JPH1061385A - Disc cutter device of tunnel excavator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the number of bolts, the number of processes for machining bolt holes, etc., and the number of disassembling and assembling processes and to apply a proper preload even to a reinforced disc cutter having an intermediate retainer. SOLUTION: This disc cutter device 10 comprises a disc cutter 11, retainers 12, 13 placed on both sides of the disc cutter 11, a support shaft 14 supported between the retainers 12, 13, and bearings 15, 16 via which the disc cutter 11 is freely rotationally supported against the support shaft 14. In this case, the device 10 has a through bolt 17 passed through the support shaft 14 adjacent to at least one of the end retainers 12, 13 located on the outside of the disc cutter device 10.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disk cutter for a tunnel machine and, more particularly, to a disk cutter for a tunnel machine which is configured to be fastened by bolts between retainers.

[0002]

[Prior art]

(1) FIG. 8 will be described as a first related art.
"A bracket 151 having a semicircular mounting portion 152,
Circular mounting portion 16 fitted and mounted to mounting portion 152
1 and a shaft 154 attached to a shaft support hole 160 of the retainer 153 by a bolt 158.
A disc cutter device 150 for a tunnel excavator, comprising a hub 156 rotatably supported on the shaft 154 via a bearing 155 and a cutter ring 157 mounted on the hub 156 is disclosed.

In the disk cutter device shown in the first prior art, a preload is applied to the bearing 155 during normal assembly in order to accurately support the hub 156 with respect to the shaft 154. At this time, when the retainers 153 and 153 on both sides are tightened to the shaft 154 with the bolts 158 and 158 while adjusting the thickness of the shim 162, the outer distance L between the inner rings 155a of the two bearings 155 and 155 decreases. But bearing 1
Since the outer ring 155b of 55 is positioned by the small diameter portion 156a of the hub 156, the taper roller 155c of the bearing 155 is tightened by the outer diameter of the inner ring 155a and the inner diameter of the outer ring 155b, and a preload is applied to the bearing 155.

(2) FIG. 9 showing the second prior art will be described. The support shaft 184 is supported by the end retainers 171 and 172 on both sides and the intermediate retainer 173, and the disk cutter is provided between one end retainer 171 and the intermediate retainer 173 and between the intermediate retainer 173 and the other end retainer 172, respectively. Hubs 174 and 175 are arranged, and the hubs 174 and 175 are provided with bearings 176 and 176 on the support shaft 184.
It is rotatably supported via 177. The hubs 174 and 175 have disk cutters 178 and 178, respectively.
179 are fixed. Flange part 1 of support shaft 184
84a is locked to one end retainer 172, and the other end retainer 171 is fastened to the support shaft 184 by bolts 180 to form the disk cutter device 170.

The adjustment of the preload applied to each of the two sets (four in total) of the bearings 176 and 177 shown in the second prior art is performed by adjusting the width of each of the small-diameter portions 174a and 175a of each of the hubs 174 and 175. This is achieved by adjusting the width of the distance spacers 181 and 182 inserted between the bearings 176a and 176b and between the bearings 177a and 177b. Therefore, when adjusting the preload applied to each of the two sets (four) of the bearings, the disk cutter device 17 is required.
0, the distance spacers 181 and 182 are taken out, and then the distance spacers 181 and 182 are taken out.
Adjust the width dimension of the assembling again.

(3) As a third prior art, “Japanese Patent Laid-Open No. 7-208415” shown in FIG. 10 will be described. “The support shaft 194 is supported by retainers 195 and 195 at both ends and is fixed by bolts 196 and 196. The support shaft 194 has a bearing 1 between the retainers 195 and 195 at both ends.
93, 193, two disc cutters 191,
192 are arranged side by side, and the two disk cutters 1
91 and 192 disclose a disc cutter device 190 "which is divided and can be independently rotated.

In the third prior art, when the retainers 195 and 195 on both sides are fastened to the support shaft 194 by the bolts 196 and 196 while adjusting the thickness of the shim 197, the outer ring between the inner rings 193a of the dual bearings 193 and 193 is formed. The distances L1 and L2 are reduced by being pushed by the flange portion 194a of the support shaft 194. However, each outer ring 193 of the two bearings 193
b is a small diameter portion 191a of the disk cutters 191 and 192,
192a, the two bearings 19
3,193 taper rollers 193c, 193c are inner ring 1
A preload is applied to the bearing 193 by being tightened by the outer diameter of the outer ring 93a and the inner diameter of the outer ring 193b.

[0008]

[Problems to be solved by the invention]

(1) Disk cutter device 15 in the first prior art
0 is integrated with the shaft 154 by bolts 158 for each retainer 153, so that the retainer 153
Each time a bolt 158 is required,
There is a problem that the number of holes 58 and the number of steps for machining the bolt holes and tap holes and the number of steps for assembling bolts also increase.

(2) The disk cutter device 170 of the second prior art is different from the conventional method of adjusting the preload applied to the bearings 176 and 177 by the thickness of the shim inserted into the end of the shaft 184. There is a problem that the number of steps of disassembling and assembling the 170 becomes extremely large. In the second prior art, if the distance spacers 181 and 182 are omitted and the shim method is adopted, the preload applied to the bearings 176 and 177 cannot be individually adjusted.
6,177 could not be given a uniform preload.

(3) In the third conventional disk cutter device 190, the two disk cutters 191 and 192 can rotate independently and the preload adjustment is performed by the shim 197. Since the retainers 195 and 195 that support the cutters 191 and 192 and are fixed on the face plate are provided only at both ends, and there is no intermediate retainer between both end retainers 195 and 195 as in the second related art, a high load acts. In some cases, the support shaft 19
Unless the outer diameter of No. 4 is increased, there is a problem that sufficient supporting strength cannot be obtained.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems in the prior art, and includes the number of bolts for fastening a retainer and a support shaft, the number of processing steps for a bolt hole, and the like, and the disassembling and assembling steps of a disk cutter device. It is an object of the present invention to provide a disk cutter device of a tunnel excavator which can reduce a load and can apply an appropriate preload to a reinforced disk cutter having an intermediate retainer.

[0012]

In order to achieve the above object, a disk cutter device for a tunnel machine according to a first aspect of the present invention has a disk cutter and two disk cutters disposed on both sides of the disk cutter. In a disk cutter device of a tunnel excavator, comprising: a retainer, a support shaft supported between the retainers, and a bearing rotatably supporting the disk cutter on the support shaft, of the disk cutter device, It is characterized by having a through bolt penetrating through a support shaft adjacent to at least one of the end retainers located outside.

According to the first aspect, when the retainers are tightened by the through bolts penetrating the support shaft from outside the disk cutter device, a preload is applied to the bearings between the retainers. Therefore, unlike the first related art, there is no need to tighten the retainer with a separate bolt for each retainer, so that the number of bolts used is reduced,
The number of man-hours for tap holes and the number of man-hours for bolt tightening are also reduced.

According to a second aspect of the present invention, a disk cutter device for a tunnel machine according to the first aspect includes a plurality of disk cutters and an intermediate retainer located inside the disk cutter device. It is characterized in that a separate bolt is provided for each cutter, and a through bolt that penetrates each of the support shafts and the intermediate retainer is provided.

According to the second aspect of the present invention, when the end retainers on both sides are tightened by the through bolts, a preload is applied to each bearing disposed between each end retainer and the intermediate retainer. The preload applied to each bearing can be adjusted by loosening the through bolts, changing the distance between the end retainers on both sides and the support shaft, and tightening again. Therefore, the adjustment of the preload of the bearing is simplified because the through bolt is loosened and only the outer end retainer on the outer side of the disk cutter device needs to be removed from the support shaft.

According to a third aspect of the present invention, there is provided a disk cutter device for a tunnel machine according to the first aspect, comprising a plurality of disk cutters and an intermediate retainer located inside the disk cutter device. The through bolt is fastened to another support shaft adjacent to the support shaft through which the support bolt is integral and separate from the intermediate retainer.

According to the third aspect of the present invention, when the through bolt penetrating through the support shaft integral with the end retainer is tightened to another support shaft adjacent to the support shaft and supported by the intermediate retainer, The distance between the partial retainer and the intermediate retainer is reduced, and a preload is applied to the bearing therebetween. Therefore, the following effects are obtained. (1) Since the end retainer and the support shaft adjacent thereto are integrated, there is no need to provide seals at both ends and a width for installing the seals. The length can be reduced, and the length of the disk cutter device can be shortened by the width for installing the seal, resulting in compactness. (2) Since the bolts are fastened from only one of the retainers in the double-disc type disk cutter, the number of bolts to be used can be halved as compared with the first conventional technique, and the number of man-hours for bolt holes and tapping, and for tightening bolts Assembly man-hours can also be reduced. (3) If the present invention is applied to a case where three or more disk cutters are arranged on a straight line, the arrangement length can be shortened via an intermediate retainer, and the arrangement of the cutters is easy even in a small-diameter pipe thruster. Becomes

A disk cutter device for a tunnel machine according to a fourth aspect of the present invention is the disk cutter device according to the third aspect, wherein the support shaft is supported between the adjacent intermediate retainers and is separate from the support shaft integral with the end retainers. It is characterized by having a support shaft.

According to the fourth aspect of the present invention, when the through bolt penetrating through the support shaft integrated with the end retainers on both sides is screwed to the support shaft supported between the adjacent intermediate retainers, the end portions on both sides are formed. The distance between the retainer and the intermediate retainer is reduced, and a preload is applied to each bearing therebetween. Therefore, similarly to the third invention, the length of the disk cutter device is shortened and compact, and more disk cutters can be supported by the number of support shafts supported between the intermediate retainers.

According to a fifth aspect of the present invention, there is provided a disk cutter device for a tunnel machine according to the first and second aspects, further comprising a preload adjusting shim for each bearing inserted between the end retainer and the support shaft. It is characterized by the following.

According to the fifth aspect, the through bolt is loosened to remove the outer retainer from the support shaft, and the preload of each bearing is determined by the thickness of the shim inserted between the outer end of the support shaft and each retainer. Adjusted. Therefore, especially in a disk cutter device of a double or more type, the use of through bolts enables shim adjustment with a small number of bolts, so that adjustment of the preload applied to each bearing is simplified.

According to a sixth aspect of the present invention, there is provided a disk cutter device for a tunnel machine according to the first, second, third and fourth inventions, wherein each of the support shafts and the intermediate retainer located inside the disk cutter device are connected to each other. It is characterized by having a preload adjusting shim between them.

According to the sixth aspect of the present invention, the through bolt is loosened and inserted between the intermediate retainer and the support shaft integrated with the end retainer, or between each support shaft supported by the intermediate retainer and the intermediate retainer. By changing the thickness of the shim, changing the distance between the retainers, and retightening, the preload of each bearing disposed between the retainers can be adjusted. Therefore, similarly to the fifth invention, particularly in a disk cutter device of two or more types, the use of through bolts enables shim adjustment with a small number of bolts, so that adjustment of the preload applied to each bearing is easy. become. Since only the thickness of the shim needs to be changed, adjustment of the preload applied to each bearing is simplified.

[0024]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a disk cutter device for a tunnel machine according to the present invention will be described below in detail with reference to FIGS. FIG. 1 is a longitudinal sectional view of a tunnel machine in which a disk cutter device of a tunnel machine according to the present invention is installed, FIG. 2 is a front view of FIG. 1, and FIG. 3 is a first embodiment of a disk cutter device according to the present invention. FIG. 4, FIG. 4 is a longitudinal sectional view showing a second embodiment of the disk cutter apparatus according to the present invention, FIG. 5 is a longitudinal sectional view showing a third embodiment of the disk cutter apparatus according to the present invention, and FIG. FIG. 7 is a longitudinal sectional view showing a fourth embodiment of the disk cutter device according to the present invention, and FIG. 7 is a longitudinal sectional view showing a fifth embodiment of the disk cutter device according to the present invention.

The configuration of the small-diameter pipe propulsion machine 1 as a tunnel machine will be described with reference to FIGS. A cutter head 3 is rotatably installed at the front of the front conduit 2 composed of a front front conduit 2a and a rear front conduit 2b, and the cutter head 3 is driven to rotate by a cutter driving motor 4. A plurality of disc cutter devices 10, and cutters such as a gauge disc cutter 5 and a cutter bit 6 are fixed to a front plate 3a fixed to the front surface of the cutter head 3, and excavated excavated sediments are provided between the cutters. An opening 7 is provided. A chamber 2c for taking in excavated earth and sand from the earth and sand intake opening 7 is provided behind the cutter head 3, and a screw conveyor 8 opened in the chamber 2c is installed toward the rear of the front conduit 2. .

The operation of the above configuration will be described. The cutter head 3 equipped with a cutter such as the disk cutter device 10 is driven to rotate by a cutter driving motor 4. The earth and sand excavated by the cutter head 3 is taken into the chamber 2c from the earth and sand intake opening 7 and then into the screw conveyor 8.
From the front conduit 2 and discharged to the ground from a propulsion shaft (not shown).

The configuration of the first embodiment of the disk cutter device according to the present invention will be described with reference to FIG. A first retainer 12 and a second retainer 12 are provided on both sides of a disc cutter 11 comprising a hub 11a and a cutter ring 11b fixed thereto.
A retainer 13 is provided. This first retainer 1
2 and each shaft support hole 12a, 13a of the second retainer 13
A support shaft 14 is supported between the first and second taper roller bearings 15 and 1.
6, the disk cutter 11 is rotatably supported. The first tapered roller bearing 15 and the second tapered roller bearing 16 are composed of inner rings 15a, 16a and outer rings 15b, 16
b, constituted by tapered rollers 15c and 16c. The inner ring 16a and the outer ring 16 of the second tapered roller bearing 16
b and the reference numerals of the tapered roller 16c are omitted,
According to the tapered roller bearing 15.

The first retainer 12 and the second retainer 13 are provided with through bolts 17 that pass through the support shaft 14 in a loose state.
Thus, the disk cutter device 10 is fastened to the support shaft 14. A shim 18 for adjusting the preload of each of the tapered roller bearings 15 and 16 is inserted between the outer end of the support shaft 14 and the side wall of the shaft support hole 13a of the retainer 13. A load ring 19 a and a seal ring 19 are provided between each of the retainers 12 and 13 and the disk cutter 11.
The mechanical seal 19 is provided to prevent the intrusion of earth and sand into the tapered roller bearings 15 and 16.

The operation of the configuration shown in FIG. 3 will be described.
By fixing each of the retainers 12 and 13 to the front plate 3a with a mounting bolt (not shown), the disk cutter device 1 is provided.
Although 0 is fixed to the cutter head 3, a method of assembling the disk cutter device 10 while adjusting the preload applied to each of the tapered roller bearings 15, 16 performed before that will be described. Each retainer 1 is provided by through bolt 17
When the first and second tapered roller bearings 15 and 16 are tightened, the outer dimension L between the inner rings 15a and 16a decreases. However, the outer ring 15b, 1 of each retainer 12, 13
6b is positioned by the small diameter portion 11c of the disk cutter 11, so that the tapered rollers 15c and 16c
c is tightened by the inner diameters of the outer rings 15b, 16b and the outer diameters of the inner rings 15a, 16a.
Preload is applied to 5,16. Therefore, when the through bolt 17 is tightened while adjusting the thickness of the shim 18,
The preload applied to each of the tapered roller bearings 15 and 16 is adjusted, and the disk cutter device 10 can be assembled.

The configuration of a second embodiment of the disk cutter device according to the present invention will be described with reference to FIG. A first retainer 23 and an intermediate retainer 24, and an intermediate retainer 24 and a second retainer 25 are disposed on both sides of the same two disk cutters 21 and 22 as in FIG. A first taper roller bearing 29, a second taper roller bearing 30, and a third taper roller are respectively supported on the first support shaft 26 and the second support shaft 27 supported between the shaft support holes 23a to 25a of the retainers 23 to 25. Bearing 31 and fourth tapered roller bearing 32
, Two disk cutters 21 and 22 are rotatably supported. The first to fourth tapered roller bearings 29 to 32 include an inner ring 29a to 32a and an outer ring 29b to
32b and tapered rollers 29c to 32c. The inner rings 30a to 32a, the outer rings 30b to 32b of the second to fourth taper roller bearings 30 to 32,
Although the reference numerals of the tapered rollers 30c to 32c are omitted, they are the same as those of the first tapered roller bearing 29.

Outer first retainer 23 and second retainer 2
5 means each of the support shafts 26 and 27 and the intermediate retainer 2
The disk cutter device 2 is fastened to the support shafts 26 and 27 by through bolts 28 penetrating the inside of the disk cutter 2 in a loose state.
0 is configured. Then, both outer end portions of the support shafts 26 and 27 and the shaft support holes 23a of the outer retainers 23 and 25,
Shims 33a and 33b for adjusting the preload of each of the tapered roller bearings 29 to 32 are inserted between the side walls 25a.

The inner sides of the outer rings 29b and 30b of the first taper roller bearing 29 and the second taper roller bearing 30 for rotatably supporting the first disk cutter 21 are positioned by the small diameter portion 21a of the first disk cutter 21 and at the same time. The outer dimension L of each of the inner races 29a, 30a is determined by the first retainer 23 and the intermediate retainer 24. Second
The third tapered roller bearing 31 and the fourth tapered roller bearing 32 that rotatably support the disk cutter 22 are similarly positioned, and therefore description thereof is omitted. Each of the retainers 23 to 25 and each of the disk cutters 21 and 22
Between them, a mechanical seal 19 composed of a load ring 19a and a seal ring 19b similar to that shown in FIG. 3 is installed to prevent earth and sand from entering the tapered roller bearings 29 to 32.

The operation of the configuration shown in FIG. 4 will be described.
3, the disk cutter device 20 is fixed to the cutter head 3 by fixing the retainers 23 to 25 to the front plate 3a of the cutter head 3 with mounting bolts (not shown). Bearing 29
A method of assembling the disc cutter device 20 while adjusting the preload applied to the disc cutters 32 will be described.

Each retainer 2 on the outside is formed by a through bolt 28.
3 and 25, the first and second tapered roller bearings 29,
The outer dimension L of each of the inner races 29a, 30a is reduced by being pressed. However, the first and second tapered roller bearings 2
Since the insides of the outer races 29b, 30b are positioned by the small-diameter portion 21a of the first disk cutter 21, the tapered rollers 29c, 30c are fixed to the outer races 29b, 30b.
And the outer diameters of the inner rings 29a, 30a are tightened, and a preload is applied to each of the tapered roller bearings 29, 30. Therefore, when the through bolt 28 is tightened while adjusting the thickness of the shim 33a, each tapered roller bearing 29,
The preload applied to 30 is adjusted.

Similarly, the intermediate retainer 24 and the second retainer 2
5, the outer dimension L of each of the inner rings 31a, 32a of the third and fourth tapered roller bearings 31, 32 is pressed and reduced. However, the third and fourth tapered roller bearings 31, 32
The inside of the outer races 31b and 32b is the second disk cutter 2
Since the tapered rollers 31c and 32c are positioned by the small diameter portion 22a, the tapered rollers 31c and 32c are tightened by the inner diameters of the outer rings 31b and 32b and the outer diameters of the inner rings 31a and 32a, and a preload is applied to the tapered roller bearings 31 and 32. . Therefore, when the through bolt 28 is tightened while adjusting the thickness of the shim 33b, the preload applied to each of the tapered roller bearings 31, 32 is adjusted. In this way, the disc cutter device 20 is assembled while adjusting the preload applied to each of the tapered roller bearings 29 to 32.

Referring to FIG. 5, the structure of a disk cutter according to a third embodiment of the present invention will be described. The disk cutter device 40 according to the third embodiment is different from the first embodiment in that the second retainer 13 of the disk cutter device 10 having a shape different from right to left.
And the second retainer 25 of the disk cutter device 20 of the second embodiment is integrated to form a second intermediate retainer 41, which is a triple-type disk cutter device. Other configurations and operations are the same as those of the first and second embodiments, and therefore, description thereof will be omitted.

The operation of the configuration shown in FIG. 5 will be described.
After preloading all six tapered roller bearings 15, 16, 29-32 of the triple-type disk cutter device 40, the four retainers 23, 24, 41, 12 are connected to the front plate of the cutter head 3. When fixed to 3 a, the disk cutter device 40 is attached to the cutter head 3. According to the present embodiment, even in the case of the triple-type disk cutter device 40, each of the six tapered roller bearings 1 of the disk cutter device 40 can be used.
Preload can be adjusted and applied to all of 5, 16, 29 to 32.

Although not shown in the drawings, the second retainers 25, 25 of the disk cutter device 20 of the second embodiment and the disk cutter device that is different from the disk cutter device are integrally formed.
If the second intermediate retainer is configured, the preload can be adjusted and applied to all the tapered roller bearings even in the case of a four-disc type disk cutter device.

Referring to FIG. 6, the structure of a disk cutter according to a fourth embodiment of the present invention will be described. A first end retainer 53, an intermediate retainer 54, and a second end retainer 55 are arranged on both sides of the disk cutters 51 and 52. A support shaft 53a integral with the first end retainer 53 is supported in one shaft support hole 54a of the intermediate retainer 54. The support shaft 53a has a first tapered roller bearing 56 and a second tapered roller bearing 57 interposed therebetween. Thus, the disk cutter 51 is rotatably supported. Similarly, a support shaft 55a integral with the second end retainer 55 is supported in the other shaft support hole 54b of the intermediate retainer 54. The support shaft 55a supports a third tapered roller bearing 58 and a fourth tapered roller bearing 59. , A disk cutter 52 is rotatably supported. The first tapered roller bearing 56-
The fourth taper roller bearing 59 is provided with inner rings 56a to 56a, respectively.
9a, outer rings 56b to 59b, taper rollers 56c to 59
c, but the illustration is omitted because it is the same as the second embodiment shown in FIG.

The first end retainer 53, the support shaft 53 a integral therewith, and the through bolt 60 penetrating the intermediate retainer 54 in a loose state are formed by tapping the support shaft 55 a integral with the second end retainer 55. The disk cutter device 50 is screwed into the hole. Then, between the end face of the support shaft 53a integral with the first end retainer 53 and one of the support holes 54a, the end face of the support shaft 55a integral with the second end retainer 55, and the other support hole 54b. Between the first to fourth
Shim 6 for adjusting preload of taper roller bearings 56 to 59
1, 62 are inserted.

The operation of the configuration shown in FIG. 6 will be described.
When the first end retainer 53 is tightened to the tapped hole of the support shaft 55a integral with the second end retainer 55 by the through bolt 60, the first end retainer 53 and the second end retainer 55 are tightened.
As a result, the outer distance between the inner rings 15a and 16a of the first to fourth taper roller bearings 56 to 59 decreases. However, since the insides of the outer rings 56b to 59b of the first to fourth taper roller bearings 56 to 59 are positioned by the small diameter portions 51a and 52a of the disk cutters 51 and 52, the taper rollers 56c to 59c are connected to the inner ring 5
The outer diameter of the outer ring 6a to 59a and the inner diameter of the outer ring 56b to 59b are tightened to apply a preload to each of the tapered roller bearings 56 to 59. Therefore, the disc cutter device 50 is assembled while adjusting the preload applied to the first to fourth taper roller bearings 56 to 59 according to the thicknesses of the shims 61 and 62.

Referring to FIG. 7, the structure of a disk cutter according to a fifth embodiment of the present invention will be described. A first end retainer 7 is provided on each side of the disk cutters 71, 72, 73.
4. A first intermediate retainer 75, a second intermediate retainer 76, and a second end retainer 77 are disposed. A support shaft 74a integral with the first end retainer 74 is supported in one of the shaft support holes 54a of the first intermediate retainer 75.
A support shaft 78 is supported in the other shaft support hole 75b of the intermediate retainer 75 and one shaft support hole 76a of the second intermediate retainer 76. Further, a support shaft 77 integral with the second end retainer 77 is provided in the other shaft support hole 76 b of the second intermediate retainer 76.
a is supported.

A support shaft 74 integral with the first end retainer 74
A disk cutter 71 is rotatably supported by a through a first tapered roller bearing 79 and a second tapered roller bearing 80. Also, the first and second intermediate retainers 75 and 76
A third tapered roller bearing 81 is provided on a support shaft 78 supported by
The disk cutter 72 is rotatably supported via the first and fourth tapered roller bearings 82. Further, a disk cutter 73 is rotatably supported on a support shaft 77 a integral with the second end retainer 77 via a fifth tapered roller bearing 83 and a sixth tapered roller bearing 84. The first to sixth taper roller bearings 79 to 84 are respectively constituted by inner rings 79a to 84a, outer rings 79b to 84b, and taper rollers 79c to 84c, but are not shown because they are the same as the second embodiment shown in FIG. I do.

As in the case of the fourth embodiment shown in FIG. 6, the tapped holes of the support shaft 78 supported by the first intermediate retainer 75 and the second intermediate retainer 76 have a support shaft integrated with the first end retainer 74. 74a, a first through-bolt 85 that penetrates the first intermediate retainer 75 in a loose state, and a second end retainer 77.
A disk cutter device 70 is formed by screwing a support shaft 77 a integral with the second intermediate bolt 76 and a second through bolt 86 that passes through the second intermediate retainer 76 in a play state. And between the end face of the support shaft 74a integral with the first end retainer 74 and one of the shaft support holes 75a of the first intermediate retainer 75, and the other shaft support hole 75b of the first intermediate retainer 75, or the second. Between one of the shaft support holes 76a of the intermediate retainer 76 and the support shaft 78, the end surface of the support shaft 77a integral with the second end retainer 77, and the other shaft support hole 7 of the second intermediate retainer 76.
6b, the first taper roller bearings 79-
A shim (not shown) for adjusting the preload of the sixth tapered roller bearing 84 is inserted.

The operation of the configuration shown in FIG. 7 will be described.
While adjusting the thickness of the preload adjusting shim, the through bolts 85 and 86 are used to tighten the first end retainer 74 and the support shaft 78, and the second end retainer 77 and the support shaft 78. In the same manner as in the fourth embodiment shown in FIG. 6, the preload applied to the first tapered roller bearing 79 to the sixth tapered roller bearing 84 is adjusted, and the disk cutter device 70 is assembled. The support shaft 78 may be integral with the first intermediate retainer 75 or the second intermediate retainer 76, and the through bolts 85 and 86 may extend through the support shaft 78 and be integral with the other end retainer or the support shaft 74a or 74a. 77a
The first tapered roller bearing 79 as described above.
-Preload applied to the sixth tapered roller bearing 84 can be adjusted.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view of a tunnel machine equipped with a disk cutter device similar to the second embodiment of the present invention.

FIG. 2 is a front view of FIG.

3A and 3B are diagrams showing a first embodiment of the present invention, wherein FIG. 3A is a side view, and FIG. 3B is a cross-sectional view taken along line BB of FIG.

FIG. 4 is a longitudinal sectional view of a second embodiment of the present invention.

FIG. 5 is a longitudinal sectional view of a third embodiment of the present invention.

FIG. 6 is a longitudinal sectional view of a fourth embodiment of the present invention.

FIG. 7 is a longitudinal sectional view of a fifth embodiment of the present invention.

FIGS. 8A and 8B are diagrams showing a first conventional technique, in which FIG.
(B) is BB sectional drawing of (A).

FIG. 9 is a longitudinal sectional side view showing a second conventional technique.

FIG. 10 is a vertical sectional plan view showing a third conventional technique.

[Explanation of symbols]

10, 20, 40, 50, 70 ... disk cutter device,
11, 51, 52, 71, 72, 73: disk cutter, 11a: hub, 11b: cutting, 12: first
Retainer, 13: second retainer, 12a, 13a: shaft support hole, 14, 53a, 55a, 74a, 77a, 78a ...
Support shaft, 15, 29: first tapered roller bearing, 16, 3
0: second tapered roller bearing, 15a, 16a, 29a-
32a, 56a to 59a, 79a to 84a ... inner ring, 15
b, 16b, 29b to 32b, 56b to 59b, 79b
-84b ... outer ring, 15c, 16c, 29c-32c, 5
6c-59c, 79c-84c ... taper roller, 17,
60 ... through bolts, 18, 33a, 33b, 61, 62
... Sim, 21 ... First disc cutter, 22 ... Second disc cutter, 23 ... First retainer, 24, 54 ... Intermediate retainer, 25 ... Second retainer, 23a-25a, 54a,
54b, 75a, 75b, 76a, 76b ... shaft support holes, 2
6 first support shaft, 27 second support shaft, 28 through bolt, 31 third taper roller bearing, 32 fourth taper roller bearing, 41 second intermediate retainer, 53 first end retainer, 55 2nd end retainer, 56, 79 ... 1st taper roller bearing, 57, 80 ... 2nd taper roller bearing,
58, 81 ... third tapered roller bearing, 59, 82 ... fourth
Tapered roller bearing, 74: first end retainer, 75: first intermediate retainer, 76: second intermediate retainer, 77: second
End retainer, 83: fifth tapered roller bearing, 84: sixth tapered roller bearing, 85: first through bolt, 86: second through bolt.

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Taku Arakawa 3-1-1 Ueno, Hirakata-shi, Osaka Komatsu Ltd. Osaka Plant

Claims (6)

[Claims] 1. A disk cutter comprising: a disk cutter; retainers disposed on both sides of the disk cutter; a support shaft supported between the retainers; and a bearing rotatably supporting the disk cutter on the support shaft. In a disk cutter device of a tunnel machine, a tunnel bolt having a through bolt penetrating a support shaft adjacent to at least one of end retainers located outside the disk cutter device among the retainers. Disk cutter device. 2. A disk cutter device for a tunnel machine according to claim 1, further comprising a plurality of disk cutters and an intermediate retainer located inside the disk cutter device, wherein each of said support shafts is separately provided for each disk cutter. And a through-bolt penetrating through each of the support shafts and the intermediate retainer. 3. The disk cutter device for a tunnel machine according to claim 1, further comprising a plurality of disk cutters and an intermediate retainer located inside the disk cutter device, wherein said end retainer and a support shaft adjacent thereto are provided. And a separate member from the intermediate retainer, and the through bolt is fastened to another support shaft adjacent to the support shaft through which the through bolt passes. 4. The disk cutter device for a tunnel machine according to claim 3, wherein the supporting shaft supported between the adjacent intermediate retainers and integral with the end retainer includes:
A disk cutter device for a tunnel machine, comprising a separate support shaft. 5. The disk cutter device for a tunnel machine according to claim 1, further comprising a shim for adjusting a preload of each bearing inserted between the end retainer and the support shaft. Cutter machine of a tunnel machine. 6. A disk cutter device for a tunnel machine according to claim 1, 2 or 3 for adjusting a preload between each of said support shafts and an intermediate retainer located inside said disk cutter device. A disk cutter device for a tunnel machine comprising a shim.