be connected to an arbitrary position in the width direction of the work platform 10.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an invert pier and a tunnel invert construction method, and more particularly to an invert pier and a tunnel invert construction method capable of performing invert excavation and invert concrete placement in parallel.

Construction of invert (tunnel floor) in tunnel construction has an effect on the entire construction period because construction vehicles related to unloading at the face, support work for the face, and spray work cannot pass through the construction section of the invert work. large.
For this reason, in order to pass the construction vehicle across the construction section of the invert work, an invert pier that is equipped with a gantry and a ramp for raising and lowering and is movable in the width direction of the tunnel is adopted.
At the position where this pier is close to the first side of the mine, the second side excavates the ground of the pier over the entire length of the pier, then moves the pier to the second side of the mine, the first side The pier is excavated over the entire length of the pier, and finally the pier is moved to the center of the mine and inverted concrete is placed on the ground excavated from the pier. When the cast invert concrete is hardened, the invert pier is advanced by one span.
Construction is progressed by repeating this as one cycle.

JP-A-6-108795 JP 2003-322000 A

However, the prior art has the following drawbacks.
<1> Until invert excavation for all spans is completed, construction of invert concrete cannot be started, so there are many waiting times and construction efficiency is low.
<2> The width of the gantry is narrow due to the structure that moves the entire pier in the width direction of the mine. Therefore, when placing concrete, the construction vehicle cannot pass through the side of the concrete mixer truck, so the construction of the face is interrupted.
<3> Since the construction speed of invert is lower than the construction speed of the working face, there is a risk of delaying the entire construction period.

  An object of the present invention is to provide an invert pier and a tunnel invert construction method that can solve the problems of the prior art.

  An invert pier of the present invention for solving the above-described problems includes a work platform having a placement space for invert concrete placement work below, and a front ramp that spans between the front end of the work platform and the ground. And a rear ramp extending between the rear end of the work platform and the ground, and a plurality of support legs attached to the lower portion of the work platform and supporting the work platform apart from the ground, the width of the front ramp is It is less than half the width of the work platform, and the front ramp is connectable to an arbitrary position in the width direction of the work platform.

  In the invert pier of the present invention, the front ramp may be slidable along the width direction of the work platform.

  The invert pier of the present invention has a front support leg with a plurality of support legs attached to the front of the work platform and a rear support leg attached to the rear of the work platform, and the placement space has a front support. It may be formed between the leg and the rear support leg.

  The tunnel invert construction method of the present invention is such that in the state where the tip of the front ramp on the Invert pier is placed on the ground before construction and the tip of the rear ramp on the ground after construction, 1) From the work platform A process of excavating the ground on the face side in advance, 2) a process of placing invert concrete on the ground below the work base from the upper part of the work base, and 3) advancing the invert pier to the face side, 1) A step of positioning above the excavation section after the execution of the process is provided, and after the 1) process and the 2) process are performed in parallel, the 3) process is performed and this is defined as one construction cycle. 1a) a step of excavating the ground on the second side of the front ramp with the front ramp located on the first side in the tunnel crossing direction, and 1b) the second ramp of the front ramp in the direction crossing the tunnel. Of the front ramp with the And a step one side drilling a ground of I, by moving the front ramp to left and right tunnel transverse, 1a) and a step and 1b) step, and carrying out interchanged as appropriate.

The Invert Pier of the present invention has at least one of the following effects.
<1> Since the front ramp can be moved to the left and right with respect to the work platform, a preceding excavation in front of the work platform is possible. For this reason, since invert excavation and invert concrete placement can be performed simultaneously, construction efficiency is remarkably high.
<2> Since the work platform is wide, the construction vehicle can pass through the side of the concrete mixer truck during the placing work. For this reason, it is possible to continuously perform tunnel inversion without interrupting the work of the face.

The tunnel invert construction method of the present invention has at least one of the following effects.
<1> The construction section is divided into two parts in the front and the rear, and invert excavation and invert concrete placement are performed in parallel, so that the construction time can be reduced and the construction efficiency can be remarkably increased.
<2> The rough road section between the face and the invert is shortened by increasing the construction efficiency of the invert work. For this reason, the runnability of the construction vehicle related to the construction of the face increases, and the workability and safety of the entire construction are improved.

Explanatory drawing of the invert pier and tunnel invert construction method concerning this invention. Explanatory drawing of the tunnel invert construction method which concerns on this invention. Explanatory drawing of the tunnel invert construction method which concerns on this invention.

Hereinafter, the invert pier and tunnel invert construction method of the present invention will be described in detail with reference to the drawings.
In this specification, etc., “front” and “rear” are the face side and pit side in the tunnel extension direction, respectively, and “up”, “down”, “left”, and “right” are the states where the invert pier faces the face side. Each direction in is meant.

[Invert Pier]
<1> Overall configuration (FIG. 1).
The invert pier 1 of the present invention is a device used for invert construction in tunnel construction.
The invert pier 1 is attached to the work platform 10, the front ramps 20 and the rear ramps 30 that extend from the front and the back of the work platform 10 to the ground, and the lower part of the work platform 10, and supports the work platform 10 at a position higher than the ground. And a plurality of support legs 40. The front ramp 20 is connected to the work platform 10 so as to be movable in the width direction.
The entire length of the invert pier 1, that is, the horizontal projection length from the front end of the front ramp 20 to the rear end of the rear ramp 30 is configured to be longer than one span of the construction section of the invert work.
A placement space S1 for invert concrete placement work is formed between the lower part of the work platform 10, the ground, and the plurality of support legs 40.
An excavation space S2 for invert excavation work is formed between the side of the front ramp 20 and the side wall of the tunnel. The excavation space S2 is switched left and right in accordance with the left and right switching of the front ramp 20.
By installing the invert pier 1 across the construction section of the invert work, it is possible to construct the invert work at the lower part while securing the travel route of the construction vehicle at the upper part.

<2> Work platform.
The work platform 10 is a member that has both a function of a work table for placing invert concrete and a function of a traffic path of the construction vehicle.
In this example, a rectangular structure in which a face material is laid on a frame made of steel girders is employed as the work platform 10. Side walls for fall prevention are provided on both sides of the upper surface of the work platform 10.
The width of the work platform 10 is set to be smaller than the cross-sectional width of the tunnel and sufficient for passage of the construction vehicle.
The width sufficient for the passage of construction vehicles means that when invert concrete is placed, a concrete mixer truck throws ready-mixed concrete from the top of the work platform 10 into the ground. The width is such that it can pass through the side of the mixer truck. In other words, it is desirable to secure at least two lanes in the construction vehicle.
Thereby, the invert work can be performed without stopping the work of the face.
In this example, a suspension arm 11 for lifting the rear end of the rear ramp 30 upward is provided at the rear of the work platform 10.
In addition to this, the floor plate of the work platform 10 may be provided with a material input port for suspending the material in the lower part or for supplying ready-mixed concrete. The material input port can be configured to be opened and closed by a hydraulic mechanism.

<3> Front ramp.
The front ramp 20 is a hoistway for a construction vehicle that spans between the front end of the work platform 10 and the ground.
In this example, a steel face material is adopted as the front ramp 20.
The front ramp 20 is connected to the work platform 10 so as to be connectable to an arbitrary position in the width direction of the work platform 10.
In this example, the front ramp 20 is configured such that a reaction force is obtained from the front support leg 40 and the tip can be lifted from the ground by a hydraulic jack (not shown). This avoids the tip of the front ramp 20 coming into contact with the ground when the invert pier 1 is moved.

<3.1> Front ramp moving function.
The front ramp 20 is connected to the work platform 10 so as to be connectable to an arbitrary position in the width direction of the work platform 10.
In this example, the front ramp 20 is a slide mechanism that is slidable in the width direction by a combination of a rail provided at the front of the work platform 10 and a pulley provided at the front ramp 20. .
In this case, a slide carriage for assisting the sliding movement of the front ramp 20 may be attached to the tip of the front ramp 20.
However, the structure of the front ramp 20 is not limited to this. For example, the front ramp 20 may be configured to be detachable from the work platform 10, and the front ramp 20 may be detached from the work platform 10 and changed to the left and right according to the process. In short, it is only necessary that the position of the front ramp 20 with respect to the work platform 10 can be changed according to the process.

<3.2> The width of the front ramp.
The width of the front ramp 20 is not more than half the width of the work platform 10. Preferably, it is half the width of the work platform 10.
As a result, when the front ramp 20 is slid to the left and right ends, there is no area where the front ramp 20 overlaps in plan view, so that the entire width of the excavation section can be excavated.

<4> Rear ramp.
The rear ramp 30 is a hoistway for a construction vehicle that spans between the rear end of the work platform 10 and the ground.
In this example, a steel face material is adopted as the rear ramp 30. It is desirable that the width of the rear ramp 30 corresponds to the width of the work platform 10.
In this example, the front end of the rear ramp 30 is hinged to the rear end of the work platform 10, and the rear end of the rear ramp 30 can be lifted upward by the suspension arm 11 of the work platform 10.
The rear ramp 30 is lifted upward by the suspension arm 11 to avoid the rear end of the rear ramp 30 coming into contact with the ground when the invert pier 1 is moved.

<5> Support leg.
The support leg 40 is a member that supports the work platform 10 from below and separates it from the ground.
In this example, a total of four support legs 40 are provided, one at each of the lower four corners of the work platform 10.
A support carriage 41 is provided at the lower end of each support leg 40.
Each support leg 40 is provided with a lifting device 42 such as a hydraulic jack so that it can be lifted and lowered.
Note that the support carriage 41 and the lifting device 42 are not essential components of the support leg 40, and various known support structures can be employed. In short, it is sufficient that the work platform 10 is supported away from the ground and the invert pier 1 can be advanced in the face direction.

<6> Placed space.
The placement space S <b> 1 is a space for performing various processes such as installation of formwork, bar arrangement, loading of ready-mixed concrete, curing, and the like in the invert concrete placing process.
In this example, the placement space S <b> 1 is formed below the work platform 10 and between the four support legs 40. As a result, it is possible to secure a wide span placement space S1 in the front and rear, and thus the workability of each process related to concrete placement is enhanced.

[Tunnel invert construction method]
Subsequently, the tunnel invert construction method of the present invention will be described in detail with reference to the drawings. 1-3 is explanatory drawing which represented each process typically.

<1> State before construction.
The invert pier 1 spans the front ramp 20 on the ground before construction and the rear slope 30 on the ground after construction, and the front ramp 20 on the first side in the crossing direction of the tunnel. Position.

<2> Advance excavation on the second side (FIG. 1).
The ground on the face side from the work platform 10 is excavated in advance.
The excavation space S2 on the second side of the front ramp 20 from the center in the tunnel width direction is excavated to a predetermined depth.

<3> First excavation on the first side (FIG. 2).
After excavating the excavation space S2 on the second side, the front ramp 20 is slid to the second side.
Subsequently, the excavation space S2 on the first side of the front ramp 20 is excavated to a predetermined depth.

<4> Invert concrete placement (FIG. 2).
Reinforcement and formwork are installed on the ground below the work platform 10 that has been excavated in the previous cycle, and the ready-mixed concrete is put into the lower ground from the concrete mixer truck disposed on the work platform 10.
At this time, it is possible to take a reaction force to prevent the formwork from lifting from the bottom surface of the work platform 10.
Subsequently, the concrete is hardened, demolded and cured.
For convenience of explanation, the preceding excavation has been described before the invert concrete placement, but in fact, the prior excavation and the invert concrete placement are performed simultaneously with the construction section being shifted back and forth.
If necessary, backfill invert concrete.

<5> Advance of Invert Pier (Fig. 3).
The tip of the front ramp 20 is pushed up with a hydraulic jack and lifted above the ground.
The rear end of the rear ramp 30 is lifted by the suspension arm 11 above the ground.
Pull the Invert Pier 1 with a construction vehicle such as a backhoe and advance it to the face side by one span. Here, one span is substantially the same distance as the excavation distance by the preceding excavation.
Thereby, the work platform 10 is positioned above the excavation section by the preceding excavation.
In addition, the advance method of the invert pier 1 is not limited to towing, but is a method of self-propelling with a hydraulic motor, or the support leg 40 is shortened with a hydraulic jack and then extended to the face side, and then extended with the front and rear support legs 40. You may employ | adopt the method of moving forward by repeating this. Since these are known techniques, they will not be described in detail here.
Regardless of whether it is self-propelled or towed, it suffices if it can move forward along the direction of tunnel extension.

<6> Repeat each step.
The process from <2> to <5> is set as one cycle, and the invert work is advanced by moving the invert pier 1 to the face side while repeating this.
It should be noted that the first side and the second side in the <2><3> steps are appropriately exchanged for convenience of construction.
In the tunnel invert construction method of the present invention, the construction section of the invert work is divided into the excavation section and the placement section, and the invert concrete placement and the invert excavation can be performed in parallel. Therefore, the construction efficiency of invert work is remarkably high.

<7> Comparison of construction efficiency.
Below, the comparison table of the construction efficiency of the tunnel invert of this invention and the construction efficiency of a prior art is shown.

本発明のトンネルインバートの施工方法は、従来技術の１スパンを前後２サイクルに分割して施工し、２サイクル目の掘削を１サイクル目のインバート打設と同時に行うことによって、施工時間を圧縮することができる。本例では、従来技術に対して作業時間が３５単位から２８単位へ２０％削減されている。
施工長が１スパン１０．５ｍのインバート施工において、従来は、１週間に３サイクルの施工が限界であった。よって、[１０．５ｍ×３回／週×４週間＝１２６ｍ（月進）]となる。
これに対し、本発明のトンネルインバートの施工方法は、１週間に５サイクルの施工が可能であるため、[１０．５ｍ×５回／週×４週間＝２１０ｍ（月進）]となる。
本工事の進捗が発破により月進１５０ｍとすると、従来技術では、施工の進捗に伴い切羽とインバート部の距離が広がり（毎月２４ｍ）全体工期に悪影響を及ぼす。これに対し、本発明のトンネルインバートの施工方法は、切羽との距離を一定以内に確保でき、工事全体の急速施工を可能とする。

The tunnel invert construction method of the present invention divides one span of the prior art into two cycles before and after, and compresses the construction time by performing excavation at the second cycle simultaneously with invert placement at the first cycle. be able to. In this example, the working time is reduced by 20% from 35 units to 28 units compared to the prior art.
In an invert construction with a construction length of 10.5 m per span, conventionally, the construction of three cycles per week was the limit. Therefore, [10.5 m × 3 times / week × 4 weeks = 126 m (monthly advance)].
On the other hand, since the tunnel invert construction method of the present invention can construct five cycles in one week, [10.5 m × 5 times / week × 4 weeks = 210 m (monthly advance)].
If the progress of this construction is 150 m / month due to blasting, with the conventional technology, the distance between the face and the invert portion will increase with the progress of construction (24 m per month), which will adversely affect the entire construction period. On the other hand, the tunnel invert construction method of the present invention can ensure the distance from the face within a certain range, and enables rapid construction of the entire construction.

DESCRIPTION OF SYMBOLS 1 Invert pier 10 Work stand 11 Suspension arm 20 Front slope 30 Rear slope 40 Support leg 41 Support carriage 42 Lifting device S1 Placing space S2 Excavation space C Invert concrete

Claims (4)

Invert pier for tunnel invert construction,
A work platform having a placement space for invert concrete placement work below;
A front ramp extending between the front end of the work platform and the ground;
A rear ramp extending between the rear end of the work platform and the ground;
A plurality of support legs attached to the lower part of the work platform and supporting the work platform apart from the ground,
The width of the front ramp is less than half the width of the work platform;
The front ramp is connectable to any position in the width direction of the work platform,
Invert pier.   The invert pier according to claim 1, wherein the front ramp is slidable along a width direction of the work platform.   The plurality of support legs include a front support leg attached to the front of the work base and a rear support leg attached to the rear of the work base, and the placement space includes the front support leg and The invert pier according to claim 1, wherein the invert pier is formed between the rear support legs. A tunnel invert construction method using the invert pier according to any one of claims 1 to 3,
In the state where the tip of the front ramp on the invert pier is over the ground before construction and the tip of the rear ramp on the ground after construction,
1) preceding excavation of the ground on the face side from the work platform;
2) From the upper part of the work platform, placing invert concrete on the ground below the work platform;
3) a step of advancing the invert pier to the face side and positioning the work platform above the excavation section after the execution of the step 1),
After the 1) step and the 2) step are performed in parallel, the 3) step is performed, and this is defined as one construction cycle.
Step 1)
1a) a step of excavating the ground on the second side of the front ramp with the front ramp located on the first side in the tunnel crossing direction;
1b) in a state where the front ramp is located on the second side in the tunnel crossing direction, the first side of the front ramp includes excavating the ground of the ground,
By moving the front ramp to the left and right in the direction crossing the tunnel, the steps 1a) and 1b) are performed as appropriate interchanged.
Tunnel invert construction method.

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