JPH0533583A - Rectangular shield excavator - Google Patents

Abstract

PURPOSE:To make it possible to excavate a hole having a square section and to promote crushing operation for gravel. CONSTITUTION:A shell 1 having a square section is used, and an external gear 42 is interlocked with an internal gear 41 through a crankshaft 52 to make planet motion. A rotary shaft 15 fixed to the external gea 42 is on a rotary partition 7 in a state of eccentricity to the center of the shell 1. A cutter head 20 makes also planet motion with the planet motion of the external gear 42 and the rotary shaft 15, an excavation section forming a regular triangle of the cutter head 20 descrikes a square locus, and a section corresponding to an outside diameter of the shell 1 excavates a square hole. A cone 21 of the cutter head 20 makes planet motion with the planet motion of the rotary shaft 15, so that gravel is held between a hood 2 and the cone 21 and crushed. Gravel passing through an opening 31 of a slit plate 30 is only guided to a chamber 13.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rectangular shield excavator for excavating a hole having a square cross section.

[0002]

2. Description of the Related Art Conventionally, there is the following shield excavator (Japanese Patent Laid-Open No. 63-247497). In this shield machine, a funnel-shaped hood is fixed to the front end of a cylindrical shell, a partition is fixed to the shell so that it is located behind the hood, and a chamber is provided between the rear end of the hood and the partition. Is forming. A rotary shaft is rotatably inserted through the center of the partition wall. Therefore, this axis of rotation is located at the center of the cylindrical shell. A cutter head is fixed to the tip of this rotary shaft. This cutter head consists of a cone fixed to the tip of the rotating shaft and an excavation part such as a cutter arm fixed to the tip of this cone.
A crushing chamber is formed between the cone and the hood. Then, mud water is supplied to this crushing chamber by a mud pipe, the ground is excavated by the excavation section, the excavated gravel is crushed in the crushing chamber, and the crushed gravel, earth and sand, etc. are guided from the crushing chamber to the chamber, Further, the sludge pipe communicating with the chamber is used to discharge the gas to the outside.

[0003]

By the way, recently, when digging a hole for a conduit having a square cross section, there is a demand to dig a hole having a square cross section according to the shape of the conduit.

However, in the above-mentioned conventional shield excavator, the rotary shaft is arranged at the center of the partition wall fixed to the cylindrical shell, that is, the center of the cylindrical shell, and the cutter head fixed to this rotary shaft excavates. Since this is done, the excavated hole inevitably becomes circular, and there is the problem that a hole with a square cross section cannot be excavated.

Therefore, an object of the present invention is to provide a rectangular shield excavator capable of excavating a hole having a square cross section.

[0006]

In order to achieve the above object, a rectangular shield excavator according to claim 1 has a shell having a square cross section, a funnel-shaped hood provided at a front end portion of the shell, and the shell. A rotary partition wall that is rotatably supported and forms a chamber between the front end of the hood and the front end of the hood, and that supports a rotary shaft at a position eccentric to the center of the shell, and a tip of the rotary shaft. Being fixed,
A cutter head having a cone forming a crushing chamber between the hood and a digging portion provided at the tip of the cone to form an equilateral triangle, and arranged behind the rotary partition wall.
It has an external gear and an internal gear that mesh with each other and have a diameter of the pitch circle of 3 to 4, and the center of the internal gear coincides with the center of the shell, while the external gear is An eccentric ring gear device fixed to a rotating shaft, a crank shaft rotatably supported by the shell, and a revolving shaft that revolves while rotating the external gear by meshing with the internal gear and rotating the crank shaft. And a driving device.

The rectangular shield excavator according to claim 2 is
In addition to the configuration of the rectangular shield excavator according to claim 1, a slit plate having an opening for passing gravel having a predetermined diameter or less from the crushing chamber to the chamber is fixed to the rotary shaft.

[0008]

When the drive device is driven, the crankshaft rotates, and the external gear of the eccentric ring gear device meshes with the internal gear and revolves around its own axis. Therefore, the rotating shaft fixed to the external gear also revolves around its own axis. At this time, since the rotary partition wall is rotatably supported by the shell having a square cross section and also supports the rotary shaft at an eccentric position, the rotary partition wall rotates on its axis. That is, the rotating shaft performs a planetary motion that revolves while rotating while being eccentrically supported by the shell through the rotating partition wall. For this reason, the excavation part that forms the equilateral triangle of the cutter head fixed to the tip of the rotating shaft excavates the earth and sand and gravel, and guides the earth and sand to the crushing chamber between the cone and the hood. The gravel guided to the crushing chamber is crushed by being sandwiched between the inner peripheral surface of the hood and the outer peripheral surface of the cone as the rotating shaft revolves around its axis. The crushed gravel and sand are guided to the chamber and discharged from the chamber to the outside.

At this time, since the excavated portion of the cutter head constitutes an equilateral triangle, and the diameter of the pitch circle of the external gear and the diameter of the pitch circle of the internal gear of the eccentric ring gear device have a ratio of 3: 4, that is, Assuming that the radius of the pitch circle of the external gear is 3 and the radius of the pitch circle of the internal gear is 4, the crankshaft eccentricity e has a relationship of 1. Therefore, the envelope curve of the excavation locus is shown in FIG. Squares are drilled as shown, and in combination with the shell having a square cross section, square holes are drilled.

Since a planetary motion is performed in which the rotary shaft revolves while revolving around its axis while excavating a square hole as described above, the dimension between the inner surface of the hood and the inner surface of the cone expands and contracts in the radial direction. Performs crushing action on gravel.

When the slit plate is provided as in claim 2, the dimension between the rear end of the hood and the rear end of the cone is increased due to the planetary motion of the rotating shaft, that is, the planetary motion of the cone. Large gravel that cannot be transported from the location is about to be supplied to the chamber, but since a slit plate having an opening of a predetermined size that prevents passage of such gravel is fixed to the rotating shaft, large gravel that cannot be transported. Is not supplied to the chamber, and the gravel is crushed and then supplied to the chamber through the opening of the slit plate. Therefore, the gravel is surely crushed in the crushing chamber, and only the crushed crushed gravel is supplied to the chamber.

[0012]

The present invention will be described in detail below with reference to the embodiments shown in the drawings. In FIG. 1, reference numeral 1 denotes a shell having a square cross section, and a hood 2 having a funnel-shaped inner circumference and a square outer circumference is fixed to the front end of the shell 1. Radial protrusions 3 are provided on the inner peripheral surface of the hood 2 as shown in FIG. On the other hand, a support plate 5 is fixed to the inside of the shell 1 at a predetermined distance from the rear end of the hood 2. A rotary partition 7 is rotatably attached to the support plate 5 via a bearing 6, and a chamber 13 is formed between the front surface of the rotary partition 7 and the rear end surface of the hood 2. The rotary partition wall 7 is composed of a cylindrical portion on the outer circumference, a cylindrical portion on the inner circumference, a flange portion and radial ribs, and the cylindrical portion on the inner circumference is at an eccentric position, and the rotary shaft 15 is positioned with respect to the center of the rotary partition wall 7. Is rotatably supported by a bush 16 on the eccentric inner peripheral portion. Therefore, the rotating shaft 15 is eccentric to the center of the shell 1 having a square cross section. The bearing 6 can support both radial load and thrust load acting on the rotary partition wall 7. A seal member 12 seals between a cylindrical portion on the outer periphery of the rotary partition wall 7 and a spacer plate 11 fixed to the inner periphery of the shell 1 and having a square outer periphery and a cylindrical inner periphery.

On the other hand, a cutter head 20 is fixed to the tip of the rotary shaft 15. As shown in FIGS. 1 and 2, the cutter head 20 includes a cone 21 fixed to the tip of the rotary shaft 15 and three cutter arms fixed to the tip of the cone 21 at equal intervals in the circumferential direction and extending in the radial direction. 22 and
A cutter ring 23 having a small curvature that connects almost the tips of the cutter arm 22, the cutter arm 22, and the cone 21.
And a feed blade 24 that connects the two. As shown in FIG. 2, the tip (A) of the cutter arm 22 is located substantially inside the square hood 2, and the tip A of the cutter arm 22 is connected to form an equilateral triangle.

In FIG. 2, 25 is a cutter tooth provided on the front surface of the cutter arm 22, 26 is an outer peripheral bit provided on the front surface of the cutter ring 23, and 27 is a projection provided on the outer periphery of the cone 21.

A slit plate 30 is fixed to the rotary shaft 15 so as to close the inner peripheral surface and rear end of the hood 2 and the outer peripheral surface and rear end of the cone 21. The slit plate 30 is dimensioned so that the rear end of the outer periphery of the cone 21 and the rear end of the inner periphery of the hood 2 face each other even if they are separated to the maximum extent. The slit plate 30 is provided with an opening 31 having a size that allows only gravel that can be conveyed by a mud pipe described later to pass through. Therefore, in the crushing chamber B between the inner circumference of the hood 2 and the outer circumference of the cone 21, only the gravel and the sand crushed smaller than the opening 31 can enter the chamber 13. In addition, the rotating shaft 1
5 includes a scraping plate 3 so as to be located in the chamber 13.
2 is fixed. The scraping plate 32 is used for the chamber 1
In 3 it works to stir gravel, earth and sand with muddy water.

On the other hand, an eccentric ring gear device 40 is provided behind the support plate 5. This eccentric ring gear device 4
Reference numeral 0 includes an internal gear 41 fixed to the inner circumference of the shell 1 and an external gear 42 meshing with the internal gear 4. The ratio of the pitch circle of the internal gear 41 and the pitch circle of the external gear 42 is 4: 3.
It has become. The external gear 42 is fixed to the rotary shaft 15. The center of the internal gear 41 is located at the center of the shell 1. Therefore, when the radius R ₁ of the pitch circle of the internal gear 41 is 4 and the radius R ₂ of the pitch circle of the external gear 42 is 3, the rotary shaft 15 and the external gear 42 are eccentric from the center of the shell 1 by an amount e. It is eccentric by = 1. Further, when the eccentricity e = 1, the radii R ₁ = 4, and R ₂ = 3, as shown in FIG. 2, the side length S = 14 of the shell 1 and the hood 2 and the apex A of the cutter arm are The length S of one side of the connecting regular triangle is S = 14.

On the other hand, one end of a crankshaft 52 is attached to bearings 53, 5 on a support frame 50 fixed to the shell 1.
It is rotatably supported via 4. This crankshaft 5
The other end of 2 is rotatably fitted to the rear end of the external gear 42 via a bush 55. Therefore, the external gear 42 can be meshed with the internal gear 41 by the rotation of the crankshaft 52, and the external gear 42 can be revolved while rotating along the internal gear 41. The crankshaft 5
2 is an electric motor 60 as a drive device provided in the shell 1.
The speed reducer 61 and the transmission gear 6 meshing with each other.
It is made to rotate through 2,63.

In FIG. 1, 71 is a direction correction jack for correcting the direction of excavation of this rectangular shield excavator, and 72 is a mud pipe for guiding muddy water to the crushing chamber B through an opening 73 provided in the hood 2. , 75 is the spacer plate 11
It is a mud discharge pipe for opening the wide area near the corner of the shell 1 to discharge the earth and sand in the chamber 13 to the outside.

The rectangular shield excavator having the above structure operates as follows. This rectangular shield excavator is propelled forward through a buried pipe by a jack (not shown) provided at the bottom of the vertical hole.

While propelling this rectangular shield excavator forward, an electric motor 60 drives a speed reducer 61, a transmission gear 62,
When the crankshaft 52 is rotated via 63, the external gear 42 of the eccentric ring gear device 40 rotates four times by the three rotations of the crankshaft 52 while rotating three times in the opposite direction.
Do it once. By the planetary motion of the external gear 42, the rotating shaft 1
5 and the cutter head 20 are also 3 of the crankshaft 52.
Rotate 4 times by rotation and 3 revolutions in the opposite direction
Perform a planetary motion that is repeated. This allows the cutter head 20
As described above, the locus of the tip A of the cutter arm 22 has a radius R within the pitch of the internal gear 41 of the eccentric ring gear device 40.
₁ = 4, the radius R ₂ of the pitch circle of the external gear 42 = 3, the eccentricity e of the crankshaft 52 = 1, the length S of one side of the triangle connecting the apex A of the cutter arm 22 = 14, and the shell 1 and Since the length S of one side of the hood 2 is S = 14,
The locus drawn by the equilateral triangle is as shown in FIG. 3, and the excavating portion such as the cutter arm 22 excavates a square hole conforming to the outer shape of the shell 1.

Further, by the rotation of the crankshaft 52,
Since the external gear 42 of the eccentric ring gear device 40 makes a planetary motion, the cone 21 of the cutter head 20 also makes a planetary motion. Therefore, the radial dimension of the crushing chamber B between the inner circumference of the hood 2 and the outer circumference of the cone 21 is expanded and contracted, and the gravel and the like excavated in the crushing chamber B and guided to the hood 2 are the cones 21. It is crushed by the planetary movements of moving away from each other. Therefore, the gravel can be efficiently crushed.

When crushing the gravel, the rotational moment acting on the rotary shaft 15 is supported by the rotary partition wall 7 and supported by the support plate 5 via the bearing 6. The rotating partition wall 7 supports the rotating shaft 15 at an eccentric position and can rotate about its axis, so that the planetary motion of the rotating shaft 15 is allowed.

Of the gravel crushed in the crushing chamber B, only the gravel that can pass through the opening 31 of the slit plate 30 is chamber 13 due to the muddy water guided to the crushing chamber B from the outlet 73 of the mud pipe 72. Be guided to. The opening 31
The gravel that cannot pass through is crushed into smaller pieces in the crushing chamber B and then guided to the chamber 13 through the opening 31. In this way, the gravel and earth and sand introduced into the chamber 13 are agitated by the agitation blade 32 and discharged from the outlet (not shown) through the mud pipe 75 to the outside. Since the gravel in the chamber 13 is gravel that has passed through the opening 31 of the slit plate 30, the gravel is not clogged in the mud discharge pipe 35 and is reliably discharged to the outside.

In the above embodiment, the eccentricity e of the crankshaft 52
= 1, the radius R ₁ of the pitch circle of the internal gear 41 is R 4, the radius R ₂ of the pitch circle of the external gear 42 is R ₂ , and the length S of one side of the triangle connecting the vertices A of the cutter arm 22 is S = 14. However, by changing the length of the length S of one side, it is possible to excavate a hole having a square cross section with a slightly deformed shape in which each side is curved inward or outward.

[0025]

As is apparent from the above, according to the first aspect of the invention, the shell has a square cross section, and the external gear and the internal gear that mesh with each other and have a diameter ratio of the pitch circles of 3: 4 are provided. The eccentric ring gear device is driven by a crankshaft, the external gear is rotated four times by three rotations of the crankshaft, and is revolved in the opposite direction three times, and the rotary shaft and cutter head fixed to the external gear are provided. Since the orbit of the cutter head is made to make a planetary motion in the excavation part forming the equilateral triangle of the cutter head, the locus of the excavation part of this equilateral triangle becomes a square, and in combination with the shell having a square cross section, You can drill holes in.

Further, according to the invention of claim 1, since the rotary shaft is supported at an eccentric position by the rotary partition wall and the rotary shaft is caused to perform a planetary motion through the eccentric ring gear device, the cone of the cutter head and the hood are cut off. The interval with the inner peripheral surface can be expanded or contracted to increase the crushing action of gravel in the crushing chamber.

Further, according to the invention of claim 2, a slit plate having an opening of a predetermined size is fixed to the rotary shaft, and only the gravel passing through the opening of the slit plate is guided to the chamber, so that the chamber is provided. It is possible to prevent the uncrushed gravel from being guided to the chamber so that only the gravel that does not block the sludge pipe is guided to the chamber.

[Brief description of drawings]

FIG. 1 is a sectional view of a rectangular shield excavator according to an embodiment of the present invention.

FIG. 2 is a view of the rectangular shield excavator of the above embodiment as viewed from the front.

FIG. 3 is an explanatory diagram showing that a digging portion forming an equilateral triangle digs a square hole by performing a planetary motion.

[Explanation of symbols]

1 ... Shell, 2 ... Hood, 7 ... Rotating partition wall, 13 ... Chamber, 15 ... Rotating shaft, 20 ... Cutter head, 21 ... Cone, 22 ... Cutter arm, 30 ... Slit plate, 4
0 ... Eccentric ring gear device, 41 ... Internal gear, 42 ... External gear, 52 ... Crank shaft, 60 ... Electric motor.

Claims (2)

[Claims] 1. A chamber having a square cross section, a funnel-shaped hood provided at a front end of the shell, and a front end of the hood rotatably supported by the shell. In addition, a rotary partition wall supporting the rotary shaft at a position eccentric to the center of the shell, a cone fixed to the tip of the rotary shaft and forming a crushing chamber between the hood, and a cone of this cone. A cutter head having an excavation portion that is provided at the tip and forms an equilateral triangle, and an external gear that is disposed behind the rotary partition wall and meshes with each other and that has a pitch circle diameter of 3 to 4 ratio. An eccentric ring gear device having a toothed gear, the center of the inner toothed gear coincides with the center of the shell, and the outer toothed gear is fixed to the rotating shaft; and an eccentric ring gear device rotatably supported by the shell, External teeth Rectangular shield excavating machine, characterized the crankshaft to revolve while the Ya is rotating by meshing with the internal gear, that a driving device for rotating the crank shaft. 2. The shield excavator according to claim 1, wherein a slit plate having an opening for passing gravel having a diameter of a predetermined value or less from the crushing chamber to the chamber is fixed to the rotary shaft. Shield excavator.