JPH07119555B2 - Shield excavator cutter plate - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cutter plate of a shield excavator capable of excavating a tunnel in the ground where foundation piles supporting abutments or piers, or other existing cast-in-place foundation piles exist.

[0002]

2. Description of the Related Art Conventionally, shield excavators having various structures capable of excavating depending on the soil quality are known, but all have a large number of cutter bits and a sand intake port communicating with the inside of the machine. While rotating the cutter plate, the ground is excavated by the cutter bit projecting from the surface of the cutter plate, and the tunnel is excavated while taking the excavated sand from the earth and sand intake into the machine.

[0003]

However, according to such a conventional shield excavator, it is possible to excavate the ground in accordance with the planned tunnel even if the soil quality changes a little. If there is a reinforced concrete foundation pile that supports, the cutter pile protruding from the cutter plate cannot cut or remove the foundation pile.

Therefore, the ground portion where the foundation pile is present must be designed in advance so that it does not enter the planned tunnel line. Therefore, the tunnel construction site is limited and the tunnel is diverted from the foundation pile for excavation. Therefore, there is a problem that the construction period becomes longer due to the necessity of such as, and the construction cost rises. The present invention has been made in view of the above problems, and even if a foundation pile is present during tunnel excavation, a cutter plate for a shield excavator capable of smoothly and reliably cutting and removing the foundation pile. For the purpose of providing.

[0005]

In order to achieve the above object, the shield plate of the shield excavator of the present invention has a large number of cutter bits projecting from the front surface thereof and a shield excavator having a sediment intake port. A rotating cutter plate, wherein a plurality of core cutters are attached to the cutter plate body to rotate the cutter plate body.
The excavation movement trajectory of these core cutters is
Arrangement that touches or partially overlaps in the radial direction of the body
In have disposed, further comprising a possible and a structure infested these Koakatta from the cutter plate front.

[0006]

Operation The ground is excavated by the cutter bit projecting from the cutter plate while rotating the cutter plate along with the promotion of the shield excavator on the planned tunnel line. The excavated earth and sand is taken into the machine from the earth and sand intake provided on the cutter plate and discharged through the tunnel. In this way, the tunnel is excavated while excavating the face ground, but when it hits the reinforced concrete foundation pile on the way of the excavation, the core board provided in the cutter board is opposed to the foundation pile and the cutter board is Stop once.

In this state, when the core cutter is rotated and advanced, the foundation pile is cut into a circular ring at an appropriate depth from the surface by the cutting blade of the core cutter. After this cutting, the core cutter is retracted, the cutter plate is rotated by a certain angle, and the core cutter is again rotated and advanced to cut at substantially the same depth so as to partially overlap the cutting portion.

As described above, when the cutter plate is rotated by a certain angle to cut the foundation pile by the core cutter, the cut portion is continuous in the left-right direction of the foundation pile with a vertical width corresponding to the diameter of the core cutter, and the foundation pile is cut. Since the core cutter is provided in the cutter plate body at regular intervals in the radial direction of the cutter plate body, the groove portion is also bored in the vertical direction. The length portion of the foundation pile corresponding to the radial direction of the plate body is appropriately cut and cut in depth. At this time, since the rebar embedded in the concrete is also divided by the core cutter, it is cut together with the cut concrete portion.

In this way, the core cutter is used for the foundation pile,
The shape and size of the abutting facing portion of the cutter plate facing the foundation pile and the portion corresponding to the size are appropriately depth-cut and removed, and then the cut surface is again cut in the front-rear radial direction of the foundation pile in the same manner as above, By repeating this operation, the foundation pile portion facing the cutter plate is cut and removed. After that, the shield excavator is driven and the tunnel is excavated while rotating the cutter plate as usual.

[0010]

Embodiments of the present invention will now be described with reference to the drawings. 1 and 2, reference numeral 1 denotes a shield excavator, in which a disc-shaped cutter plate body 3 is arranged at a front end of an opening of a skin plate 2 thereof, and the cutter plate body 3 is appropriately spaced on the rear side thereof. It is rotatably supported by a partition wall 4 integral with the skin plate 2 stretched over.

The cutter plate main body 3 has a plurality of arm-shaped plate portions 3a, 3b radially protruding from the center and having a constant thickness and length.
And the earth and sand intake 5 provided between the opposite side surfaces of the arm-shaped plate portions 3a and 3b, and the ring-shaped peripheral edge portion 3c integrally connecting the tips of the arm-shaped plate portions 3a and 3b, A large number of cutter bits 6 for excavating earth and sand are provided so as to project forward on both side edge portions of the arm-shaped plate portions 3a, 3b and front end surfaces of the ring-shaped peripheral edge portion 3c.

The arm plate portions 3a and 3b are alternately arranged in the circumferential direction, and the cutter plate body 3 is provided on one arm plate portion 3a.
A core cutter 7 which can freely project and retract from the front surface of the above is provided with several roller cutters 8 for concrete cutting on the other arm-shaped plate portion 3b.

As shown in FIGS. 3 and 4, the core cutter 7 is formed in the shape of a short cylinder with a bottom, and is capable of cutting concrete and rebar at its annular opening end toward the front at regular intervals in the circumferential direction. The cutting blade 9 is fixed to the arm-shaped plate portion 3a so that the cutting blade 9 is rotated from the rear surface side of the arm-shaped plate portion 3a and is projected forward.

In the rotating mechanism of the core cutter 7, a movable casing 10 which is movable in the front-rear direction is arranged on the back side of the arm-shaped plate portion 3a, and a central chamber in which a drive motor 12 is installed in the inner center of the movable casing 10. 11 has a structure in which the rotary shaft 13 of the drive motor 12 is integrally fixed to the center of the outer bottom surface of the core cutter 7 via a speed reducer 14.
The operation of 12 causes the core cutter 7 to rotate on a vertical plane.

In the retracting mechanism of the core cutter 7, the movable cylindrical casing 10 is fitted and supported on the rear surface of the arm-shaped plate portion 3a so as to be movable back and forth, and the outer peripheral surface of the central chamber 11 is key-fitted. One end is connected to the central fixed casing 16 that is fitted only so that it can be moved back and forth by means such as the arm-shaped plate portion 3a or the central fixed casing 16, and the rod end is a movable casing.
It is composed of a jack 17 that is integrally connected to the inner surface of 10.
The movable casing 10 is moved back and forth by the operation of the jack 17 so that the core cutter 7 is projected and retracted from the front surface of the cutter plate body 3. The front end portion of the central fixed casing 16 is formed into a cylindrical body portion 16a capable of accommodating the core cutter 7, and its front end is opened to the front surface of the arm-shaped plate portion 3a.

As shown in FIG. 2, two such core cutters 7 are provided for each arm-shaped plate portion 3a. These core cutters 7 are the cutter plate main body 3a.
Are arranged in the outer radial direction from the center of the core at intervals corresponding to the diameter of the core cutter 7. For example, the cutter plate body 3
The core cutter on the center side is attached to the next arm-shaped plate portion 3a adjacent in the rotation direction of the cutter plate body 3 to the arm-shaped plate portion 3a having the core cutter 7 disposed closest to the center portion of the core cutter. The core cutter 7 is provided at a portion of the cutter plate body 3 in the outer diameter direction with respect to 7, at a distance substantially corresponding to the diameter of the core cutter 7.

In the same manner, the core cutters 7 are sequentially arranged on the arm plate portions 3a, 3a, 3a at positions shifted in the outer diameter direction at the above intervals in the rotation direction of the cutter plate body 3 in the same manner. The core cutters 7, 7 may be provided at positions where some of the core cutters 7 overlap each other on a concentric circle. Further, when the number of the core cutters 7 to be installed is large, the two core cutters 7 are completely concentric on each other. It may have a structure provided at overlapping positions. The core cutter 7 disposed on the outermost end side, as shown in FIG.
It is desirable to incline in the outer diameter direction.

Further, the arrangement state of the roller cutters 8 provided on the other arm-shaped plate portion 3b is such that the roller cutters 8 arranged on the arm-shaped plate portions 3a adjacent to the rotation direction of the cutter plate body 3 are sequentially arranged. The phase difference is provided so that some of them overlap. The structure of the mounting portion of the roller cutter 8 is such that mounting holes 18 are formed in each arm-shaped plate portion 3b at predetermined intervals.
The central axis of the roller cutter 8 is rotatably supported between the surfaces of the mounting hole 18 which face each other in the radial direction of the cutter plate body 3, and a part of the outer periphery of the roller cutter 8 is projected forward from the arm-shaped plate portion 3b. It is what

The rotary driving means of the cutter plate body 3 having the core cutter 7 and the roller cutter 8 may have a well-known structure, but in the drawing, the central axis 19 of the cutter plate body 3 is a partition wall. The ring body 21 is rotatably supported at the center of the support member 4 and is fixed between the tips of a plurality of support members 20 projecting from concentric circles on the rear surface of the partition wall 4.
Is also rotatably supported, and a gear 22 integrally provided on the outer peripheral surface of the ring body 21 is meshed with a small gear 24 fixed to the rotary shaft of a drive motor 23 installed on the back side of the partition wall 4. It is configured to be rotated by the drive motor 23.

Further, as means for carrying out sediment from the sediment intake chamber 25 formed in the space between the rear surface of the cutter plate body 3 and the opposing surface of the partition wall 4, a screw conveyor 26 is installed in the machine, and The screw conveyor (26) has a structure in which the opening at the downwardly inclined end faces the lower end of the earth and sand intake chamber (25). In the figure, 27 is a propulsion jack arranged at a plurality of positions on the inner peripheral surface of the skin plate 2, and 28 is an erector for segment assembly.

The shield excavator 1 thus constructed is
Segment 29 assembled in the tail of skin plate 2
To move forward by operating the propulsion jack 27 and rotate the cutter plate body 3 by the operation of the drive motor 23 to build a tunnel while excavating the ground with the cutter bit 6. Then, the excavated earth and sand is taken into the intake chamber 25 from the earth and sand intake 5, is carried into the machine by the screw conveyor 26, and is discharged through the tunnel by means of a toro or the like.

As shown in FIG. 5, the tunnel is excavated and the excavated wall surface is advanced with segment lining.
As shown in FIG. 5, when a part of the front surface of the cutter plate body 3 is in contact with the reinforced concrete support foundation pile A such as an abutment placed in the ground, the excavation of the ground is stopped at that position.

Next, the core cutter 7 disposed on any arm-shaped plate portion 3a of the cutter plate body 3, for example, FIG.
In the arm-shaped plate portion 3a having a core cutter 7-1 disposed at the outermost diameter portion and a core cutter 7-3 disposed at a portion spaced apart from the core cutter 7-1 by a distance substantially equal to the diameter of the core cutter. -1 is made to face the foundation pile A, and these core cutters 7-1 and 7-3 are rotated by the operation of the drive motor 12 and moved forward by the jack 17.

Then, these core cutters 7-1,
As shown in FIG. 7, the tip cutting blade 9 of 7-3 cuts an appropriate depth from the surface of the foundation pile A into an annular shape b1.
To be done. When the reinforcing bar C embedded in the concrete is reached during this cutting, the reinforcing bar C is also cut by the cutting blade 9 and cut into a predetermined length C1 (see FIG. 10), and is temporarily stored together with the concrete part in the core cutter. It will be in the state of being.

Next, when the core cutter reaches a depth at which it can be cut, it is retracted by the jack 17 to separate these core cutters 7-1 and 7-3 from the surface of the foundation pile A,
Rotate the cutter plate body 3 by a certain angle, and use the core cutters 7-1 and 7-3 to move the next annular cutting portion b2 in the same manner as described above so that one half overlaps with the already cut annular cutting portion b1. To cut.

The annular cutting parts b1, b2, b3 ...
As shown in FIG. 6, when the cutter plate body 3 is sequentially rotated by a predetermined angle while being cut by the core cutters 7-1 and 7-3, the core cutters 7-1 and 7-3 are cut at the time of removal or first. Due to the overlap between the cutting portion and the cutting portion to be cut next, the concrete portion of the foundation pile A surrounded by these core cutters 7-1 and 7-3 and the divided rebar portion C1 are exfoliated or cut and removed. Cutting groove B1 that is curved in the radial direction,
B3 is formed.

Further, as shown in FIG. 5, when the arm-shaped plate portion 3a is provided radially with a phase difference of 120 degrees, the core cutters 7-1 and 7- of the arm-shaped plate portion 3a-1 are provided. When the foundation pile A is cut by 3, the core cutters 7-1, 7-4 of the arm-shaped plate portion 3a-2 adjacent to the arm-shaped plate portion 3a-1,
Alternatively, the core cutters 7-2 and 7-5 of the arm-shaped plate portion 3a-3 similarly form cutting grooves B1, B4, or B2, B5 in the foundation pile portion having a constant distance from the cutting grooves B1, B3. be able to.

The foundation pile A is cut by the core cutter 7 while rotating the cutter plate body 3 at a constant angle as described above, and when the cutter plate body 3 makes one revolution, the core cutter 3 is rotated.
As shown in FIG. 6, the cutting grooves B1 to B5 cut by 7-1 to 7-5 are continuously connected in the length direction of the foundation pile A, and the portion of the foundation pile A facing the cutter plate body 3 is shown in FIG. 5, a cutting portion D having a depth corresponding to the cutting depth of the core cutter 7 is formed over a range indicated by diagonal lines.

Next, the shield excavator 1 is attached to the cutting portion D.
After the cutter plate main body 3 is brought closer, the next cutting groove may be immediately formed by the core cutter 7 in the same manner as described above, but in the cutting portion D, the uncut portion by the core cutter 7 and the divided reinforcing bar C1 are formed. In some cases, the surface of the cutting portion D is crushed by the roller cutter 8, as shown in FIGS. 9 to 12.

That is, as shown in FIG. 9 and FIG. 10, when the cutter plate body 3 is rotated while pressing the roller cutter 8 protruding from each arm-shaped plate portion 3b against the cutting portion D surface,
As shown in FIG. 12, the residual concrete protrusion protruding from the cutting portion D is scraped off and the dividing reinforcing bar C1 is also removed, and further, the concrete which remains at that portion up to the bottom of the annular cutting portion by the core cutter 7 is also removed. The portion is crushed and the surface of the cutting portion D is leveled so as not to interfere with the cutting by the core cutter 7.

After that, the shield excavator 1 is slightly advanced to bring the cutter plate body 1 close to the cutting portion D, and the cutting grooves D1 to B5 having a predetermined depth are formed in the cutting portion D by the core cutter 7 again. Then, the cutting portion D is further deepened, and the cutting surface is ground and smoothed by the roller cutter 8. By repeating this cutting work, the portion of the foundation pile A facing the cutter plate body 3 of the shield excavator 1 is cut.

After the shield excavator 1 passes through the foundation pile A while cutting the foundation pile A by the core cutter 7 of the cutter plate body 3 as described above, the cutter bit 6 of the cutter plate body 3 normally operates. We will build a tunnel while excavating the ground. The cut end face of the foundation pile A is integrated with the segment lining 29 of the tunnel and is supported by the tunnel portion.

[0033]

As described above, according to the cutter plate of the shield excavator of the present invention, in the rotary cutter plate of the shield excavator having a large number of cutter bits protruding from the front surface and having a sediment intake port, Multiple cores on the cutter plate body
The cutter with these core brackets by rotating the cutter plate body.
Drilling movement path of data is arranged with an array state as contact or partially in the radial direction of the cutter plate body overlap, further
In addition, since these core cutters are configured so that they can appear and disappear from the front surface of the cutter plate, it is of course possible to construct a tunnel as usual while excavating the ground with a cutter bit, as well as a bridge abutment on the planned tunnel line. Even if the supporting foundation pile exists, the foundation pile can be surely cut and removed by the core cutter protruding from the cutter plate body.

Further, since the core cutter is capable of projecting and retracting from the cutter plate main body and is provided at regular intervals in the radial direction of the cutter plate main body, the core cutter can be pushed to the predetermined depth by rotating the core cutter on the foundation pile. Not only can it be cut, but also the reinforcing bars in the foundation pile can be easily separated by the core cutter, and moreover, since multiple core cutters are arranged in the radial direction of the cutter plate body, these core cutters are With this, it is possible to efficiently cut the foundation pile part that blocks passage of the shield excavator, and to shorten the tunnel construction period.

[Brief description of drawings]

FIG. 1 is a simplified vertical sectional side view of a shield excavator,

FIG. 2 is a front view of the cutter plate main body,

FIG. 3 is a vertical side view of the core cutter portion,

FIG. 4 is a front view of the core cutter,

FIG. 5 is a front view of the cutter plate body facing the foundation pile on the planned tunnel line,

FIG. 6 is an explanatory view showing a cutting process of the foundation pile by the core cutter,

FIG. 7 is a vertical sectional side view showing a cutting state of a foundation pile by a core cutter,

FIG. 8 is a vertical sectional side view showing a cutting state of a foundation pile by another core cutter,

FIG. 9 is a simplified vertical sectional side view showing a crushed state by a roller cutter,

FIG. 10 is a cross sectional view thereof,

FIG. 11 is a simplified vertical sectional side view showing a cutting portion after being crushed by a roller cutter.

FIG. 12 is a cross-sectional view thereof.

[Explanation of symbols]

 1 Shield excavator 2 Skin plate 3 Cutter plate body 3a, 3b Arm plate part, 5 Sediment intake 6 Cutter bit 7 Core cutter 8 Roller cutter

Continued Front Page (72) Inventor Kiyoshi Matsumoto 2-2-2 Matsuzaki-cho, Abeno-ku, Osaka-shi, Osaka Prefecture Okumura Gumi Co., Ltd.

Claims (2)

[Claims] 1. A rotary cutter plate of a shield excavator having a large number of cutter bits protruding from the front surface and having a sand intake port , wherein a plurality of core cutters are provided on the cutter plate body.
Of these core cutters by rotating the cutter plate body
Drilling moving track with an array state as contact or partially in the radial direction of the cutter plate body are overlapped and arranged, further characterized in that these Koakatta are retractable constructed from the cutter plate front Cutter plate for shield excavator. 2. The cutter plate for a shield excavator according to claim 1, wherein a plurality of roller cutters for concrete cutting are provided on the cutter plate body so as to project therefrom.