JPH0266295A - Excavator for rectangular cross-section tunnel - Google Patents

Abstract

PURPOSE:To reduce the scraping torque for debris and effectively discharge it by dividing a cylindrical cutter which excavates a rectangular cross-section tunnel into a pair of a drum cutter and a ring cutter. CONSTITUTION:Drum cutters 22, 22 are turned via flanges 20A, 20A stuck to shafts 20, 20, respectively. Since the turning torque of a gear 52 is transmitted to the shaft 2 via the gears 54, 56, two ring cutters 26 and 26 are turned via shafts 24, 24, respectively. As a result, the drum cutters 22, 22 and ring cutters 26, 26 are turned counterclockwise (as shown by an arrow A) to excavate the ground 66 with cutter bits 28, 28. In this case the external end part 22A, 22B of the drum cutters 22, 22 are set as to excavate the ground by approximately the same width. The ground 66 may be therefore excavated in the rectangular cross-section form having approximately the same width as the lining 12.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a tunnel excavator used in a tunnel construction method for constructing underground tunnels, sewers, etc., and particularly to a tunnel excavator that excavates the ground in a rectangular shape. Regarding.

[Conventional technology]

Conventional tunnel excavators have often used a circular cross section due to their excavation mechanism; in other words, a cutter with a cutter bit on the front is supported rotatably around the axis of the lining.
The cutter is rotated via a rotary wheel fixed coaxially with the force to excavate the ground, and then the lining takes up the reaction force and propels it forward. This tunnel excavator excavates the ground in a circular cross section because the cutter rotates around the axis of the lining. Therefore, when constructing a pipe or tunnel with a rectangular cross section, which is often used, in order to secure this excavation cross section, it is necessary to excavate a circular cross section with a large diameter larger than the diagonal diameter in the ground. There is a problem that the earth and sand must be removed.

In order to solve this problem and make effective use of underground space, it is desirable to excavate with a rectangular cross section. A number of drilling rigs have been proposed with rotating wheels. For example, JP-A-61-7219
Publication No. 4 discloses a shield excavator that excavates a rectangular cross section in the ground. This shield tunneling machine has an integrated cylindrical rotating body that is rotatably supported with its axis perpendicular to the axis of the lining, a hydraulic motor is built inside the cylindrical rotating body, and a cutter bit is mounted on the outer circumferential surface. is installed. Therefore, by rotating the cylindrical rotating body, the cutter bit can excavate the ground into a rectangular cross section.

[Problem that the invention seeks to solve]

However, since this shield excavator uses an integral cylindrical rotating body, it is necessary to fix the shaft of the cylindrical rotating body from both outsides of the drum cutter. Therefore, since the support members that support the shaft protrude on both sides of the drum cutter, when the shield excavator is propelled, an uncut portion is created that hits the support members, and this support member comes into contact with the ground, especially when the ground is hard. , there is a problem that propulsion becomes impossible.

Furthermore, in order to reduce the unexcavation area and reduce the contact resistance between the support member and the ground, if the overhanging dimensions of the support member are made thinner and smaller, sufficient rigidity cannot be maintained and the strength will be insufficient. The disadvantage is that the required power cannot be obtained because the space, for example, the hydraulic passage, is narrow.

The present invention has been developed in view of the above circumstances, and is capable of reducing the propulsion resistance of a tunnel excavator by being stable in terms of strength, having no uncut parts, and eliminating contact resistance between the support member and the ground. At the same time, the rotary ring of the cutter bit is installed in a direction perpendicular to the direction of excavation of the tunnel excavator, which prevents rolling of the tunnel excavator and enables well-directed excavation. It is an object of the present invention to provide a rectangular cross-section tunnel excavation device that can effectively discharge the sludge by reducing the raking torque of the sludge because the directions are the same.

[Means for solving problems]

In order to achieve the above-mentioned object, the present invention includes a rectangular tunnel excavating machine body supported at the tip of a lining in a direction controllable manner, and a jack provided on the tunnel excavating machine body for controlling the direction of the tunnel excavating machine body. and a pair of drum cutters having rotating wheels in a direction perpendicular to the excavation direction and coaxially arranged at a predetermined distance at the tip of the tunnel excavator body, and a pair of drum cutters -1 arranged eccentrically. A pair of ring cutters that can excavate approximately the same diameter as the excavation diameter of the drum cutter, a rotary drive source installed in the tunnel excavation machine body, and a pair of drum cutters installed in the tunnel excavation machine body. It is characterized by having a power transmission mechanism that transmits power from a rotational drive source through a space formed on the opposing surface, and an earth removal means disposed behind the ring cutter or the drum cutter.

[Effect]

According to the present invention, by dividing the cylindrical cutter for excavating a rectangular cross section into a pair of drum cutters and a ring cutter, the support member and the power transmission mechanism can be disposed between the drum cutters. , there is no possibility of leaving uncut holes due to the support member. Therefore, when the tunnel excavator is propelled, the support member does not come into contact with the ground, so it will not become impossible to excavate even in hard ground.

〔Example〕

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of a rectangular cross-section tunnel excavation device according to the present invention will be described in detail below with reference to the accompanying drawings.

As an example, an example of the mud water pressurized shield method will be explained.

As shown in FIGS. 1 to 4, the rectangular shield tunneling machine 10 has rectangular linings 12, 12, and 12 having approximately the same diameter.
·have. At the tip of this lining 12, a rectangular shield tunneling machine main body 14 is arranged on the same axis. Lining 1 is installed at the rear of the shield tunneling machine body 14.
A tail seal 13 is provided to seal 2. The shield tunneling machine main body 14 is connected to the tip of the lining 12 at its rear via a shield jack 16.16.16.16. Therefore, by expanding and contracting the shield jack 16, it is possible to propel the shield excavator 10 and control the direction of propulsion of the shield excavator 10.

Further, a bulkhead portion 1 is provided at the tip of the shield tunneling machine main body 14.
4A is formed. The partition wall portion 14A may be provided in an arc shape along the shape of the drum cutter 22 at the tip of the shield tunneling machine main body 14.

A gear case 18 is fixed to the front side of the partition wall 14A, and a drum cutter 22.
22 is rotatably supported, and furthermore, a shaft 24.24
A ring cutter 26.26 is rotatably supported via the ring cutter 26.26. The ring cutter 26.26 is arranged between the drum cutters 22.22, as shown in FIG. Cutter bits 28, 28, . . . are spirally arranged on the entire circumferential surfaces of the ring cutter 26, 26 and the drum cutter 22, 22. Further, on the rear side of the bulkhead portion 14A of the shield tunneling machine main body 14, as shown in FIGS. 1, 3, and 4, an electric or hydraulic motor 32. 32 has been criticized in several cases.

FIG. 4 shows a power transmission mechanism 34 that transmits the rotational force of the motor 32 to the drum cutter 22 and the ring cutter 26. As shown in FIG.

This power transmission mechanism 34 has a bevel gear 38.38 fixed in the gear case 18 to an output shaft 36.36 of a reduction gear 30.30. A bevel gear 40 meshes with the bevel gear 38. Bevel gear 40.40
are fixed to both ends of the shaft 41, and a gear 42 is fixed to the center of the shaft 41. A gear 44 meshes with the gear 42, and a gear 46 meshes with the gear 44. Gear 46 is fixed to the center of shaft 48, and gears 50, 50 are fixed to both ends thereof.

A gear 52 meshes with the gear 50, and the gear 52 is fixed to the shaft 20. The shaft 20 is the gear case 18
is rotatably supported. The shaft 20 is arranged on the axis of the drum cutter 22, and its end is connected to the flange 2.
It is fixed to the drum cutter 22 via the OA. Therefore, when the motor 32.32 is driven, the bevel gear 38.
38, Bevel gear 40.40. Gear 42, Gear 44, Gear 46, Gear 50.50, Gear 52.52, Shaft 2
The drum cutter 22.22 rotates through 0.20. Further, the gear 52 meshes with a gear 54, and the gear 54 meshes with a gear 56. This gear 56 is the shaft 24
The shaft 24 is rotatably supported by the gear case 18. In the center of the shaft 24,
A ring cutter 26 is fixed. Therefore, simultaneously with the rotation of the drum cutter 22.22, the ring cutter 26.26 rotates in the same direction via the shaft 24.24.

Further, as shown in FIGS. 1 and 3, the partition wall 1114
A mud feeding pipe 58 is installed in the upper part of A, and a mud draining pipe 6 is installed in the lower part.
0 is placed. A stop valve 64 is attached to the mud discharge pipe 60 to adjust the amount of mud discharged depending on the excavation state. Further, 62 is a hydraulic unit such as a hydraulic jack 16. In addition, each drum cutter 22.22 and ring cutter 2
6. There is a seal member (
(not shown) is provided.

The operation of the rectangular cross-section tunnel excavation device according to the present invention formed as described above will be explained.

First, mud is fed from the mud feeding pipe 58 to the chamber 63, and the motors 32 and 32 are driven.

Therefore, the bevel gear 40.40 is the reducer 30.30,
It rotates via a drive shaft 36.36 and a bevel gear 38.38. Bevel gear 40.400 rotations is shaft 41,
A gear 46 is rotated via a gear 42 and a gear 44. The rotation of the gear 46 causes the shaft 48 and the gear 50.50 to rotate, and the rotation of the gear 50 causes the gear 52.52 and the shaft 20 to rotate.
．． 20 rotates. Therefore, the drum cutter 22.22 has flanges 2OA, 2OA fixed to the shaft 20.20.
Rotate through. Also, gear 520 rotation is gear 54,
It is transmitted to the shaft 24 via the gear 56, so that the two ring cutters 26.26 rotate via the shaft 24.24.

As a result, the drum cutter 22.22 and the ring cutter 26
．． 26 is in the counterclockwise direction (arrow direction) in Figure 1.
and excavate the ground 66 with the cutter bits 28, 28, . . .

In this case, as shown in FIG.
6 is arranged so that it can excavate approximately the same diameter as the drum cutter 22, and furthermore, the drum cutter 22.
The outer end portions 22A and 22B are arranged so that substantially the same width as the lining 12 can be excavated. Therefore, the ground 66 can be excavated to have a rectangular cross-section having approximately the same width as the lining 12.

Sludge generated by excavation is discharged from the mud drain pipe 60 together with muddy water.

Also, a gear case 18 supporting the shaft 20 of the drum cutter 22 and the shaft 24 of the ring cutter 26
Since the gear case 18 is disposed between the drum cutters 22 and 22 and is equipped with the ring cutters 26 and 26, the shape of the gear case 18 can be set to obtain sufficient strength, so there is no need to leave a moat. It is possible to efficiently excavate the ground 66 without causing any damage.

Furthermore, with the shield jack 16, the shield excavator main body 14
can be controlled in any direction.

As a result, since the direction of excavation can be easily changed, the shield excavator can be easily caused to excavate along the planned line.

Further, since the cutter bit 28 is spirally attached, the sludge generated during excavation can be effectively introduced into the mud removal pipe and discharged.

In the above embodiment, a single excavation unit consisting of the drum cutter 22.22 and the ring cutter 26.26 was used, but the present invention is not limited to this, and as shown in FIG. 5, the excavation unit may be provided on the upper side and the lower side. It can also be used double. As a result, a large rectangular cross-sectional hole can be excavated in the ground 66, so the large shield excavator main body 70 can be easily propelled into the ground, and the lining 72 can be constructed. In the above embodiment, the mud water pressurized shield method was explained, but the present invention can also be applied to earth pressure shield method, propulsion method, or mountain tunnel excavation method.

〔Effect of the invention〕

As explained above, according to the rectangular cross-section tunnel excavation device according to the present invention, a ring cutter capable of excavating a diameter approximately the same as the diameter of the drum cutter is rotatably supported between the pair of drum cutters. Therefore, it is possible to excavate the ground in a rectangular shape, and since there is no unexcavated area between the drum cutter and ring cutter, the propulsion resistance of the tunnel excavator can be reduced, and the strength of the support member can be increased. It can be secured.

[Brief explanation of the drawing]

FIG. 1 is a cross-sectional view showing an embodiment of the rectangular cross-section shield excavation device according to the present invention, FIG. 2 is a view taken along the line A-A in FIG. 1, and FIG. 3 is a cross-sectional view taken along the line B-B in FIG. , FIG. 4 is a sectional view showing the power transmission means of an embodiment of the rectangular-section shield excavation device according to the present invention, and FIG. 5 is a cross-sectional view showing the power transmission means of an embodiment of the rectangular-section shield excavation device according to the present invention, in which a plurality of excavation units are arranged. It is a sectional view showing an example. DESCRIPTION OF SYMBOLS 10... Shield excavator, 12... Lining, 14... Shield excavator main body, 16... Jacket, 18... Gear case, 20. 24... Shaft, 22... Drum cutter , 26... Ring cutter, 28... Cutter bit, 32... Rotation drive source, 34... Power transmission mechanism, 58... Sludge feeding pipe, 60... Sludge removal pipe.

Claims (3)

[Claims] (1) A rectangular tunnel excavator body supported at the tip of the lining in a direction controllable manner, a jack installed on the tunnel excavator body to control the direction of the tunnel excavator body, and a jack installed in a direction perpendicular to the excavation direction. A pair of drum cutters with rotating wheels are placed coaxially at the tip of the tunnel excavator body at a predetermined distance. A pair of ring cutters capable of excavating the same diameter, a rotary drive source installed in the tunnel excavator body, and a space formed between the opposing surfaces of a pair of drum cutters installed in the tunnel excavator body. A rectangular cross-section tunnel excavation device comprising: a power transmission mechanism that transmits power from a rotational drive source; and an earth removal means disposed behind a ring cutter or a drum cutter. (2) A plurality of excavation units each including the pair of drum cutters and a pair of ring cutters arranged between the pair of drum cutters are arranged in parallel at the tip of the main body of the tunnel excavator. ) Tunnel excavation equipment described. (3) A claim characterized in that cutter teeth are disposed around the entire circumferences of the drum cutter and the ring cutter, and cutter bits are disposed spirally in opposite directions on the pair of drum cutters. (1) The rectangular cross-section tunnel excavation device described in (1).