The present invention relates to a device for replacing an excavating bit in which a roller bit (disk cutter) abraded by crushing rocks and pebbles during excavation can be replaced from a workspace provided in a cutter head of an excavating machine such as a shield machine.
As a technique for a bit replacing device which replaces the abraded roller bit for another roller bit from the workspace formed in the cutter head during excavation, for example, Patent Literature 1 and Patent Literature 2 have been proposed. The bit replacing devices each include a rotor having an opening and disposed on the front surface of a cutter spoke. A roller bit is disposed in the opening of the rotor. When replacing the roller bit, the rotor is turned by 90° or 180° to cause the opening of the rotor to face an opening for replacement provided on the side surface side or rear surface side of the opening of the rotor. Thus, the roller bit is removed out from the opening of the rotor into the workspace via the opening for replacement.
Patent Literature 1: Japanese Patent No. 3139749
Patent Literature 2: Japanese Patent No. 4163965
In the conventional literatures, however, the rotor is disposed on the front surface of the cutter head (cutter spoke), and a sliding gap between the rotor and its supporting member is exposed so as to face the front surface of the cutter head. Thus, during excavation, muddy water pressure may be directly applied to the sliding gap or fragments of pebbles and the like may enter the gap. Accordingly, a sealing material provided at the sliding gap may be easily broken to impede the rotation of the rotor.
The present invention has been devised to solve the above problem. An object of the present invention is to provide a bit replacing device for an excavating machine which can improve sealing properties at the sliding gap of a rotor including a roller bit and replace the roller bit by smoothly rotating the rotor during excavation.
In order to solve the problem, the invention of a first aspect is a bit replacing unit for an excavating machine, in which the excavating machine includes, in the front part thereof, a cutter head rotatably supported about an excavating machine axial center, a roller bit for crushing rocks and pebbles, the roller bit being disposed on the front surface of the cutter head, and a workspace in which the abraded roller bit can be replaced, the workspace being formed inside the cutter head, wherein a housing is disposed in the front part of the cutter head, a bit containing path is formed in the housing along an in-and-out axis along which the roller bit is extended and retracted, a bit containing portion which opens at the front surface of the cutter head and a valve containing portion which is formed behind the bit containing portion are provided on the bit containing path, an opening for replacement is formed in the direction of an insertion-and-removal axis at a predetermined angle with relative to the in-and-out axis in the housing, the opening for replacement communicating with the valve containing portion and the workspace, a rotary valve is provided in the valve containing portion, the rotary valve being rotatable about a rotary axis substantially perpendicular to the in-and-out axis and the insertion-and-removal axis, an attachment/detachment path communicating with the bit containing portion is formed in the rotary valve, a bit case containing the roller bit is removably inserted into the attachment/detachment path, the rotary valve is turned at a predetermined angle to cause the attachment/detachment path to communicate with the opening for replacement, so that the bit case is movable between the attachment/detachment path and the workspace, a bit extending/retracting mechanism for extending and retracting the bit case between the attachment/detachment path and the bit containing portion is provided on the rotary valve, a first sealing material is provided for sealing at a gap between the bit case and the valve containing portion, and a second sealing material is provided for sealing at a gap between the periphery of the opening of the attachment/detachment path and the inner surface of the valve containing portion on the outer peripheral surface of the rotary valve.
The invention of a second aspect is the bit replacing unit for an excavating machine according to the first aspect wherein a reactive force support block is provided on the rear surface side of the bit case in the attachment/detachment path of the rotary valve, the reactive force support block transferring the excavating reactive force of the roller bit to the housing, and a cotter for transferring the excavating reactive force is removably fitted between the bit case and the reactive force support block in the valve containing portion.
The invention of a third aspect is the bit replacing unit for an excavating machine according to the first or second aspect, wherein the bit containing path penetrates through the cutter head, the attachment/detachment path penetrates through the rotary valve, the reactive force support block is removably inserted into the attachment/detachment path, and the reactive force support block is removably inserted into the workspace from the rear opening of the attachment/detachment path of the rotary valve via the opening for replacement.
The invention of a fourth aspect is the bit replacing unit for an excavating machine according to the third aspect, wherein a first soil removal path containing the roller bit penetrates through the bit case in the direction of the in-and-out axis, a second soil removal path communicating with the first soil removal path penetrates through the reactive force support block in the direction of the in-and-out axis, and soil excavated by the roller bit can be discharged from the first soil removal path to the rear surface side of the cutter head via the second soil removal path.
According to the configuration of the first aspect, the valve containing portion containing the rotary valve is formed behind the bit containing portion which opens at the front surface of the cutter head, and the bit case including the roller bit is moved from the attachment/detachment path of the rotary valve so as to protrude into the bit containing portion. Thus, a sliding gap between the rotary valve and the valve containing portion is covered by the bit case and is not exposed to the front surface of the cutter head. Further, the first sealing material stops water at a gap between the bit containing portion and the bit case, and muddy water pressure is supported by the first sealing material during excavation. Thus, fragments of pebbles and the like do not enter the gap between the rotary valve and the valve containing portion together with muddy water and muddy water pressure is not directly applied to the second sealing material during excavation. Hence, the sliding gap between the rotary valve and the valve containing portion can be favorably sealed, so that the rotary valve can be smoothly rotated when replacing the abraded roller bit.
According to the configuration of the second aspect, the excavating reactive force transferred from the bit case via the cotter can be supported by the housing via the reactive force support block on the rear surface side of the attachment/detachment path. Thus, a large excavating reactive force can be effectively supported.
According to the configuration of the third aspect, the reactive force support block is first removed from the attachment/detachment path, and then the bit case is removed from the attachment/detachment path, so that the roller bit can be easily replaced. Further, options for the rotation direction of the rotary valve can be increased.
According to the configuration of the fourth aspect, soil excavated by the roller bit can be smoothly discharged from the first soil removal path to the rear surface side of the cutter head via the second soil removal path, so that rocks and pebbles can be favorably crushed.
Embodiments of the present invention will be described.
The following will describe an embodiment of a bit replacing unit which is a bit replacing device for a shield machine (excavating machine) according to the present invention.
A first embodiment will be described with reference to
[Shield Machine]
As shown in
As shown in
A plurality of bit replacing units 30 according to the present invention are arranged on the main spoke member 21. A roller bit 31 for crushing rocks and pebbles is provided on each bit replacing unit 30 so as to be rotatable about an axis in a radial direction of the shield body 11. The roller bits 31 on all the bit replacing units 30 are positioned such that the turning radii from the shield axial center O are different from each other. Thus, the roller bits 31 can excavate and crush different turning regions. A center roller bit is provided on the center member 20, and a plurality of fixed bits 26 are provided on two sides of each main spoke member 21.
As shown in
A first embodiment of the bit replacing unit will be described with reference to
As shown in
As shown in
In the present embodiment, the in-and-out axis OP is parallel to the shield axial center O. The cutter head on which the roller bit 31 is provided has a front surface plate. The outer peripheral side of the front surface plate may be inclined or curved rearward. Further, the roller bit is provided so as to extend and retract substantially perpendicular (for example, 85° to 95°) to the front surface plate of the cutter head. Alternatively, the roller bit is provided so as to extend and retract while being tilted at a predetermined angle of, for example, about 45° to 85° relative to the front surface of the cutter head. In such cases, even when the in-and-out axis OP of the roller bit is positioned substantially perpendicular to the front surface plate of the cutter head, the in-and-out axis OP of the roller bit is not parallel to the shield axial center O but tilted at a predetermined angle relative to the shield axial center O.
Moreover, the opening for replacement 37 is formed in the direction of the tangent axis OE perpendicularly intersecting with the in-and-out axis OP and the radial axis OR. The opening for replacement 37 may be inclined at a predetermined angle relative to the tangent axis OE, for example, in a range of 15° forward to 60° rearward, as long as the roller bit 31 and a reactive force support block 44 can be extended and retracted, which will be described later, and the roller bit 31 and the reactive force support block 44 can be contained in the space of the main cutter spoke 21.
A cylindrical rotary valve 39 is placed in the valve containing portion 35 so as to freely rotate about the radial axis OR. The rotary valve 39 includes a cylindrical outer peripheral plate 39a and an expanding cylinder 39b which penetrates through the outer peripheral plate 39a in the diameter direction thereof to form an attachment/detachment path 38. The attachment/detachment path 38 has an elliptical cross-section whose longer diameter is formed along the tangent axis OE, and has a front surface opening communicated with the bit containing portion 34. Further, the attachment/detachment path 38 has a larger diameter than that of a soil removal path 49 of the reactive force support plug 32E. The rotary valve 39 is rotated to turn the attachment/detachment path 38 by 90° from a use position, so that the attachment/detachment path 38 can be communicated with the opening for replacement 37 while taking up a replacement position along the tangent axis OE.
Furthermore, in the present embodiment, the radial axis OR as the rotation center of the rotary valve 39 perpendicularly intersects with the in-and-out axis OP and the tangent axis OE. However, the radial axis OR may intersect with the shield axial center O and the tangent axis OE at about 90° (for example, 85° to 95°) to rotate the rotary valve 39.
(Bit Case and Reactive Force Support Block)
As shown in
As shown in
The reactive support block 44 includes a block body 45 with a large diameter which is fitted into the attachment/detachment path 38, and a guide cylinder 46 with a small diameter which protrudes from a reactive force receiving surface 45a on the front surface of the block body 45 and is slidably fitted into the soil removal path 42 of the bit case 41. The block body 45 and the guide cylinder 46 are cylindrically-shaped to have an elliptical cross-section, and a soil removal path 47 having an elliptical cross-section along the in-and-out axis OP penetrates through the block body 45 and the guide cylinder 46. Further, an arc-like reactive force transmission surface 45b is formed along the outer peripheral surface of the rotary valve 39 on the rear end surface of the block body 45.
Thus, as shown in
Reference numeral 48 in
(Valve Rotating Mechanism and Bit Extending/Retracting Mechanism)
As shown in
The valve rotating mechanism 51 includes: an arc-like internal gear rack 52 attached to the inner surface of the outer peripheral plate 39a of the rotary valve 39 within a predetermined range; a pinion 53 rotatably supported by the housing 32 via a supporting member and engaged with the internal gear rack 52; and a valve rotating handle 54 for rotating the pinion 53 via a driving mechanism with a wrapping connector 54a composed of a chain and a sprocket.
The bit extending/retracting mechanism 55 includes: the pair of cam rollers 43 protruding in the symmetric position of the bit case 41; guide holes 56 formed in an extending/retracting direction on the expanding cylinder 39b of the rotary valve 39 to guide the bases of the cam rollers 43; a pair of cam axes 57 for extension/retraction which is supported on the outer surface of the expanding cylinder 39b so as to freely rotate about an axis parallel to the in-and-out axis OP and has cam grooves 57a formed on the outer peripheral surfaces thereof, the cam grooves 57a being engaged with the leading ends of the cam rollers 43; and bit extending/retracting handles 58 for rotating the extending/retracting cam axes 57 via worm gears 58a, driving shafts 58b, and driving mechanisms with wrapping connectors 58c.
The bit extending/retracting mechanism 55 may be composed of a linear drive device such as a feed screw mechanism, a hydraulic cylinder, or an electric jack.
(Seal Structure)
As shown in
Specifically, a first sealing material 61 is provided on the outer periphery of the front end of the bit case 41. The first sealing material 61 stops water at a gap between the inner surface of the bit containing portion 34 of the housing 32 and the outer peripheral surface of the bit case 41 in an excavation position.
Second sealing materials 62A and 62B and third sealing materials 63A and 63B are provided on the rotary valve 39. The second sealing materials 62A and 62B are provided on the inner circumferential surface of the valve containing portion 35 so as to surround the opening surface and the rear opening surface of the valve containing portion 35 to seal a sliding gap between the inner circumferential surface of the valve containing portion 35 and the outer peripheral plate 39a of the rotary valve 39. The third sealing materials 63A and 63B are provided over the peripheries around two end surfaces of the outer peripheral plate 39a of the rotary valve 39 to seal the sliding gap between the outer peripheral plate 39a of the rotary valve 39 and the inner circumferential surface of the valve containing portion 35. Further, as shown in
Thus, when the bit case 41 is located at an excavation position, muddy water and pebbles with a small diameter, which are about to flow into the gap between the rotary valve 39 and the valve containing portion 35, are prevented by the first sealing material 61 from flowing into the bit containing portion 34. Moreover, the second sealing materials 62A and 62B and the third sealing materials 63A and 63B prevent water leakage into the workspace 28.
In the retraction position of the bit case 41, the first sealing material 61 seals a gap between the inner surface of the attachment/detachment path 38 and the bit case 41. The second sealing materials 62A and 62B and the third sealing materials 63A and 63B prevent water leakage from the gap between the rotary valve 39 and the valve containing portion 35 into the workspace 28. Even when the rotary valve 39 is turned by 90° from the use position to the replacement position, the second sealing materials 62A and 62B, the third sealing materials 63A and 63B, the fourth sealing material 64, and the fifth sealing material 65 prevent water leakage into the workspace 28.
(Replacement of Roller Bit)
The procedure for replacing the roller bit 31 in the above configuration will be described.
1) When the abraded roller bit 31 is replaced at an excavation position where the bit case 41 is contained in the bit containing portion 34, the cutter head 16 is stopped at a predetermined position, operators enter the workspace 28 in the main spoke member 21 from the manhole 27 to replace the roller bit 31.
2) After the pair of cotters 48 is removed from the cotter inserting holes 40, the bit extending/retracting handle 58 is operated to rotate the extending/retracting cam axis 57, so that the bit case 41 is retracted from the excavation position to the retraction position of the attachment/detachment path 38 via the cam rollers 43.
3) The valve rotating handle 54 is operated to turn the rotary valve 39 by 90° from the use position to the replacement position, thereby causing the rear opening of the attachment/detachment path 38 to face the opening for replacement 37.
4) The door for replacement 37a is opened, and an operating tool such as a jack is used to draw out the reactive force support block 44 in the direction of the tangent axis OE from the attachment/detachment path 38 to the workspace 28 via the opening for replacement 37. Next, the bit case 41 is retracted to the rear opening side, the cam rollers 43 are detached from the bit case 41 and removed from the guide holes 56, and then the bit case 41 is drawn out from the attachment/detachment path 38 to the workspace 28 through the opening for replacement 37.
5) The bit case 41 with another roller bit 31 mounted thereon is inserted into the attachment/detachment path 38 from the opening for replacement 37, the cam rollers 43 are attached to the bit case 41 and pushed into the inner side of the attachment/detachment path 38, and the cam rollers 43 are fitted into the guide holes 56 and engaged with the cam grooves 57a of the extending/retracting cam axes 57. Further, the reactive force support block 44 is fitted from the workspace 28 into the attachment/detachment path 38 via the opening for replacement 37.
6) After the door for replacement 37a is closed, the valve rotating handle 54 is operated to turn the rotary valve 39 by 90° from the replacement position to the use position to align the front opening of the attachment/detachment path 38 with the bit containing portion 34.
7) The bit extending/retracting handle 58 is operated to rotate the extending/retracting cam axes 57, the bit case 41 is moved from the retraction position of the attachment/detachment path 38 in the direction of the in-and-out axis OP via the cam rollers 43 so as to protrude into the bit containing portion 34, and stops at the excavation position. Further, the cotters 48 are inserted from the cotter inserting holes 40 and fitted between the rear surface of the bit case 41 and the reactive force receiving surface 45a of the reactive force support block 44 to fix the bit case 41.
According to the first embodiment, the bit case 41 contained in the attachment/detachment path 38 of the rotary valve 39 is moved so as to protrude into the bit containing portion 34 which opens at the front surface of the main cutter spoke 21, and is fixed to excavate soil. Thus, the sliding gap of the rotary valve 39 in the valve containing portion 35 is closed by the bit case 41, is not exposed to the front surface of the main cutter spoke 21, and is not directly subjected to the muddy water pressure of an excavated portion.
The first sealing material 61 surrounding the bit case 41 and the second sealing material 62A surrounding the front opening of the valve containing portion 35 favorably stop water at the sliding gaps. Thus, muddy water pressure is not directly applied to the sliding gap of the rotary valve 39 and fragments do not flow into the sliding gap. This enables the sliding gap between the rotary valve 39 and the valve containing portion 35 to be favorably sealed, thereby increasing sealing properties. Hence, the rotary valve 39 can be smoothly rotated.
The excavating reactive force transferred from the bit case 41 to the rear surface of the attachment/detachment path 38 via the cotters 48 can be supported by the reactive force support plug 32E of the housing 32 via the reactive force support block 44. Thus, a large excavating reactive force applied to the roller bit 31 can be effectively supported.
The reactive force support block 44 is removed from the attachment/detachment path 38 and the bit case 41 is then removed from the attachment/detachment path 38, so that the roller bit 31 can be easily replaced.
Soil excavated by the roller bit 31 can be smoothly discharged from the soil removal path 42 to the duct for soil removal 21D via the soil removal path 47 and the soil removal path 49, so that rocks and pebbles can be favorably crushed.
According to the modified example of the first embodiment, in addition to the effects of the first embodiment, the roller bit 31 can be further easily replaced only by removing the bit case 41.
A second embodiment of the bit replacing unit will be described with reference to
Bit replacing units 70 are disposed on left and right sides of a main cutter spoke 21, and a rotary valve 75 contained in a housing 71 is rotated about a tangent axis (rotary axis) OE to replace a roller bit 31 from above or below.
As shown in
As shown in
An opening for replacement 76 having an opening/closing door 76a is formed on one side in the direction of the radial axis OR (on the outer peripheral surface) [or on the other side (on the surface on the shield axial center O side)] of the housing 71.
As shown in
In the above configuration, as shown in
According to the second embodiment, the same effects as the first embodiment and the modified example can be produced. Further, multiple bit replacing units 70 can be disposed on the main cutter spoke 21, which is preferable to a large excavating machine.
Number | Date | Country | Kind |
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2010-017520 | Jan 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2010/072604 | 12/16/2010 | WO | 00 | 7/3/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2010/092964 | 8/4/2011 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4193637 | Spencer | Mar 1980 | A |
4234235 | Robbins et al. | Nov 1980 | A |
6347838 | Mukaidani et al. | Feb 2002 | B1 |
6382732 | Tanaka et al. | May 2002 | B1 |
Number | Date | Country |
---|---|---|
2000-096987 | Apr 2000 | JP |
3139749 | Dec 2000 | JP |
2002-276290 | Sep 2002 | JP |
2004-211477 | Jul 2004 | JP |
2004-218298 | Aug 2004 | JP |
4163965 | Aug 2008 | JP |
Entry |
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Int'l Search Report from corresponding Int'l Patent Application No. PCT/JP2010/072604, 2 Pages. |
Number | Date | Country | |
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20120274122 A1 | Nov 2012 | US |