JPH0288883A - Method of shielding construction and excavator thereof - Google Patents

Abstract

PURPOSE:To execute a method of shielding construction safely and efficiently by excavating a branch pipe branched from a main-pipe excavating region by a second shield excavator started from a first shield excavator for excavating a main pipe and excavating the main-pipe excavating region by the first excavator. CONSTITUTION:A second shield excavator B is started from a first shield excavator A, and a branch pipe 21a branched from a main-pipe excavating region 24 is constructed. The sections of segments except the main-pipe excavating region 24 are exchanged with segments 21'' made of reinforced concrete while an intermediate wall 32 made of steel is built on the boundary section of the excavating region 24 and the branch pipe 21a. The insides of plain-concrete segments 29 are filled with sand 33 while overhauling segments 30 made of steel on the insides of segments 21 in the excavating region 24. The excavator A is moved forward along the center line 25 of the excavating region 24, a main pipe 8a is constructed, and the intermediate wall 32 is removed.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a shield construction method and an excavator therefor for efficiently performing branch pipe work, main pipe widening work, single pipe cross-sectional change work, etc.

[Conventional technology]

In the past, when excavating a branch pipe that branches from the main pipe, it took a lot of man-hours to excavate the branch pipe after excavating the main pipe.
The problem was that it was not efficient.

Furthermore, when expanding the width of the main pipe, the same problem as the former occurs because the main pipe is excavated and then the width is widened.

Furthermore, a similar problem occurred in the case of single pipe construction where the cross section changes.

[Problem to be solved by the invention]

Therefore, an object of the present invention is to efficiently perform branch pipe work, main pipe widening work, work to change the cross section of a single pipe, etc.

[Means to solve the problem]

The branch pipe construction method according to the present invention includes at least one branch pipe branching from a main excavation area by at least one second shield excavator having a smaller diameter than the first shield excavator started from a first shield excavator for main pipe excavation. The present invention is characterized in that one branch pipe is excavated, and then the main pipe excavation area is excavated by the first shield excavator.

Further, in the main pipe widening method according to the present invention, at least one second shield excavator having a smaller diameter than the first shield excavator, which is started from a first shield excavator for main pipe excavation, is used to expand the main pipe excavation area. excavating at least one main pipe widening conduit substantially parallel to and partially overlapping with the main pipe excavation area, and then excavating the main pipe excavation area by the first shield excavation machine. shall be.

Further, in the single pipe cross-section changing construction method according to the present invention, after the first main pipe is excavated by the first shield excavator for main pipe excavation, the first shield excavator started from the first shield excavator The present invention is characterized in that a second main pipe having a smaller diameter than the first main pipe is excavated by at least one second shield excavator having a small diameter.

Furthermore, the shield excavator according to the present invention includes a first shield excavator for excavating a main pipe, and at least one first shield excavator that starts from within the first shield excavator and excavates a branch pipe or a main pipe widening conduit. It is characterized by consisting of two shield tunneling machines.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

1 and 2 show one of the shield tunneling machines according to the present invention.
It consists of two second shield tunneling machines B.

The first shield excavator A is used for main pipe excavation, and
The second shield tunneling machine B has a smaller diameter than the first shield tunneling machine A, and is used for branch pipe work, main pipe widening work, or single pipe cross-section changing work.

This first shield tunneling machine A has, in front of the cylindrical outer shell 1,
It has an annular outer shield face plate 3 provided with a large number of cutter bits 2, and excavates the earth by rotating this outer shield face plate 3 with a cutter motor 4.

The excavated earth and sand is mixed with mud water supplied from the outer shield mud feeding pipe 5 and is discharged to the outside of the machine through the outer shield mud draining pipe 6. The outer shield face plate 3 has a hole 12 in the center thereof, through which the second shield tunneling machine B passes.

This first shield excavator A moves forward while kicking the segments 8 with the shield jack 7. 9 is Elecuku.

On the other hand, the second shield tunneling machine B
The bulkhead 10 of the first shield excavator A is housed in a cylindrical storage portion 11 in the first shield excavator A so that the bulkhead 10 of the first shield excavator A is substantially aligned with the bulkhead 10 of the first shield excavator A.

This second shield excavator B has a disc-shaped inner shield face plate 16 equipped with a large number of canter bits 15 in front of a cylindrical outer shell 14, and this inner shield face plate 16 is moved by a cutter motor 17. Excavate the ground by rotating it.

The excavated soil is mixed with mud water supplied from the inner shield mud feed pipe 18 and is discharged outside the machine through the inner shield mud discharge pipe 19.

This second shield excavator B moves forward while kicking the segments 21 with the shield jack 20. 22 is an erector.

Next, various construction methods using the shield excavator C will be explained.

(1) J Method First, the single branch pipe construction method using shield excavator C will be explained. This construction method is used, for example, for water/sewage pipe construction, road tunnel entrance/exit construction, etc.

(2) As shown in FIG. 3, the first shield tunneling machine A and the second shield tunneling machine B, which constitute the shield tunneling machine C, are driven together to construct the main pipe 8a. Then, the shield tunneling machine C is stopped at a predetermined position.

■ Next, as shown in FIG. 4, the second shield excavator B is started from the first shield excavator A to open the branch pipe 21a.
Build.

That is, the second shield excavator B moves straight along the center line 25 of the main excavation area 24 for a predetermined distance, and then reaches point 0.
It curves along an arcuate center line 26 centered at and exits the main excavation area 24. The second shield excavation mB that has gone out of the main excavation area 24 moves straight for a predetermined distance along an inclined axis 27 that is inclined by a predetermined angle θ with respect to the center line 25 of the main excavation area 24. Afterwards, it will stop.

At this time, a branch pipe 21a made up of segments 21 is constructed behind the second shield tunneling machine B. however,
The segment 21 that spans within the main excavation area 24 and the inside and outside of this main excavation area 24, that is, the segment 21 between the front surface 28 of the first shield excavation machine A and the end portion 29 of the curved portion, is: As shown in Figure 6, unreinforced concrete 3
0 is reinforced with a steel segment 31, and a reinforced concrete segment 21° is used for the segment outside the main excavation area 24.

■ Next, as shown in Figure 5, the segment outside the main excavation area 24 is covered with reinforced concrete segment 2.
In addition to replacing it with 1N, the main pipe excavation area 24 and branch pipe 21a
A steel inner wall 32 will be constructed at the boundary between the two.

■ Next, the segment 21 in the main excavation area 24
While dismantling the inner steel segment 30, the unreinforced segment 29 is filled with sand 33.

■ Next, after installing a face plate (not shown) with a carter bit in the center hole 12 of the outer shield face plate 3 of the first seal excavator A, the first shield excavator A is moved to the main excavation area. 24 along the center line 25 to construct the main pipe 8a.

(2) Next, remove the inner wall 32 between the main pipe 7a and the branch pipe 21H.

(2) Side widening method Next, the side widening method using shield excavator C will be explained. This construction method is used, for example, for road tunnel emergency parking zone construction, common ditch cable joint construction, etc.

(2) As shown in FIG. 7, the first shield tunneling machine A and the second shield tunneling machine B, which constitute the shield tunneling machine C, are driven together to construct the main pipe 8a. Then, the shield tunneling machine C is stopped at a predetermined position.

(2) Next, as shown in FIG. 8, the second shield excavator mB is started from the first shield excavator A to construct the main pipe widening passage 35.

That is, after the second shield excavator B moves straight along the center line 25 of the main excavation area 24 for a predetermined distance, it curves in an S-shape and returns to the position of the generatrix 36 of the main excavation area 24. Next, after going straight for a predetermined distance along the generatrix lines 3 and 6 of the main excavation area 24, it curves at a predetermined radius and retreats outside the main excavation area 24.

At this time, a main pipe widening passage 35 is constructed by the segments 21 behind the second shield excavator B.

■ Next, steel segment 3 inside segment 21
Fill with sand 33 while removing 1.

However, the main pipe widening passage 35 part is shown in Fig. 9 and 1.
As shown in Figure 0, the inner steel segment 31 of the segment 21 is removed, and the outer segment 21 of the main excavation area 24 is replaced with a steel segment 211.
The boundary with the main excavation area 24 is partitioned off by a 32° inner wall.

■ Next, after installing a face plate (not shown) having a carter pin into the center hole 12 of the outer shield face plate 3 of the first shield excavator A, the first shield excavator A is installed in the main excavation area 24. The main pipe 8a is constructed by advancing along the center line 25.

(2) Next, the inner wall 32° between the main pipe 7a and the main pipe widening passage 35 is removed to form the widened part 37.

(3) Single pipe cross section/chemical construction method Next, we will discuss the single pipe cross section change construction method using shield excavator C. This construction method is used, for example, for construction of water and sewage branch pipes.

(2) This construction method is carried out by moving the shield excavator C forward to a predetermined location and then moving only the second shield excavator B forward, as shown in FIGS. 11(al) and (b).

Next, a shield tunneling machine C° including two second shield tunneling machines B will be explained.

As shown in FIGS. 12 and 13, this shield tunneling machine C' has two second shield tunneling machines B built into a first shield tunneling machine A'.

The first shield excavator A° is used for main pipe excavation, and the two second shield excavators B are used for branch pipe work, main pipe widening work, etc.

This first shield excavator aA'' has the same structure as the first shield excavator 8, except that it has two holes 12' in the outer shield face plate 3'' for the second shield excavator iB to pass through. are the same, so the explanation will be omitted.

Furthermore, since the two second shield tunneling machines B each have the same structure as the second shield tunneling machine B in the shield tunneling machine C, the description thereof will be omitted.

Although FIG. 12 shows a case where two second shield tunneling machines B are arranged on the left and right sides, the present invention is not limited to this.

There is no hindrance to arranging the two second shield tunneling machines B one above the other.

Further, two or more second shield tunneling machines B may be provided.

Next, various construction methods using the shield excavator C" will be explained.

(1) Regarding the double branch pipe construction method, as shown in Figure 14, according to the shield excavator C'',
Two branch pipes 21a, 21a' can be constructed.

The individual branch pipes 21a', 21a'' are constructed in the same manner as the branch pipe 21a already described, so the description thereof will be omitted.

This construction method is used, for example, for water/sewage branch pipe construction, underground station escalator tunnel construction, underground parking lot construction, underground water storage tunnel construction, underground substation construction, etc.

(2) Regarding both sides widening method According to the shield excavator C°, both sides of the main pipe 8a can be simultaneously widened as shown in FIG. 15.

The individual widened portions 37", 37" are similar to the widened portion 3 already described.
Since it is constructed in the same manner as 7, the explanation will be omitted.

This construction method is used, for example, for emergency parking zones, power transmission line joints, underground station construction, etc.

〔Effect of the invention〕

As described above, according to the present invention, branch pipe work, main pipe widening work, single pipe cross-sectional change work, etc. can be carried out safely and
It can be done efficiently.

[Brief explanation of drawings]

FIG. 1 is a front view of the shield tunneling machine according to the present invention, FIG. 2 is a vertical sectional view thereof, FIGS. 3 to 5 are explanatory diagrams of the single branch pipe construction method, and FIG. 6 is a sectional view of a segment. Figure 7 - 1st O
The figures are explanatory diagrams of the single-sided IJ method, Figures 11 (al, (b)
1 is an explanatory diagram of the single pipe cross-sectional change construction method, FIG. 12 is a front view of another shield excavator according to the present invention, FIG. 13 is a longitudinal sectional view thereof, and FIG. 14 is an explanatory diagram of the double branch pipe construction method. , FIG. 15 is an explanatory diagram of the both-side width widening construction method. A: First shield excavator, B: First shield excavator, C: Shield excavator, l, 14: Outer shell,
2.15... Cutter bit, 3, 16... Shield face plate, 4. ■7...Cutter motor, 8...Sludge feeding pipe, 6,19...Sludge removal pipe, 7,2 Yatsuki, 8.21
...Segment, 9.2')ter 10.23.
...Bulkhead, hangar, 12...holes. Agent Patent Attorney Nobuo Ogawa −

Claims (1)

[Scope of Claims] 1. At least one branching area from the main excavation area by at least one second shield excavator having a smaller diameter than the first shield excavator launched from the first shield excavator for main excavation. A shield construction method in which two branch pipes are excavated, and then the main pipe excavation area is excavated by the first shield excavator. 2. Almost parallel to the main excavation area by at least one second shield excavator having a smaller diameter than the first shield excavator launched from the first shield excavator for main excavation,
and a shield construction method in which at least one main pipe widening conduit that partially overlaps with the main pipe excavation area is excavated, and then the main pipe excavation area is excavated by the first shield excavation machine. 3. After excavating the first main pipe by the first shield excavator for main pipe excavation, at least one shield excavator having a smaller diameter than the first shield excavator started from the first shield excavator.
A shield construction method in which a second main pipe having a smaller diameter than the first main pipe is excavated using two second shield excavators. 4. A shield excavator comprising a first shield excavator for excavating a main pipe, and at least one second shield excavator that starts from within the first shield excavator and excavates a branch pipe or a main pipe widening conduit. .