JP2001132385A - Underwater shield tunneling method and shield machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently backfill a segment tunnel constructed in the rear of a shield machine. SOLUTION: This invention provides an underwater shield tunneling method and the shield machine used for the method as means for solving the above problem. This method has such characteristics that the shield machine is driven in the water while assembling segments rearward and the rearward existing segments are backfilled followed to the driving using soil in the working face side of the shield machine removed in driving.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an underwater shield method and a shield machine.

[0002]

Conventionally, in the construction of underwater tunnels, a submerging method, a shield method, and the like have been used. The underwater tunnel using the shield method has advantages such as a small amount of excavated soil and does not require a large-scale skeleton manufacturing yard. However, it has disadvantages such as a large earth covering and a large planned height of the tunnel. Therefore, an object of the present invention is to reduce the earth covering in the underwater shield construction method and efficiently backfill the segment tunnel constructed behind the shield machine.

[0003]

According to the present invention, as a means for solving the above-described problems, the shield machine is propelled underwater while assembling the segments rearward, and the face of the shield machine removed at the time of propulsion is removed. An underwater shield method is provided, in which the existing segment at the rear is sequentially back-filled following the propulsion using earth and sand.

According to a second aspect of the present invention, in the underwater shield method according to the first aspect, the earth and sand on the face side of the shield machine is removed by means of excavation from above the water, and is transported to the periphery of the existing segment at the rear through the water and filled. Provide an underwater shield method characterized by returning.

According to a third aspect of the present invention, in the underwater shield method according to the second aspect, of the earth and sand on the face side of the shield machine, earth and sand near the bottom of the shield machine flows into the shield machine, and is discharged into the shield machine. To provide an underwater shield method characterized by being carried out from the back of a tunnel through mud equipment.

According to a fourth aspect, in the underwater shield method according to the first aspect, the earth and sand on the face side of the shield machine flows into the shield machine, communicates with the inside and outside of the shield machine, and reaches the existing segment at the rear. An underwater shield method characterized by backfilling an existing segment at the back via a backfill pipe.

According to a fifth aspect of the present invention, in the underwater shield method according to the fourth aspect, a part of the earth and sand which has flowed into the shield machine is used for backfilling the existing rear segment.
Another part is to provide an underwater shield method characterized by being carried out from the rear of the tunnel through the sludge equipment inside the shield machine.

According to a sixth aspect of the present invention, in the underwater shield method according to the first aspect, a part of the earth and sand on the face side of the shield machine is caused to flow into the shield machine, communicates with the inside and outside of the shield machine, and the existing segment at the rear. An underwater shield method is characterized in that the existing segment at the rear is backfilled through a backfill pipe that reaches to the ground, and other parts of the earth and sand are removed and removed by means of excavation from the water.

According to a seventh aspect of the present invention, there is provided a shield machine for use in the underwater shield method according to the fourth aspect, wherein means for taking in the earth and sand on the face side of the shield machine into the shield machine, And a backfill pipe that reaches the existing segment and transports the earth and sand taken into the shield machine to the periphery of the existing segment at the rear.

According to an eighth aspect of the present invention, in the shield machine used in the underwater shield method according to the fifth aspect, means for taking in the earth and sand on the face side of the shield machine into the shield machine, and communicating the inside and outside of the shield machine with the rear of the shield machine. It has a backfill pipe that reaches the existing segment and transports a part of the sediment taken in the shield machine to the periphery of the existing segment at the back, and a mud exhaust facility that carries out the other part of the sediment taken from behind the tunnel. Provide a shield machine characterized by the above. Hereinafter, referring to the drawings,
An embodiment of the present invention will be described.

[0011]

First Embodiment <A> Structure of Shield Machine As shown in FIG.
Reference numeral 0 denotes a structure in which no cutter device is provided on the front surface. A partition 110 is provided on the front surface of a cylindrical or rectangular skin plate, and a sediment inlet 111 is opened on the bottom side. In addition, a cutting port 112 is provided on the outside so as to receive the earth and sand intake port 111 as necessary. In addition, a cutter device or a stirring device may be provided in order to easily take in the earth and sand.

Inside the sediment intake 111, a sediment intake device 1 is provided.
20 is provided, and one end of a mud discharge pipe 121 reaching a predetermined discharge place behind the tunnel communicates. In the shield machine 100, in addition to the shield jack 130 and the automatic segment assembling apparatus 131, equipment necessary for construction of the shield tunnel such as a sludge drainage equipment is provided.

<B> Promotion of the shield machine While assembling the segment 200 behind the shield machine 100, the shield machine 100 is propelled by the shield jack 130. At this time, the earth covering is propelled with zero or very small. The earth and sand on the face side of the shield machine 100 is
Drilling is performed by a drilling means such as a dredger 300 on water. Thereby, the propulsive force of the shield machine 100 can be reduced.

Among the earth and sand on the face side, the earth and sand left undigged near the bottom of the shield machine 100 flows into the earth and sand intake device 120 from the earth and sand intake port 111, and is discharged from the rear of the tunnel through the exhaust pipe 121. . As described above, since the excavation by the dredger 300 and the inflow of earth and sand by the propulsive force of the shield machine 100 can remove the earth and sand on the face side, there is no need to provide a cutter device in front of the shield machine 100. Although not shown, a jet-type or mechanical earth-and-sand stirrer may be provided in the vicinity of the earth and sand intake port 111 toward the outside to facilitate the earth and sand intake.

A movable work table 210 is continuously installed at the bottom of the completed tunnel, and a mud pipe 121 or the like is mounted thereon so that the shield machine 100 can follow the propulsion. Further, in order to prevent the floating of the tunnel before the backfilling, the weight bogie 220 which moves forward following the propulsion of the shield machine 100 is installed.

<C> Backfilling of existing rear segment The earth and sand excavated by the dredger 300 is successively transported to the periphery of the existing existing segment 200 via water-borne transport means to be backfilled sand 400. Therefore, shield machine 100
In accordance with the promotion, the existing segment 200 can be efficiently backfilled.

As a specific example of the conveying means, a belt conveyor barge 310 is connected to the rear of the dredger 300, and on these ships, a hopper 320 for charging earth and sand, a belt conveyor 330 for conveying, and an existing segment 200 in the rear. And a plurality of tremie pipes 340 into which the earth and sand are introduced around the pipe. In addition, it is preferable to improve the soil quality by fluidizing the excavated earth and sand or mixing the solidified material in the middle of the conveying means.

[0018]

Second Embodiment <A> Structure of Shield Machine As shown in FIGS. 2 and 3, a shield machine 500 according to a second embodiment has a structure in which a cutter device is not provided on the front surface. A partition plate 510 is provided on the front surface of the skin plate, and a sediment intake 511 is opened on the bottom side. Further, in front of the partition wall 510, a cutting edge 512 is provided so as to project outward so as to receive the sediment intake 511. In addition, a cutter device or a stirring device may be provided in order to easily take in the earth and sand.

Inside the sediment intake 511, a sediment intake device 5 is provided.
Sedimentation sorting plant equipped with 20 and installed in a tunnel
530 is communicated by a sediment intake pipe 521. The sediment sorting plant 530 has the function of sorting the required amount for backfilling of the sediment taken in, and the unnecessary part is passed through a mud discharging facility such as a mud pipe 531 to a predetermined discharging site behind the tunnel. It is carried out.

The required amount of earth and sand is sent to an earth and sand improvement plant 540 or the like, where the soil is improved by fluidizing or mixing a solidified material. Further, one end of a backfill pipe 550 communicates with the earth and sand improvement plant 540. This backfill tube 550
Extends through, for example, the upper surface of the skin plate of the shield machine 500 and reaches the existing segment 600 at the rear.

The backfill pipe 550 has a plurality of branch pipes 551 that are branched on the segment 600 and extend downward so that backfill can be performed uniformly and efficiently. At this time, the backfill pipe may be composed of a plurality of independent pipes. Further, a moving device 552 such as a roller is provided in the backfill pipe 550 on the segment 600 so as to follow the propulsion of the shield machine 500.

The shield machine 500 includes a shield jack 560, an automatic segment assembling apparatus 561, and the like.
The facilities required for the construction of the shield tunnel are being deployed.

<B> Propulsion of the shield machine The shield machine 500 is propelled by the shield jack 560 while assembling the segment 600 behind the shield machine 500. At this time, the earth and sand on the face side of the shield machine 500 is moved from the earth and sand inlet 511 by the propulsion force to the earth and sand intake device 5.
Capture within 20.

As described above, since the sediment on the face side can be removed by taking in the earth and sand by the propulsive force of the shield machine 500, it is not necessary to provide a cutter device in front of the shield machine 500. Although not shown, a jet-type or mechanical-type earth and sand stirring device may be provided in the vicinity of the earth and sand intake port 511 toward the outside to facilitate the earth and sand intake.

At the bottom of the completed tunnel, a movable workbench 610 is continuously installed, and a sediment sorting plant 53 is installed.
0. By mounting the earth and sand improvement plant 540 and the mud pipe 531 on it, it is possible to follow the propulsion of the shield machine 500. Also, in order to prevent the floating of the tunnel before backfilling, a weight bogie 620 that moves forward following the propulsion of the shield machine 500 is installed.

<C> Backfilling of the existing rear segment The sediment taken in the sediment intake device 520 is sent to a sediment sorting plant 530 through a sediment intake pipe 521, and unnecessary portions are tunneled through a mud drain pipe 531. Discharges sequentially rearward. After the required amount is improved by the earth and sand improvement plant 540, it is successively transported to the periphery of the existing segment 600 through the backfill pipe 550, and
00. Therefore, the existing segment 600 can be efficiently backfilled following the propulsion of the shield machine 500.

[0027]

Third Embodiment A shield machine according to a second embodiment.
When propelling using the 500, a part of the face earth and sand may be excavated from the water by the dredger 300 as used in the first embodiment. Dredged soil volume from the water and shield machine 50
Balancing the amount of soil taken in and disposing of part of the excavated soil as dredged soil via water.

[0028]

Since the present invention is configured as described above,
The following effects can be obtained. <B> The face-side earth and sand can be sequentially conveyed to the periphery of the existing segment at the rear through conveying means on the water or a back-filling pipe in the shield machine. Therefore, the existing segment can be efficiently backfilled following the propulsion of the shield machine.

<B> Since the backfilling is performed sequentially following the propulsion, the period during which the segments are exposed to the water can be shortened.
The safety of the tunnel during construction is improved.

<C> In the case where the cutter device is not provided on the front surface of the shield machine, it is economical and requires less trouble.

<D> Since the shield machine is excavated with zero or very small earth cover, the planned height of the tunnel can be reduced and the total length of the tunnel can be shortened.

<E> Excavation of part of the face earth and sand from the water and disposal as dredged soil may reduce the disposal cost of the excavated earth and sand.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of Embodiment 1 of the present invention.

FIG. 2 is an explanatory diagram of Embodiment 2 of the present invention.

FIG. 3 is an explanatory diagram of Embodiment 2 of the present invention.

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Nobuyuki Hayashi 1-25-1, Nishishinjuku, Shinjuku-ku, Tokyo Taisei Construction Co., Ltd. (72) Inventor Masaki Takaku 1-25-1, Nishishinjuku, Shinjuku-ku, Tokyo Taisei Corporation F term (reference) 2D054 AA10 AC05 DA12

Claims (8)

[Claims] 1. A shield machine is propelled underwater while assembling a segment at the rear, and the existing segment at the rear is sequentially backfilled following the propulsion using earth and sand on the face side of the shield machine removed at the time of propulsion. The underwater shield method. 2. The underwater shield method according to claim 1, wherein the earth and sand on the face side of the shield machine is removed by means of excavation from above the water, and is conveyed back to the periphery of the existing segment via the water and backfilled. The underwater shield method. 3. The underwater shield method according to claim 2, wherein the earth and sand near the bottom of the shield machine among the earth and sand on the face side of the shield machine is caused to flow into the shield machine and passed through a mud discharging facility in the shield machine. Underwater shield method characterized by carrying out from behind the tunnel. 4. The underwater shield method according to claim 1, wherein earth and sand on the face side of the shield machine flows into the shield machine, and the backfill pipe communicating with the inside and outside of the shield machine and reaching the existing segment at the rear is provided. Underwater shield method characterized by backfilling the existing segment behind. 5. The underwater shield method according to claim 4, wherein a part of the earth and sand which has flowed into the shield machine is used for backfilling the existing segment at the rear, and the other part is provided with a sludge discharge facility in the shield machine. Underwater shield method characterized by being carried out from the back of the tunnel through a tunnel. 6. The underwater shield method according to claim 1, wherein a part of the earth and sand on the face side of the shield machine flows into the shield machine, communicates with the inside and outside of the shield machine, and reaches the existing segment at the rear. An underwater shield method characterized by backfilling the existing segment at the back via a return pipe, and removing other parts of the earth and sand by means of excavation from the water. 7. The shield machine used in the underwater shield method according to claim 4, wherein means for taking in the earth and sand on the face side of the shield machine into the shield machine, and communicating with the inside and outside of the shield machine to reach the existing segment at the rear. And a backfill pipe for transporting the earth and sand taken into the shield machine to the periphery of the existing segment at the rear thereof. 8. A shield machine used in the underwater shield method according to claim 5, wherein means for taking in the earth and sand on the face side of the shield machine into the shield machine, and communicating with the inside and outside of the shield machine to reach the existing segment at the rear. And a backfill pipe that transports a part of the sediment taken into the shield machine to the periphery of the existing segment at the back, and a mud discharge facility that carries out the other part of the sediment taken from behind the tunnel. A shield machine.