JP6650697B2 - Tunnel excavator - Google Patents

Description

  The present invention relates to a tunnel excavator installed in the ground to excavate a tunnel, and more particularly to a tunnel excavator capable of safely exchanging bits from inside the excavator when excavating a long-distance tunnel with a large cross section. It is.

  As a conventional technique relating to a bit exchanging technique of a tunnel excavator, for example, there is a technique disclosed in Patent Document 1. This prior art has a mechanism in which an outer peripheral cutter (12A: the reference numerals described in this patent document are shown in parentheses, the same applies hereinafter) and an inner peripheral cutter (12B) rotate independently. Further, an L-shaped cylindrical frame (58) is connected to the inner end of the cutter spoke 13, and the other end of the cylindrical frame (58) is connected to the outer cutter rotary joint (26) located at the center of the cross section. ing. The L-shaped cylindrical frame (58) in the prior art is intended to support the rotary joint, and no measures are taken, such as moving an operator in and out of the tunnel excavator.

JP 2013-231317 A

  When examining the above-mentioned prior art, the L-shaped cylindrical frame (58) does not have a space passage for workers to enter and exit and to carry in and out materials such as alternative bits. Further, the cylindrical body (26) provided on the outer periphery of the rotation shaft (25) of the center cutter (12B) is a rotary joint for the outer peripheral cutter, and does not have a worker or a room for carrying in materials. It does not have the idea, mechanism or function of exchanging bits from inside the cutter spokes, and there is no description or figure suggesting this. This conventional technique has a problem that a bit cannot be replaced from within a tunnel excavator in a long-distance shield or a super-large section shield.

  The present invention has been made in view of the above-mentioned problems, and a first object of the present invention is to smoothly exchange bits from inside a tunnel excavator in a tunnel excavator shield that excavates a long-distance tunnel with a large cross section. Is to be able to do it.

  A second object of the present invention is to facilitate replacement of bits from inside a tunnel excavator and to prevent a decrease in shield excavation work accompanying the replacement of bits.

In order to achieve the above object, the present invention provides a tunnel excavator in which a cutter head including a central cutter head and an outer peripheral cutter head is rotatably supported at a front portion of a tunnel excavator body. A plurality of cutter spokes having a hollow structure having a size capable of accommodating a human and capable of moving forward and backward, and radially extending from the periphery of the central cutter head to the outer periphery; A cutter working chamber formed inside the spokes, a rotating chamber arranged behind the center of the cutter head and having a volume that allows humans to enter and exit and work , forward from around the rotating chamber , and wherein toward the outer periphery of the cutter head is connected to the cutter spokes extending radially hollow structure of the internal human accommodate available-sized A plurality of connecting frames is, the center cutter chamber formed between the center cutter head in front of the rotary chamber and the connection frame, extends through the center cutter head, the center cutter bearing A drive shaft supported and attached to the rotation chamber, a central cutter bit attached to the drive shaft at a front surface of the central cutter head, and a drive shaft disposed in a central cutter chamber; A center stirring device having a stirring blade supported and connected thereto, wherein the connection frame having the hollow structure communicates from the rotating chamber to the cutter spokes so that humans can enter and exit, and is excavated by the center cutter head. The earth and sand taken into the central cutter chamber are stirred by the stirring action of the stirring blades provided in the central stirring device. Is, the gist that.

Thus, a room is provided at the rear part of the center of the cutter head where an operator can enter and exit, a passage extending from this room to the outer periphery of the cutter head is provided, and bits can be exchanged from inside the tunnel excavator. Further, the earth and sand excavated by the center cutter head is stirred by the center stirring device disposed in the center cutter chamber, so that the efficiency of the earth stirring operation is improved.

A second invention of the present application is directed to a tunnel excavator in which a cutter head composed of a central cutter head and an outer peripheral cutter head is rotatably supported at the front of a tunnel excavator body, and is attached to the cutter head, Is a hollow structure large enough to accommodate humans and to be able to move forward and backward, and a plurality of cutter spokes extending radially from the periphery of the central cutter head to the outer periphery, and formed inside the cutter spokes. A cutter working chamber, a rotating chamber disposed behind the center of the cutter head and having a volume that allows humans to enter and exit and work, radially from the periphery of the rotating chamber toward the outer peripheral direction of the cutter head. A plurality of connection frames extending to the cutter spokes and having a hollow structure having a size capable of accommodating a human. The connection frame having the hollow structure communicates from the rotation chamber to the cutter spoke so that a person can enter and exit, and the cutter spoke extends to the outer peripheral spoke and the center of the cutter head continuously to the outer peripheral spoke. It is divided and formed into a central spoke, and the cutter working chamber is provided inside the outer peripheral spoke, while an auxiliary cutter working chamber communicating with the cutter working chamber is provided inside the central spoke. The outer spoke and the center spoke are connected by a spoke connection device, and the spoke connection device moves up and down the cutter spoke inside a boundary between the outer spoke and the center spoke. Moving, connecting the outer peripheral spokes and the central spokes in an airtight manner, and Communicating the work chamber and the auxiliary cutter working chamber, or the subject matter that has a function to release communication.

  According to this configuration, the worker can enter the inside of the tunnel excavator from the entrance of the chamber, move to the cutter working chamber formed in the cutter spoke through the passage, and head toward the outer peripheral portion of the cutter head. . Then, when the position of the bit to be worked is reached, the bit can be repaired or the bit can be replaced.

  Since the tunnel excavator of the present invention has a chamber in which workers can enter and exit at a position behind the center of the cutter head, and a cutter working chamber connected to this chamber and formed in the cutter spoke, the inside of the tunnel excavator is controlled. Since the bit can be exchanged through the cutter head to the outer peripheral portion of the cutter head, the effect that the bit exchange operation can be performed smoothly and quickly can be obtained.

  In addition, since the room where workers can enter and exit is installed at a predetermined distance behind the cutter head, the excavated earth is not hindered from moving backward by the room, and the soil is discharged. It can be done smoothly.

It is a side sectional view showing the schematic structure of the tunnel excavator concerning a 1st embodiment of the present invention. FIG. 2 is a front view of the tunnel excavator according to the embodiment, wherein a left half is a front view viewed along arrow A in FIG. 1 and a right half is a rear view viewed along arrow B in FIG. It is a side sectional view showing the schematic structure of the tunnel excavator concerning a 2nd embodiment of the present invention. It is a fragmentary sectional view in the RR line in Drawing 3 showing the central part of the tunnel excavator concerning a 2nd embodiment of the present invention. It is a side sectional view showing the schematic structure of the tunnel excavator concerning a 3rd embodiment of the present invention. It is sectional drawing seen from the front (or back) side of the tunnel excavator which concerns on the 3rd Embodiment of this invention, The left half of FIG. 6 is the front view seen according to arrow A of FIG. The right half is a side sectional view showing a schematic configuration of the tunnel excavator according to the rear view seen along arrow B in FIG. It is a side sectional view showing the schematic structure of the tunnel excavator concerning a 4th embodiment of the present invention. FIG. 9 is a cross-sectional view of the tunnel excavator according to the fourth embodiment of the present invention as viewed from the front (or back) side, and the left half of FIG. 8 is a front view viewed along arrow C in FIG. The right half is a rear view as viewed along arrow D in FIG. It is a side sectional view showing an example of 1 composition of a spoke connection device used for a tunnel excavator concerning a 4th embodiment of the present invention. FIG. 10 is a plan view of the spoke connection device shown in FIG. 9.

Embodiment 1
Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. FIG. 1 is a side sectional view showing a schematic configuration of a tunnel excavator according to a first embodiment of the present invention. FIG. 2 is a partial front view of a central portion of the tunnel excavator according to the embodiment.

  In these figures, reference numeral 1 denotes a tunnel excavator, which excavates a tunnel underground by a shield method. Reference numeral 2 denotes an outer cylinder which defines a cylindrical structure of the tunnel excavator 1, 3 denotes a hood for protecting a front end portion of the tunnel excavator 1, 4 denotes an outer peripheral partition wall of the tunnel excavator 1, 5 denotes an inside of the tunnel excavator 1 It is a peripheral partition, and shields the excavated earth and sand excavated by the outer peripheral partition 4 and the inner peripheral partition 5 so as not to enter the working space of the tunnel excavator 1 behind. Reference numeral 6 denotes an outer peripheral cutter head, which excavates by rotating an outer peripheral portion of a face having a shield cross section. Reference numeral 7 denotes an inner peripheral cutter chamber which is located on the center side of the drive frame 8a (described later) and between the center rotating cylinder 12 (described later). Numeral 8 denotes a cutter spoke, which is hollow and has a cutter working chamber 8b secured (or formed), in which a worker enters to perform a bit replacement operation or the like. The drive frame 8 a connects the cutter spoke 8 and the turning ring 19 (described later), and transmits a rotational force to the outer peripheral cutter head 6. The cutter working chamber 8b is a chamber for repairing and replacing the cutter, etc., and is made up of a workable space secured inside the cutter spokes 8, and a worker enters the inside to exchange bits. .

  Reference numeral 9 denotes a central cutter head, which includes a central cutter bit (fish tail bit) 11 and excavates a face at the center of the tunnel excavator 1. The central cutter head 9 can be excavated at a different rotation speed and direction from the outer peripheral cutter head 6. Reference numeral 10 denotes a central cutter chamber, which represents a region formed by a cutting face excavated by the central cutter head 9 and a central rotary partition 13 provided at the rear of the central cutter head 9. Slightly behind the center cutter bit 11, a mud material injection port 11a is provided. Mud soil material (material that promotes plastic fluidization of excavated earth and sand) supplied from a through hole extending through the center of the drive shaft is ejected from the mud soil material injection port 11a.

  Reference numeral 12 denotes a center rotating cylinder, which is supported by a center bearing 28 and driven by the outer cutter head 6. A center rotating partition 13 is provided on the front surface of the center rotating cylinder 12, and the inside of the center rotating cylinder 12 has a hollow hermetic structure. A connection frame 16 (described later) is connected to the center rotary cylinder 12, and the connection frame 16 is fixed to the cutter spoke 8. Reference numeral 14 denotes a drive shaft supported and mounted via a central cutter bearing 15, which rotationally drives the central cutter head 9. The center cutter bearing 15 rotatably supports the drive shaft 14. The connection frame 16 connects the cutter spoke 8 and the central rotating cylinder 12 to transmit the rotational force of the drive shaft 14 to the cutter spoke 8 and also promotes fluidization by stirring mud in the central cutter chamber 10. There is also the effect of doing. The cross section of the connection frame 16 is formed in a circular, elliptical, or rectangular shape, and the shape of the cross section is not limited as long as there are no obstacles to workers and materials that pass through the inside. Is determined in consideration of Further, the shape of the connection frame 16 in the extension direction can be selected from a linear shape, an L shape, and a curved shape, and a plurality of shapes may be selected. Further, a central stirring device 46 having a stirring blade 45 is disposed in the central cutter chamber 10. The stirring blade 45 is connected to and supported by the drive shaft 14 by a fixed bearing 47 attached to the drive shaft 14 on the front side of the center rotary partition 13. Therefore, the stirring blade 45 rotates together with the drive shaft 14 in the center cutter chamber 10, and stirs the mud that has entered the center cutter chamber 10 with the soil material.

  Reference numeral 17 denotes a work passage formed in the connection frame 16, which is formed inside the tunnel excavator 1 and includes a cavity formed over the center rotary cylinder 12, the connection frame 16, and the cutter spokes 8, so that workers can enter and exit. It is formed into a cross-section that can carry in a substitute bit and collect materials such as a worn bit. Reference numeral 18 denotes a communication port, which is provided at a connection portion between a work passage 17 provided in the connection frame 16 and a cutter work chamber 8b provided in the cutter spoke 8, and is necessary for an operator or a bit exchange. It has a cross section through which various materials can enter and exit the cutter working chamber 8b. Reference numeral 19 denotes a revolving ring, the outer surface and the inner surface of which are in contact with the outer seal portion 29 and the inner seal portion 27, respectively, and a cutter bearing 37 is rotatably mounted on the rear end surface. A drive frame 8 a is fixed to the front end of the turning ring 19, and is rotatable via the outer peripheral cutter head 6. Reference numeral 20 denotes an outer peripheral cutter chamber, which includes a hood 3, an outer peripheral partition 4, and a bit (not shown, which has a structure that can be exchanged from inside the cutter spoke) attached to a front end of the outer peripheral cutter head 6. It is a space formed by the excavated face.

  Reference numeral 21 denotes an outer peripheral stirring blade, which is attached to the back surface of the cutter spoke 8 and agitates excavated earth and sand taken into the outer peripheral cutter chamber 20 with a soil material. Reference numeral 21a denotes an inner peripheral stirring blade, which is attached to the back surface of the cutter spoke 8 and agitates excavated earth and sand taken into the inner peripheral cutter chamber 7 with mud soil material. Reference numeral 21c denotes a fixed blade, which is composed of a rod or a blade fixed to the outer peripheral wall 4 and the inner peripheral wall 5. 22 is a water pressure gauge. Reference numeral 23 denotes a cutter pinion gear for transmitting a driving force to the cutter. Reference numeral 24 denotes a cutter drive motor for driving the cutter via the cutter pinion gear 23. 25 is a jack spreader. Reference numeral 26 denotes a cutter bearing support frame, which receives the excavating force and its own weight of the outer peripheral cutter head 6 acting on the cutter bearing 37 as a part of the shield. Reference numeral 27 denotes an inner seal portion, which is provided inside the revolving ring 19 connected to the cutter bearing support frame 26 to prevent intrusion of earth and sand or water from the front surface.

  28 is a center bearing. An outer seal portion 29 is a seal provided on the outside of the turning ring 19 connected to the cutter bearing support frame 26. Prevents sediment and water from entering from the front. Reference numeral 30 denotes a center cutter bearing B, which rotatably supports the center cutter together with the center cutter bearing A. A central cutter gear 31 and a central cutter drive motor 32 rotate the central cutter head 9 while changing (decelerating) the driving force of the central cutter drive motor 32 with the central cutter gear 31. Reference numeral 33 denotes a rotary joint, which is a hydraulic pipe extending to the cutter working chamber 8b, a control and detection cable, or a work extended to a plurality of mud soil material ejection ports (not shown) installed in the cutter spokes 8. Consists of a universal joint that relays mud material piping. Reference numeral 34 denotes a rotation chamber, which is formed inside the central rotating cylinder 12 disposed behind the central cutter head 9. The rotating chamber 34 is a room for an operator to enter and exit the cutter working chamber 8b, and is also used for loading and unloading a replacement bit and its replacement working equipment. Reference numeral 34a denotes a first doorway to the rotating chamber 34, which is disposed at the rear end of the center rotary cylinder 12, and is used as a doorway for workers and materials. The connection frame 16 is connected to the rotation chamber, and a second port 34b for allowing the rotation chamber to enter and exit the connection frame 16 is provided at the connection portion. Reference numeral 35 denotes a fixed frame which is connected to the main body of the tunnel excavator 1 and receives a rotational reaction force and a drilling reaction force of the central cutter head 9.

  Reference numeral 36 denotes a cutter gear. The rotational driving force of the cutter driving motor 24 gives a rotational force to the outer peripheral cutter head 6 via the cutter pinion gear 23 and the cutter gear 36. Reference numeral 44 denotes a screw conveyor, one end of which is connected to the outer peripheral partition 4, and discharges excavated earth and sand (discharge) taken into the internal cutter chamber 7. Reference numeral 44a denotes a discharge outlet provided at the connecting portion of the outer peripheral wall 4 of the screw conveyor 44. Reference numeral 38 denotes a shield jack for moving the excavator 1 forward. Reference numeral 39 denotes a tail plate, which is disposed behind the tunnel excavator 1 and is composed of a cylinder for assembling segments and mounting a tail seal (not shown). 40 is a segment. Reference numeral 42 denotes a cutter outer peripheral ring, which is composed of a steel ring that connects the outermost peripheral portions of the cutter spokes 8 (plural) and reinforces the cutter spokes 8 so that a number of bits can be attached. A connecting member 43 connects a cutter spoke divided body (outer peripheral spoke) 8c closer to the outer periphery in the radial direction and a cutter spoke divided body (center spoke) 8d closer to the center in the radial direction at an intermediate portion in the radial direction. To build and reinforce the overall structure of the cutter spokes 8. In the present embodiment, of the outer peripheral spokes 8c and the central spokes 8d, only the outer peripheral spokes 8c are provided with the cutter working chamber 8b inside. Not secured. That is, the width of the center spoke 8d in the front-rear direction of the excavator 1 is set smaller than that of the outer spoke 8c. Therefore, the connecting member 43 connects the outer peripheral spoke 8c and the central spoke 8d, and forms an end wall of the cutter working chamber 8b at a boundary between these.

  The operation of the tunnel excavator 1 having the above configuration will be described below. In the excavation work of the tunnel excavator 1, while excavating the ground in front of the tunnel excavator 1 with a cutter, the jack spreader 25 applies a reaction force to the existing segment, and extends to extend the tunnel excavator 1 a predetermined distance. Just move forward. That is, in excavation by the tunnel excavator 1, first, the cutter heads are rotated by driving the cutter driving motors 24 and 32 at the initial position (the state of FIG. 1) in which all the jack spreaders 25 are contracted. That is, the outer cutter head 6 and the center cutter head 9 are rotated.

  Next, all or any jack spreader 25 is extended from the above state, and the tunnel excavator 1 is propelled (forwarded) by one stroke. At this time, the propulsion reaction is received in the existing segment. With this propulsion, a large number of various cutter bits 11 mounted on the cutter heads 6 and 9 excavate the ground in front. The excavated earth and sand is taken into the outer peripheral cutter chamber 20 from the sediment intake opening opened between the cutter spokes 8 in the vicinity of the outer peripheral cutter head 6, and near the center in the vicinity of the central cutter head 9. It is taken into the inner peripheral part cutter chamber 7 and the central part cutter chamber 10 from the earth and sand intake opening opened between the cutter spokes 8. The earth and sand taken into the respective cutter chambers 7, 10, and 20 in this way are respectively taken into the outer circumference cutter chamber 20 by the stirring action of the outer circumference stirring blades 21 and agitated with the mud soil material. The earth and sand taken into the peripheral cutter chamber 7 is stirred with the mud material by the stirring action of the inner stirring blade 21a. The earth and sand taken into the central cutter chamber 10 is stirred by the stirring action of the stirring blades 45 provided in the center stirring device 46 with the mud soil material spouted from the mud soil material ejection port 11a. As described above, the central cutter chamber 10 is provided with the central stirring device 46 having the stirring blades 45 to stir the earth and sand. Therefore, the excavated earth and sand excavated by the central cutter head 9 is sufficiently stirred. Fluidity is provided. The stirred earth and sand is discharged from the cutter chambers 7, 10, and 20 to the outside by the screw conveyor 44 and the like.

  When replacing bits during the excavation work of the tunnel excavator 1 as described above, first, the excavation of the tunnel excavator 1 is stopped and the rotation of the cutter head 9 at the center of the cutter spoke 8 is stopped. Next, a worker enters the rotating chamber 34 formed in the center rotating cylinder 12 installed behind the center cutter head 9 from the first entrance 34a, and a bit and necessary equipment are brought in. Workers, bits and the like enter the cutter working chamber 8b provided in the cutter spoke 8 through the working passage 17 of the connection frame 16. Then, the worker, the bit, and the like move in the cutter working chamber 8b of the cutter spoke 8 to a site where the bit needs to be replaced (replacement work place). In this replacement work, the operator removes the damaged bit or the bit whose function has been reduced due to the expiration date from the outer peripheral cutter head 6 corresponding to the outer peripheral spoke 8c, and attaches a new bit to the portion. After the installation of the new bit is completed, the worker, the removed bit and the equipment move in the original path in the opposite direction, and pass from the cutter spoke 8 through the work passage 17 to the rotation chamber 34 of the center rotary cylinder 12. And exits through the first entrance 34a. As described above, since it is possible to move to the bit exchange position inside the tunnel excavator 1 and perform the bit exchange operation, the bit exchange operation can be made more efficient. Since the cutter working chamber 8b is not provided inside the center spoke 8d in the center of the tunnel excavator 1, the bit is exchanged from outside the cutter spoke 8 in the same manner as in the related art.

  As described above, according to the first embodiment of the present invention, the rotating chamber through which an operator can enter and exit the center of the cutter head and the cutter chamber are formed in the cutter spokes in connection with the rotating chamber. Since it has a cutter working chamber, the bit can be exchanged toward the outer peripheral portion of the cutter head through the inside of the tunnel excavator. Further, since the earth and sand is agitated with the center stirring device 46 having the stirring blade 45 in the center cutter chamber 10, the earth and sand excavated by the center cutter head 9 can be sufficiently stirred.

Embodiment 2
FIG. 3 is a side sectional view showing a second embodiment of the tunnel excavator in which bits can be exchanged from the inside of the excavator, the structure of which is partially changed from that of the first embodiment. FIG. 4 is a partial cross-sectional view taken along line RR in FIG. 3 illustrating a central portion of the tunnel excavator according to the second embodiment. Since the tunnel excavator 50 according to the second embodiment has the same basic configuration as the tunnel excavator 1 according to the first embodiment, the same members and functions as those of the first embodiment are used. Portions are given the same reference numerals and detailed description is omitted.

  The tunnel excavator 50 according to this embodiment has a first embodiment in which the structure of a rotating chamber 52 formed in a central tubular body 51 and the structure of a connection frame 53 that connects the rotating chamber 52 and the cutter spokes 8 are the first embodiment. And different. Further, the rotating chamber 52 is arranged at a position farther away (that is, farther away) from the center cutter head 9 as compared with the first embodiment. When the dimension of the rotation chamber 52 behind the cutter spokes 8 is D, the earth and sand taken into the central cutter chambers 10 and 20 by the excavation operation of the cutters 6 and 9 are the rotation chambers. The dimensions are set such that the liquid is smoothly stirred between the cutter 52 and the cutter spoke 8. Thereby, a sufficient space is formed between the cutter head and the rotation chamber.

  As described above, since the space of the dimension D is provided between the rotation chamber 52 and the cutter spoke 8, the rotation shaft 54 is provided between the center cutter head 9 and the stirring driving device 57 via the hub 56. Is provided to transmit the power of the stirring driving device 57 to the central cutter head 9. A portion of the rotating shaft 54 between the rotating chamber 52 and the hub 56 of the center cutter head 9 is provided with a center stirring device 55 having a structure different from that of the center stirring device 46 (the first embodiment). Wing members are attached. The stirring driving device 57 is supported at the front of the rotation chamber 52 by the rotation shaft 54 being attached to the rotating partition 13 by a stirring device bearing 58.

  As described above, by increasing the distance between the rotating chamber 52 and the cutter spokes 8, the spaces of the inner peripheral cutter chamber 7 and the central cutter chamber 10 are enlarged. Thus, near the center cutter head 9, the earth and sand taken into the inner cutter chamber 7 and the center cutter chamber 10 from the opening between the cut spokes 8 near the center is stirred by the center stirring device 55. Under the action, fluidity is imparted, and the fluid is discharged from the cutter chambers 7, 10, 20 to the outside by the screw conveyor 44 or the like.

  As described above, also in the second embodiment of the present invention, the rotating chamber through which an operator can enter and exit at the center rear portion of the cutter head, and the cutter formed in the cutter spoke connected to the rotating chamber. Since it has a working chamber, the bit can be exchanged toward the outer peripheral portion of the cutter head through the inside of the tunnel excavator. Further, according to the second embodiment of the present invention, the space between the cutter spoke 8 and the various partition walls 19 and 13 is made larger than in the case of a normal excavator to enlarge the chamber space. The stirring operation is easily performed, and a high degree of stirring mud is obtained.

Embodiment 3
FIG. 5 is a side sectional view showing a third embodiment in which a bit is changed from the inside of the excavator, and the structure of the tunnel excavator is partially changed from those of the first and second embodiments. is there. FIG. 6 is a cross-sectional view of the tunnel excavator according to the third embodiment of the present invention as viewed from the front (or back) side, and the left half of FIG. The right half of FIG. 6 is a rear view viewed along arrow B in FIG. Since the tunnel excavator 60 according to the third embodiment has the same basic configuration as the tunnel excavator 1 according to the first embodiment, the same members and functions as those of the first embodiment are used. Portions are given the same reference numerals and detailed description is omitted.

  In a tunnel excavator 60 according to this embodiment, a rotating chamber 61 is provided at the center of the excavator, and a working passage 17 is provided from the rotating chamber 61 toward the outer peripheral spokes 8c. The point that a member can enter the cutter spoke 8 is the same as in the first embodiment. Further, in the cutter spoke 8, the outer spoke 8c is connected at the radial center portion by the connecting member 43, and the central spoke 8d is connected at the outer diameter portion to construct and reinforce the entire structure of the cutter spoke 8. This is the same as in the first embodiment. Furthermore, the center spoke 8d is set to have a smaller width in the front-rear direction of the excavator 60 than the outer spoke 8c, and the center spoke 8d is not provided with a cutter working chamber. The material 43 connects the outer peripheral spokes 8c and the central spokes 8d, and also forms an end wall of the cutter working chamber 8b at the boundary between them, as in the first and second embodiments. . On the other hand, in the tunnel excavator 60 according to the third embodiment, the rotary chamber 61 provided in the center of the excavator is located closer to the cutter spoke 8 than the rotary chamber 35 of the first embodiment. This is because the central stirring device 45 and the stirring blade 46 used in the first embodiment are not provided in the third embodiment.

Embodiment 4
FIG. 7 is a side sectional view showing a fourth embodiment of the tunnel excavator in which a bit can be exchanged from the inside of the excavator, the structure of which is partially modified from the first to third embodiments. It is. FIG. 8 is a cross-sectional view of the tunnel excavator according to the fourth embodiment of the present invention as viewed from the front (or back) side, and the left half of FIG. 8 is a front view viewed along arrow C in FIG. The right half of FIG. 8 is a rear view viewed along arrow D in FIG. Since the tunnel excavator 70 according to the fourth embodiment has the same basic configuration as the tunnel excavator 1 according to the first embodiment, the same members and functions as those of the first embodiment are used. Portions are given the same reference numerals and detailed description is omitted.

  In a tunnel excavator 70 according to this embodiment, a rotating chamber 34 is provided in the center of the excavator, and a working passage 17 is provided from the rotating chamber 61 toward the outer spoke 8c, and work is performed for bit replacement. The point that a member can enter the cutter spoke 8 is the same as in the first embodiment. However, in the fourth embodiment, the outer spoke 8c is connected to the outer spoke 8c and the center spoke 8e (different from the center spoke 8d) at a radially intermediate portion thereof. The entire structure of the cutter spoke 8 is constructed so that a worker can enter the center spoke 8e from inside and replace the bit, and this point is different from the first to third embodiments.

  The center spoke 8e has the same longitudinal dimension as the excavator 70 in the front-rear direction and the outer spoke 8c, and a cutter working chamber 8f is formed inside. That is, in the fourth embodiment, the outer peripheral spoke 8c is provided with the cutter working chamber 8b, and the center spoke 8e is provided with the auxiliary cutter working chamber 8f. In the present embodiment, the outer spoke 8c and the center spoke 8e are connected by the spoke connection device 100. FIG. 9 is a side sectional view showing one configuration example of the spoke connection device 100. FIG. 10 is a plan view of the spoke connection device 100. The spoke connection device 100 moves up and down inside the cutter spoke 8 inside the boundary between the outer spoke 8c and the center spoke 8e to connect the outer spoke 8c and the center spoke 8e in an airtight state. In addition, it has a function of communicating or releasing the communication between the cutter working chamber 8b and the auxiliary cutter working chamber 8f. In FIG. 10, the left half with respect to the axis O3 passing through the center represents a state in which the connecting device 100 is operated to communicate the outer peripheral spoke 8c and the center spoke 8e, while the right half with respect to the axis O3 passing through the center. The half represents a state in which the connection device 100 is reversely operated to release the communication between the outer peripheral spokes 8c and the central spokes 8e.

  The spoke connection device 100 includes a connection body 101 for connecting the outer spoke 8c and the center spoke 8e, a support body 102 for supporting the connection body 101 inside the cutter spoke 8, and a connection body 101. A bottom flange 105, a seal member 106 attached to the outer periphery of the connection body 101 and abutting on the inner peripheral surface of the outer peripheral spoke 8c or the central spoke 8e, and the outer periphery of the cutter spoke 8 (radially outward; upward in FIG. 9) ) Side to the inner periphery of the connection body 101, a jet water pipe 108 extending vertically to the lower end portion of the connection body 101, a lifting jack 109 for driving the connection body 101 up and down, and an upper end of the connection body 101 A pivot jack 110 operatively connected to the portion. In the following description, the direction toward the outer periphery of the cutter spoke 8 (which is accurate in the radial direction) is defined as the upward direction, and the direction toward the center of the cutter spoke 8 is defined as the downward direction, according to the image of FIG.

  In this embodiment, the cutter spokes 8 (including the outer peripheral spokes 8c and the central spokes 8e) are formed of a cylindrical body having a rectangular cross section (see FIG. 10). A flange 116 extending in a direction perpendicular to the longitudinal direction of the center spoke 8e is provided inside the vicinity of the upper end of the center spoke 8e, and a through hole 117 through which a human can pass is formed in the flange 116. On the other hand, a lid 112 is provided in the through-hole 117 portion. Therefore, when the lid 112 is closed, the auxiliary cutter working chamber 8f of the center spoke 8e is shut off from the outside, and when the lid 112 is opened, the auxiliary cutter working chamber 8f of the center spoke 8e passes through the through hole 117 to the outer peripheral spoke. 8c can communicate with the cutter working chamber 8b. Further, a fixed block 118 for fixing and holding the spoke connection device 100 which moves up and down is attached to a predetermined height portion on the inner periphery of the outer spoke 8c by a fastening bolt 120.

  The connection body 101 forms a main body or a housing portion of the spoke connection device 100, and basically has a cylindrical tube portion 104 that opens in both end directions. Further, a bottom flange 105 extending in a direction perpendicular to the longitudinal direction of the tube portion 104 is provided inside the lower portion of the tube portion 104, and a through hole 119 through which a human can pass is provided in the bottom flange 105. On the other hand, a lid 111 is provided in the through hole 119. Therefore, when the lid 111 is closed, the lower side and the upper side are shut off with the bottom flange 105 of the cylindrical portion 104 as a boundary, and when the lid 111 is opened, the lower side is formed through the through hole 119 of the bottom flange 105 of the cylindrical portion 104. The upper side is communicated. At the lower end of the cylindrical portion 104, a blade edge 107 whose tip is shaped like a knife edge and which extends in the circumferential direction of the cylindrical portion 104 is provided.

  On the other hand, a support 102 that supports the connection body 101 is disposed at an upper end of the cylindrical portion 104. The support 102 is formed of a right-angled triangular flat plate having a curved hypotenuse 102a so as to accommodate the connector 101 having a cylindrical tubular structure in the cutter spoke 8 having a rectangular tubular structure. In this case, four support members 102 are arranged so that the right-angled portions 102b fit into the four inner corners of the outer peripheral spokes 8c, and the curved oblique side 102a is provided on the outer side of the connection body 101 with the bearing 103 interposed therebetween. 104. The connection between the support 102 and the cylinder 104 is made possible by the interposition of the bearing 103 so that relative movement is possible in the direction in which the cylinder 104 rotates, and that they can be integrally moved up and down in the vertical direction. I have. A seal member 122 is attached to the outer peripheral portion of the support body 102 so as to block the leakage of earth and sand from the inner surface of the outer peripheral spoke 8c.

  The ends of the piston rods 109a of the plurality of lifting jacks 109 are hinged to each of the supports 102. The lifting jack 109 is composed of a hydraulic cylinder device, is disposed so as to substantially coincide with the direction of the axis O3 of the outer peripheral spoke 8c, and the main body (cylinder) of the lifting jack 109 is hinged to the inner surface of the outer peripheral spoke 8c. I have. Further, a jet water pipe 108 is disposed inside the cylindrical portion 104 so as to extend in the vertical direction. The jet water pipe 108 is formed of a pipe body, hangs down from above the cutter spoke 8, extends downward through the bottom flange 105, reaches the vicinity of the cutting edge 107 of the cylindrical portion 104, and has an injection hole 115 at the tip. ing. The seal member 106 is formed of a ring-shaped body made of a material such as rubber, and is mounted on a holder 121 attached to the outer surface of the cylindrical body 104. The seal member 106 has a variable function capable of expansion and contraction, and is held in a contracted state when the spoke connection device 100 is not operated, so that the connection member 101 and the outer peripheral spoke 8c or the center spoke 8e can be connected to each other. While the gap 113 is formed between the spokes 100, the spoke 113 is deformed and held in an expanded state when the spoke connection device 100 is operated, and is pressed against the inner surface of the outer peripheral spoke 8c or the center spoke 8e to exert a water stopping function. The turning jack 110 is composed of a hydraulic cylinder, like the lifting jack 109, and the rear end of the turning jack 110 is pin-coupled to the pin support 123 of the support 102, while the tip of the piston rod of the turning jack 110 is located above the cylinder 104. It is pin-connected to the pin support 124 on the end face. Further, two turning jacks 110 are provided, and the pin support portions 123 (or 124) are arranged diagonally to each other when viewed in the plan view of FIG.

  In the above spoke connection device 100, the connecting body 101 is fitted inside the outer peripheral spoke 8c in a normal state (non-use state), and can be protruded and retracted in the center spoke 8e in use. To operate the spoke connection device 100, first, the fastening bolt 120 is removed and the fixing block 118 is separated from the outer peripheral spoke 8c. As a result, the connecting body 101 can be moved up and down freely. Therefore, while the lifting jack 109 is extended and the turning jack 110 is extended and contracted, water is jetted from the jet hole 115 of the jet water pipe 108 to rotate the connecting body 101. Let go down. During the lowering operation of the connecting body 101, the cutting edge 107 at the tip of the cylindrical portion 104 removes the sediment accumulated on the flange 116 of the central spoke 8 e by the penetrating action by the lifting jack 109 and the turning (rotating) motion by the turning jack 110. Excavate. At the same time, the jet water is jetted from the jet holes 115 of the jet water pipe 108 toward the cutting edge 107, so that the sediment accumulated near the cutting edge 107 is blown up along with the water through the gap 113 through the gap 114 together with the water. Discharge into chamber 20.

  Further, the cutting edge 107 is pressed against earth and sand accumulated near the cutting edge 107 and rotated by the lowering operation of the connecting body 101, so that the sand and gravels sandwiched between the cutting edge 107 and the upper surface of the sand 116 and the flange 116 of the central spoke 8 e. Is cut or crushed. In this way, the cutting edge 107 reliably comes into contact with the flange 116 of the center spoke 8e. It is preferable to embed a carbide tip in the cutting edge 107 or weld a wear-resistant welding material. Under this condition, the seal member 106 is expanded and pressed against the inner surface of the center spoke 8e of the seal member 106 to stop water. When the connection is made by the spoke connection device 100, the position is adjusted so that the center axes of the frequency spoke 8c and the center spoke 8e match, but the gap 113 is determined in consideration of the adjustment accuracy.

  Next, the cover 111 of the connection body is removed to open a through-hole 119 so that the operator can enter the inside of the connection body 101. Further, the cover 112 on the side of the center spoke 8e is removed to remove the outer periphery spoke 8c. Is communicated with the auxiliary cutter operation chamber 8f of the center spoke 8e. Thereby, the worker can move from the cutter working chamber 8b on the outer peripheral spoke 8c side to the auxiliary cutter working chamber 8f on the center spoke 8e side, and various kinds of the inside of the central spoke 8e in the auxiliary cutter working chamber 8f. Perform the work. When the predetermined work is completed, the operation is performed according to an operation procedure reverse to the above description. That is, the work retreats from the central spoke 8e to the outer peripheral spoke 8c, closes the lid 112, and then closes the lid 111. Then, the connecting member 101 is raised by contracting the sealing member 106 and then contracting the lifting / lowering jack 109, and when reaching the predetermined height 1, the fixing block 118 is fixed to the inner surface of the outer peripheral spoke 8c with a fastening bolt. .

  Although not shown in the drawing, for example, by providing a mechanism that can horizontally move the rear end pin support portion 123 of the turning jack 110 in the cross-sectional direction of the outer peripheral spoke 8c, the turning angle of the turning jack 110 is further increased. You can also. Thereby, the efficiency of the lowering operation of the cylindrical portion 104 can be improved. Further, the number of jet water pipes can be reduced. Further, in the fourth embodiment, as described above, the spoke connection device 100 is provided with both the lifting jack 109 and the turning jack 110 so that the lifting jack 109 is extended, and the A configuration is adopted in which water is injected from the injection hole 115 of the pipe 108 and the connecting body 101 is lowered while rotating. However, since the lowering operation of the connecting body 101 is mainly performed by the extension operation of the lifting jack 109, the turning jack 110 does not need to be particularly equipped.

  As described above, in the fourth embodiment, the rotating chamber through which an operator can enter and exit the center of the cutter head and the cutter working chamber formed in the cutter spokes connected to the rotating chamber. Further, a cutter working chamber 8b is provided in the outer peripheral spoke 8c, and an auxiliary cutter working chamber 8f is provided in the central spoke 8e so that the two cutter working chambers 8b and 8f can be connected by the spoke connecting device 100. I have to. Therefore, it is possible to enter the outer peripheral portion of the cutter spoke 8 through the inside of the tunnel excavator, and further enter the central spoke 8e from the outer peripheral spoke 8c to perform various operations such as replacement of bits.

  In the tunnel excavator of the tunnel excavator, a room is provided at the rear of the center of the cutter head so that an operator can enter and exit, and a passage is provided from this chamber through the inside of the cutter spoke to the outer periphery of the cutter head. This is useful because bits can be exchanged from inside the machine.

1, 50, 60, 70 Tunnel excavator 2 Outer cylinder 3 Hood 4 Outer peripheral wall 5 Inner peripheral wall 6 Outer peripheral cutter head 7 Inner peripheral cutter chamber 8 Cutter spoke 8a Drive frame 8b Cutter work chamber 9 Central cutter head 9a Center cutter outer peripheral ring 10 Center cutter chamber 11 Center cutter bit 12 Center rotating cylinder 13 Center rotating partition 14 Drive shaft 15 Center cutter bearing A
16, 53 Connection frame 17 Work passage 18 Connection port 19 Revolving ring 20 Outer peripheral cutter chamber 21 Outer peripheral stirring blade 21a Inner peripheral stirring blade 21b Central cutter stirring blade 21c Fixed blade 22 Earth pressure gauge 24 Cutter pinion gear 24 Cutter drive motor 25 Jack spreader 26 Cutter bearing support frame 27 Inner seal part 28 Center bearing 29 Outer seal part 30 Center cutter bearing 31 Center cutter gear 32 Center cutter drive motor 33 Rotary joints 34, 52 Rotary chamber 34a Doorway 35 Fixed frame 36 Cutter gear 37 Cutter bearing 38 Shield jack 39 Tail plate 40 Segment 42 Cutter outer ring 43 Connecting member 44 Screw conveyor 45 Central stirring device 46 Stirrer blade 47 fixed Receiving 51 the central part cylinder 54 rotates shaft 56 the hub 57 stirrer drive unit 58 stirrer bearing 100 spoke connections 101 connecting body 102 support 105 bottom flange 106 sealing member 107 cutting edge 108 jet water pipe 109 lifting jack 110 pivoting jacking

Claims (5)

In a tunnel excavator in which a cutter head composed of a central cutter head and an outer peripheral cutter head is rotatably supported at the front of the tunnel excavator body,
A plurality of cutter spokes attached to the cutter head, having a hollow structure having a size capable of accommodating a human inside, and extending radially from the periphery of the central cutter head to the outer periphery,
A cutter working chamber formed inside the cutter spokes,
A rotating chamber disposed behind the center of the cutter head and having a volume that allows humans to enter and exit;
A plurality of connection frames that extend radially forward from the periphery of the rotating chamber and toward the outer peripheral direction of the cutter head, are connected to the cutter spokes, and have a hollow structure having a size capable of accommodating a human inside. When,
A center cutter chamber formed between the rotation chamber and the center cutter head in front of the connection frame;
A drive shaft extending through the central cutter head and supported and attached to the rotating chamber via a central cutter bearing;
A central cutter bit attached to the drive shaft at a front portion of the central cutter head;
A central stirring device disposed in the central cutter chamber and provided with a stirring blade coupled and supported by the drive shaft;
The connection frame of the hollow structure, from the rotating chamber to the cutter spokes, communicates so that humans can enter and exit,
The earth and sand excavated by the center cutter head and taken into the center cutter chamber are stirred by a stirring action of a stirring blade provided in the center stirring device,
A tunnel excavator, characterized in that: In a tunnel excavator in which a cutter head composed of a central cutter head and an outer peripheral cutter head is rotatably supported at the front of the tunnel excavator body,
A plurality of cutter spokes attached to the cutter head, having a hollow structure having a size capable of accommodating a human inside, and extending radially from the periphery of the central cutter head to the outer periphery,
A cutter working chamber formed inside the cutter spokes,
A rotating chamber disposed behind the center of the cutter head and having a volume that allows humans to enter and exit;
A plurality of connection frames extending radially from the periphery of the rotating chamber toward the outer peripheral direction of the cutter head and connected to the cutter spokes, and having a hollow structure having a size capable of accommodating a human inside,
Connection frame of the hollow structure, wherein the rotary chamber to the cutter spokes, human and communicating to be out,
The cutter spoke is divided and formed into an outer peripheral spoke and a central spoke extending to the center of the cutter head continuously to the outer peripheral spoke, and the cutter working chamber is provided inside the outer peripheral spoke. On the other hand, an auxiliary cutter working chamber communicating with the cutter working chamber is provided inside the center spoke, the outer spoke and the center spoke are connected by a spoke connection device,
The spoke connection device moves up and down in the cutter spoke inside a boundary portion between the outer peripheral spoke and the center spoke, and connects the outer spoke and the center spoke in an airtight state, and Has a function of communicating with the cutter working chamber and the auxiliary cutter working chamber, or releasing the communication,
A tunnel excavator, characterized in that: The tunnel excavator according to claim 1, wherein the connection frame forms a work passage. The tunnel excavator according to claim 1 or 2, wherein a cutter working chamber for exchanging bits of the tunnel excavator is formed inside the cutter spoke. The rotary chamber is disposed at a position away from the central cutter head by a distance D such that the earth and sand taken in between the rotary chamber and the cutter spokes is smoothly stirred. The tunnel excavator according to claim 1.

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