The present invention relates to a clamping apparatus for fixing a movable member such as a work pallet or a work to a reference block such as a table of a machine tool, and further relates to a clamping system using this clamping apparatus.
This kind of clamping apparatus is conventionally described in Patent Document 1 for example. The clamping apparatus presented in the Patent Document 1 is constituted in such a way that a plurality of rotary clamps are arranged around a work placed on a work pallet, and clamping member of the rotary clamps press the work from above.
Patent Document 1: U.S. Pat. No. 5,820,118
However, the clamping apparatus described in the Patent Document 1 has problems that since the plurality of rotary clamps are arranged around the work, it is difficult to machine side surfaces of the work, further that an upper surface of the work cannot be machined at the pressing points of the clamping members.
It is an object of the present invention to provide a new clamping apparatus which does not obstruct accessing (namely, machining/utilizing) each surface of a movable member such as a work and a work pallet, and a clamping system using the clamping apparatus.
The problems to be solved by the present invention are as described above, next, explanation for means for solving the problems and effects thereof will be made.
[1] In order to accomplish the objective mentioned above, a first aspect of the present invention is constituted as follows, for example as illustrated in
A guide hole 20 into which a plug portion 3 of a movable member 2 is allowed to be inserted is opened in a leading end portion of a reference block 1. An outer engaging member 21 is arranged inside the guide hole 20. An inner engaging member (31, 72) which is diametrically expandable and diametrically contractible is arranged inside the outer engaging member 21, the inner engaging member (31, 72) is axially wedge-engaged with the outer engaging member 21, and the inner engaging member (31, 72) which is in the wedge-engaged state is adapted to be movable for locking toward a base end and in such a direction as to contract diametrically. An output member 36 is inserted into the reference block 1 axially movably, and the output member 36 is connected to either one of the inner engaging member (31, 72) and the outer engaging member 21. The output member 36 is allowed to be connected to a drive means D.
It is noted that both an automatic drive means using an actuator such as a fluid pressure cylinder or an electric motor and a human-powered drive means can be employed as the drive means D.
The first aspect of the present invention operates as follows, for example as illustrated in
In a release state illustrated in
To fix the movable member 2 on the reference block 1, the plug portion 3 is fitted inside the inner engaging member 31, and then the output member 36 is moved toward the base end (downward) by the drive means D, by which the inner engaging member 31 and the outer engaging member 21 are wedge-engaged with each other.
Then, first, the inner engaging member 31 (72) diametrically contracts via the outer engaging member 21, and the inner engaging member 31 comes into contact with an outer peripheral surface of the plug portion 3. Successively, when the movement of the inner engaging member 31 toward the base end is blocked, the inner engaging member 31 strongly wedge-engages with the outer engaging member 21 and diametrically contracts, and the inner engaging member 31 comes into strong and close contact with the outer peripheral surface of the plug portion 3. Thereby, as illustrated in
It is noted that, in a case that the support surface 1a of the reference block 1 and the supported surface 2a of the movable member 2 has been in substantially perfect contact with each other and the supported surface 2a has been received by the support surface 1a before the locking movement mentioned above, the inner engaging member 31 (72) operates as follows during the locking movement.
After coming into close contact with the outer peripheral surface of the plug portion 3, the inner engaging member 31 moves toward the base end while sliding with respect to the plug portion 3 of the movable member 2 received by the reference block 1. Then, as described above, when the movement of the inner engaging member 31 toward the base end is blocked, the inner engaging member 31 comes into strong and close contact with the outer peripheral surface of the plug portion 3, and this inner engaging member 31 strongly presses the movable member 2 toward the reference block 1.
On the other hand, in a case that a gap is left between the support surface 1a of the reference block 1 and the supported surface 2a of the movable member 2 at the start of the locking movement for some reason, the inner engaging member 31 (72) operates as follows during the locking movement.
After coming into close contact with the outer peripheral surface of the plug portion 3, the inner engaging member 31 in the close contact state moves the movable member 2 toward the reference block 1 via the plug portion 3, and bring the supported surface 2a into contact with the support surface 1a. Then, as described above, when the movement of the inner engaging member 31 toward the base end is blocked, the inner engaging member 31 comes into strong and close contact with the outer peripheral surface of the plug portion 3, and the inner engaging member 31 strongly presses the movable member 2 toward the reference block 1.
The first aspect of the present invention is constituted and operates as described above, so that the first aspect of the present invention exhibits the following effect.
It becomes easier to access five surfaces other than the supported surface among six surfaces of the movable member. Therefore, for example, in a case that the movable member is a work, five surfaces can be simultaneously machined by one clamping operation. In addition, in a case that the movable member is a work pallet, the effective use area of the work pallet can be significantly increased.
[2] According to a second aspect of the present invention, in the first aspect of the present invention, as illustrated in
[3] According to a third aspect of the present invention, in the first aspect of the present invention, as illustrated in
Namely, a plurality of pressing members 72 arranged circumferentially at intervals are employed as the inner engaging member. An annular socket 71 into which the plug portion 3 is allowed to be inserted is arranged inside the outer engaging member 21. Each of the pressing members 72 is supported on a peripheral wall of the annular socket 71 radially movably, and each of the pressing members 72 is adapted to be movable radially outward by a return means 74. The output member 36 is connected to either one (71, 21) of the annular socket 71 and the outer engaging member 21.
With this structure, the pressing members can be greatly projected radially inward, so that even when fitting gaps between inside surfaces of the pressing members and the outer peripheral surface of the plug portion are large, proper clamping operation can be performed.
[4] According to a fourth aspect of the present invention, in the first aspect of the present invention, as illustrated in
[5] According to a fifth aspect of the present invention, in the first aspect of the present invention, as illustrated in
[6] According to a sixth aspect of the present invention, in the first aspect of the present invention, as illustrated in
[7] According to a seventh aspect of the present invention, in the first aspect of the present invention, as illustrated in
[8] According to an eighth aspect of the present invention, in the first aspect of the present invention, as illustrated in
[9] According to a ninth aspect of the present invention, in the first aspect of the present invention, as illustrated in
[10] According to a tenth aspect of the present invention, in the first aspect of the present invention, as illustrated in
[11] According to an eleventh aspect of the present invention, in the first aspect of the present invention, as illustrated in
[12] According to a twelfth aspect of the present invention, in the first aspect of the present invention, as illustrated in
[13] According to a thirteenth aspect of the present invention, in the first aspect of the present invention, as illustrated in
[14] According to a fourteenth aspect of the present invention, in the second aspect of the present invention, as illustrated in
[15] A fifteenth aspect of the present invention relates to a new clamping system using the clamping apparatus of the second aspect of the present invention, and is constructed as follows as illustrated in
Two of the plug portions 3, 3 are provided at a predetermined interval on the movable member 2. The reference block 1 is provided with a first socket means 11 and a second socket means 12 corresponding to the plug portions 3, 3. Each of the socket means 11 and 12 includes the guide hole 20, the outer engaging member 21 and the inner sleeve 31. The first socket means 11 is constituted in such a way that substantially the entire circumference of an outer peripheral surface of the outer engaging member 21 is allowed to come into close contact with an inner peripheral surface 24 of the guide hole 20. The second socket means 12 is constituted in such a way that a pair of projections 62, 62 radially facing each other are provided on at least any of an inner periphery of the guide hole 20, an outer periphery or an inner periphery of the outer engaging member 21 and an outer periphery or an inner periphery of the inner sleeve 31, and escape grooves 63, 63 are formed between the projections 62, 62.
In the clamping system constructed as described above, a mechanically simple structure that can accurately position and fix the movable member with respect to the reference block can be obtained.
[16] A sixteenth aspect of the present invention relates to a new clamping system using the clamping apparatus of the third aspect of the present invention, and is constructed as follows as illustrated in
Two of the plug portions 3, 3 are provided at a predetermined interval on the movable member 2. The reference block 1 is provided with a first socket means 11 and a second socket means 12 corresponding to the plug portions 3, 3. Each of the socket means 11 and 12 includes the guide hole 20, the outer engaging member 21, the annular socket 71 and the plurality of pressing members 72. The first socket means 11 is constituted in such a way that substantially the entire circumference of an outer peripheral surface of the outer engaging member 21 is allowed to come into close contact with an inner peripheral surface 24 of the guide hole 20 and that three or more of the pressing members 72 are arranged circumferentially at intervals. The second socket means 12 is constituted in such a way that two of the pressing members 72 are arranged so as to radially face each other.
In the clamping system constructed as described above, a mechanically simple structure that can accurately position and fix the movable member with respect to the reference block can be obtained.
[17 and 18] According to a seventeenth aspect of the present invention, in the fifteenth aspect of the present invention, and according to an eighteenth aspect of the present invention, in the sixteenth aspect of the present invention, as illustrated in
[19] According to a nineteenth aspect of the present invention, in the seventeenth aspect of the present invention, as illustrated in
[20] According to a twentieth aspect of the present invention, in the eighteenth aspect of the present invention, the third socket means 13 includes the guide hole 20, the outer engaging member 21 and the plurality of pressing members 72, and the outer engaging member 21 is attached to the guide hole 20 radially movably. In this case, absorbing axial misalignment between the axis of the plug portion and the axis of the guide hole by radial movements of both the outer engaging member and the pressing members can be consistent with securing a strong locking force.
[21] According to a twenty-first aspect of the present invention, in the seventeenth aspect of the present invention as illustrated in
[22] According to a twenty-second aspect of the present invention, in the eighteenth aspect of the present invention, the third socket means 13 includes the guide hole 20, the outer engaging member 21 and the plurality of pressing members 72, and the inner peripheral surface 24 of the guide hole 20 is allowed to move radially with respect to the reference block 1. With this structure, absorbing axial misalignment between the axis of the plug portion and the axis of the guide hole by radial movements of the inner peripheral surface of the guide hole can be consistent with securing a strong locking force.
Explanation for a first embodiment of the present invention will be made with reference to
As illustrated in
The reference block 1 is provided with a base plate 4, and this base plate 4 is fixed to the table T. This base plate 4 is provided with both a first socket means 11 and a second socket means 12 which have a positioning function and a locking function, and is provided with two third socket means 13, 13 which have only a locking function. These socket means 11, 12, 13 and 13 correspond to the plug portions 3. Each of the four socket means 11, 12, 13 and 13 serves as a clamping apparatus respectively, and the four socket means 11, 12, 13 and 13 are arranged so as to form vertexes of a rectangle in a plan view as illustrated in
Among these socket means, as illustrated in
As illustrated in
The third socket means 13, 13 are constituted in such a way that the inner sleeve 31 is allowed to move radially with respect to the guide holes 20 described later, and therefore, the third socket means 13, 13 do not have the horizontally positioning function mentioned above.
The first socket means 11 and the second socket means 12 have substantially the same structure except for some different points described later, and the common structure are described as follows. Namely, as illustrated in
As illustrated in
In addition, as illustrated in
The diameter of the outer sleeve 21 is set to be slightly smaller than the diameter of the inner peripheral surface 24 of the guide hole 20 in a usual/normal state (the released state of
As illustrated in
Inside the outer sleeve 21 is arranged the inner sleeve (inner engaging member) 31 into which the plug portion 3 is allowed to be inserted. A tapered outer surface of the inner sleeve 31 has made a tapering engagement (wedge engagement) with a tapered inner surface of the outer sleeve 21 from above. Both the tapered outer surface and the tapered inner surface are formed in such a manner as to gradually narrow downward.
The inner sleeve 31 as well as the outer sleeve 21 is formed in a collet shape. Namely, in a peripheral wall of the inner sleeve 31 is formed one slit 32 extending vertically (see
The inner sleeve 31 is diametrically expanded in a usual/normal state (the release state of
It is noted that, as illustrated in
As illustrated in
A cylindrical extending portion 42 extending downward from the inner sleeve 31 is inserted into the piston 38. On an outer peripheral surface of a lower end portion of the extending portion 42 is attached a retaining ring 44. This retaining ring 44 is inserted into an annular output groove 41 formed between the piston 38 and the cover 39.
Inside the housing 15 are provided both a lock means 51 and a release means 52 as a drive means D, namely, the drive means D includes both the lock means 51 and the release means 52. The lock means 51 is composed of both the piston 38 and a lock chamber 53 formed above the piston 38. The lock chamber 53 is communicatively connected to a pressurized oil supply/discharge port 54 provided for locking. The release means 52 is composed of both the piston 38 and a release chamber 56 formed below the piston 38. The release chamber 56 is communicatively connected to a pressurized oil supply/discharge port 57 provided for releasing.
In one of the three support surfaces 1a (see
As illustrated in
The positioning mechanism 11a of the first socket means 11 is constructed in such a way that, as illustrated in
Next, explanation for differences between the positioning mechanism 12a of the second socket means 12 and the positioning mechanism 11a of the first socket means 11 will be made as follows with reference to
Namely, as illustrated in
It is noted that, as illustrated in
Herein, the projections 62, 62 may be projected from the inner peripheral surface 24 of the guide hole 20 inward, instead of being projected from the outer peripheral surface of the outer sleeve 21. Furthermore, it is also possible that the projections 62, 62 are projected from an inner peripheral surface of the outer sleeve 21 inward, projected from an outer peripheral surface of the inner sleeve 31 outward, or projected from the inner peripheral surface of the inner sleeve 31 inward.
Next, explanation for differences between the positioning mechanism 13a of the third socket means 13 and the positioning mechanism 11a of the first socket means 11 will be made as follows with reference to
As illustrated in
Both this radial gap 64 and the radial gap 65 allow both the inner sleeve 31 and the outer sleeve 21 to move radially with respect to the guide hole 20, by which axial misalignment between the axis of the plug portion 3 and the axis of the guide hole 20 can be absorbed.
It is noted that, in the second socket means 12 and the third socket means 13, for the sake of smooth radial movement of the outer sleeve 21 when absorbing the axial misalignment, it is preferable that a contact gap is provided on an upper side of the outer sleeve 21 in a state that the outer sleeve 21 is raised by the coned disc spring 25.
The first socket means 11, the second socket means 12 and the third socket means 13 operates in substantially the same manner as follows.
In a release state of
To position the work pallet 2 on the reference block 1, first, the work pallet 2 is lowered in the release state mentioned above, the plug portions 3 are fitted into the inner sleeve 31, resulting in a state of
Then, the pressurized oil in the release chamber 56 is discharged and pressurized oil is supplied to the lock chamber 53. Then the piston 38 lowers the inner sleeve 31 via the output groove 41, the retaining ring 44 and the extending portion 42, and the tapered outer surface of the inner sleeve 31 makes a wedge engagement with the tapered inner surface of the outer sleeve 21.
Then, the inner sleeve 31 diametrically contracts via the outer sleeve 21 held at substantially a raised position by urging force of the coned disc spring 25, and the inner sleeve 31 comes into contact with the outer peripheral surface of the plug portion 3. Next, the inner sleeve 31 diametrically contracts while compressing the coned disc spring 25 downward via the outer sleeve 21 and comes into close contact with the outer peripheral surface of the plug portion 3. The outer sleeve 21 diametrically expands and comes into close contact with the inner peripheral surface 24 of the guide hole 20. Therefore, the inner sleeve 31 positions the work pallet 2 horizontally via both the outer sleeve 21 and the inner peripheral surfaces 24 of the guide holes 20. Simultaneously, the inner sleeve 31 makes the outer sleeve 21 retreat downward against the urging force of the coned disc spring 25. When the retreating outer sleeve 21 descends by a distance corresponding to the advancing stroke, the coned disc spring 25 comes into contact with the annular projection 85, and the outer sleeve 21 is received by the housing 15 via the coned disc spring 25. Then, the inner sleeve 31 strongly makes a wedge engagement with the received outer sleeve 21 and diametrically contracts, and the inner sleeve 31 comes into strong and close contact with the outer peripheral surface of the plug portion 3 (the state of
It is noted that in a case that the support surface 1a and the supported surface 2a has been in substantially perfect contact with each other and the supported surface 2a has been received by the support surfaces 1a before the locking movement, the inner sleeve 31 operates as follows during the locking movement.
After coming into close contact with the outer peripheral surface of the plug portion 3, the inner sleeve 31 descends while sliding with respect to the plug portion 3. And, as described above, when the outer sleeve 21 compresses the coned disc spring 25 and descends by the advancing stroke, the inner sleeve 31 comes into strong and close contact with the outer peripheral surface of the plug portion 3, and the inner sleeve 31 strongly presses the work pallet 2 toward the reference block 1.
On the other hand, in a case that a gap is left between the support surface 1a and the supported surface 2a for some reason at the start of the locking movement, the inner sleeve 31 operates as described below during the locking movement.
After coming into close contact with the outer peripheral surface of the plug portion 3, the inner sleeve 31 which is in close contact pulls the work pallet 2 downward via the plug portion 3, and brings the supported surface 2a into contact with the support surface 1a. And, as described above, when the outer sleeve 21 compresses the coned disc spring 25 and descends by the advancing stroke, the inner sleeve 31 comes into strong and close contact with the outer peripheral surface of the plug portion 3, and the inner sleeve 31 strongly presses the work pallet 2 toward the reference block 1.
It is noted that, simultaneously with the operation of the first socket means 11 and the second socket means 12, the two third socket means 13, 13 having only the locking function strongly fix the work pallet 2 on the reference block 1 via the inner sleeve 31.
Meanwhile, to switch the state of the clamping apparatus from the locked state (
The first embodiment can be changed, for example, as follows.
(1) The inner peripheral surface (surface to be brought into close contact with the outer peripheral surface of the plug portion 3) of the inner sleeve 31 may be formed in a serrated shape or in an uneven shape instead of the vertically straight shape.
(2) Each of the outer sleeve 21 and the inner sleeve 31 that are diametrically expandable and diametrically contractible may be provided with a plurality of through grooves opened alternately on an upper surface and a lower surface of its peripheral wall and the plurality of through grooves are arranged in the circumferential direction instead of being provided with the one slit 22, 32 in its peripheral wall. Each of the outer sleeve 21 and the inner sleeve 31 may also be constituted with a plurality of divided members arranged in the circumferential direction.
(3) The inner surface of the outer sleeve 21 may be formed with a plurality of inclined wedge surfaces arranged circumferentially at predetermined intervals instead of the illustrated tapered surface. In this case, it is also possible that a plurality of inclined grooves are arranged circumferentially at predetermined intervals on the inner surface of the outer sleeve 21 and bottom surfaces of the inclined grooves may form the wedge surfaces. The outer surface of the inner sleeve 31 may also be formed with a plurality of inclined wedge surfaces arranged circumferentially at predetermined intervals instead of the illustrated tapered surface.
(4) The outer sleeve 21 and the inner sleeve 31 may be indirectly engaged with each other via another member instead of directly engaging with each other.
(5) The structure of the third socket means 13 may employ the structure illustrated in the exemplified variation of
With the above mentioned structure, a radial frictional force acting on the outer sleeve 21 is reduced, thereby, it is possible to move both the inner sleeve 31 and the outer sleeve 21 radially smoothly during the absorbing operation for the axial misalignment between the axis of the plug portion 3 and the axis of the guide hole 20. It is a matter of course that the structure of
Next, explanation for a plurality of embodiments and exemplified variations of the present invention will be made with reference to
The first socket means 11 of the second embodiment is different from the first embodiment in the following points.
Namely, in place of the inner sleeve 31 which is diametrically expandable and diametrically contractible as described in the first embodiment (
Each of the pressing members 72 is adapted to move radially outward by a return means 74 (see
The return means 74 may also be constituted as an exemplified variation of
In the exemplified variation shown in
The operation of the second embodiment is different from that of the first embodiment in that, during the locking operation, each of the pressing members 72 supported on the annular socket 71 projects radially inward and an inner surface of each of the pressing members 72 comes into strong and close contact with the outer peripheral surface of the plug portion 3.
The second embodiment can be changed for example as follows.
(1) The pressing members 72 may be indirectly engaged with the inner surface of the outer sleeve 21 via other members instead of directly engaging with the inner surface. The pressing members 72 may be provided in two, four or more instead of three as illustrated.
(2) The inner surface of the pressing member 72 may be formed in a serrated shape or in an uneven shape instead of the vertically straight shape.
(3) It is desirable that discharge ports for cleaning fluid are formed by fitting gaps between the annular socket 71 and the pressing members 72, and are communicatively connected to the blow port 60 formed in the reference block 1. In this case, the fitting gaps can be automatically cleaned, so that the pressing members can smoothly move with high degree of accuracy.
(4) The advancing means may be a plurality of coned disc springs vertically laminated, compression coil spring or rubber instead of the illustrated one coned disc spring 25.
(5) The advancing means is only required to have a function to press the outer sleeve 21 with predetermined force, and instead of (or in addition to) using the elastic member such as the coned disc spring 25, for example, as illustrated in the exemplified variation of
An annular pressing portion 79 is integrally formed in a projecting manner from an upper surface of the advancing piston 78. The pressure of the pressurized oil supplied to the lock chamber 53 is adapted to press the outer sleeve 21 upward via the advancing piston 78 and the annular pressing portion 79.
Instead of forming the annular pressing portion 79 integrally with the advancing piston 78, it is also possible that another member such as a pin is arranged between the advancing piston 78 and the outer sleeve 21, and the advancing piston 78 indirectly presses the outer sleeve 21 via the pin or the like.
In this third embodiment, the plug portion 3 formed in a long shape is positioned at two points on a leading end side of the plug portion and a base end side of the plug portion.
Hereinafter, concrete explanation for the third embodiment will be made. Namely, as illustrated in
Inside the extending portion 42 of the inner sleeve 31 is fitted a second sleeve 84. The second sleeve 84 is formed in a collet shape, and in its peripheral wall is formed one slit 88 extending vertically. As a result, the second sleeve 84 is adapted to be diametrically expandable and diametrically contractible.
The second sleeve 84 is provided so as to project downward from the extending portion 42, and an inner peripheral surface of the projecting portion is adapted to come into close contact with an outer peripheral surface of a leading end side of the plug portion 3, meanwhile, a tapered outer surface is formed on an outer peripheral surface of the projecting portion. On the other hand, on an inner peripheral surface of the axial hole 82 of the closing cover 81 is formed a tapered inner surface, and the tapered outer surface of the second sleeve 84 is adapted to wedge-engage with this inner surface from above.
The second sleeve 84 is usually urged downward by a coil spring-shaped urging spring 86 arranged inside the extending portion 42. However, the second sleeve 84 is prevented from moving downward by more than a predetermined distance by means of a second retaining ring 87 fitted inside the extending portion 42.
With this structure, when the pressurized oil in the release chamber 56 is discharged and pressurized oil is supplied to the lock chamber 53, a base end side of the plug portion 3 is positioned horizontally by the inner sleeve 31 in completely the same manner as the first embodiment. Simultaneously, the inner peripheral surface of the second sleeve 84 comes into close contact with the outer peripheral surface of the leading end side of the plug portion 3 pulled downward by the inner sleeve 31 which is in close contact with the plug portion 3, and the second sleeve 84 is pulled downward due to friction between the second sleeve 84 and the plug portion 3. Simultaneously, due to aligning action based on wedge-engagement between the tapered outer surface of the second sleeve 84 and the tapered inner surface of the axial hole 82, the leading end side of the plug portion 3 is positioned horizontally. As described above, the long-shaped plug portion 3 is adapted to be positioned at the two ends, which are the leading end and the base end thereof.
In this fourth embodiment, as illustrated in
At a lower position of the output member 36, a closing cover 81 is fitted to the cylindrical hole 37. In this closing cover 81 is formed an axial hole 82 in which an urging spring 25 described later can be accommodated. Between the closing cover 81 and the output member 36 is formed the release chamber 56. This release chamber 56 is communicatively connected to the pressurized oil supply/discharge port 57 via a communication hole 83 penetrating the closing cover 81 vertically.
Below the inner sleeve 31 is arranged a spring support member 89, and between this spring support member 89 and a bottom surface of the axial hole 82 is elastically provided a coil spring-shaped urging spring 25. As a result, the inner sleeve 31 is urged upward.
From an upper surface of the piston 38 as the output member 36 is integrally projected an annular extending cylindrical portion 93. On an inner peripheral surface of a leading end of the extending cylindrical portion 93 is formed a narrow portion, and to the narrow portion is connected a lower end of the outer sleeve 21 via a retaining ring 44.
It is noted that
As illustrated in this
In the third socket means 13, as well as the third socket means of the first embodiment, the peripheral wall of the outer sleeve 21 is circumferentially formed in a seamless manner without any slit (
In this fifth embodiment, a spring support member 89 is arranged below the annular socket 71 in the same manner as the fourth embodiment, and this spring support member 89 is urged upward by the urging spring 25.
On the annular socket 71 are supported a plurality of pressing members 72, and the pressing members 72 are wedge-engaged with the outer sleeve 21 from below. Namely, the tapered inner surface of the outer sleeve 21 and tapered outer surfaces formed on the pressing members 72 are formed so as to gradually narrow upward.
It is noted that, in this fifth embodiment, as illustrated in
In this sixth embodiment, as illustrated in
With this structure, as illustrated in
It is noted that the elastic resistance force when the outer sleeve 21 is diametrically expanded corresponds to the urging force of the coned disc spring (advancing means). Therefore, in this sixth embodiment, the advancing means such as the coned disc spring is omitted. When the outer sleeve 21 elastically deforms in the diametrically expanding direction and the annular gap 92 completely disappears, the outer sleeve 21 is received by the housing 15 (in detail, by the inner peripheral surface 24 of the guide hole 20), and the inner sleeve 31 comes into strong and close contact with the outer peripheral surface of the plug portion 3 while diametrically contracting.
The positioning mechanism 12a of the second socket means 12 is different from the positioning mechanism 11a of the first socket means 11 in that the projections 62, 62 and escape grooves 63, 63 are provided on the outer peripheral surface of the outer sleeve 21. In the released state, as illustrated in
In this third socket means 13, outside the outer sleeve 21 is arranged an intermediate sleeve 94. Between this intermediate sleeve 94 and an inner peripheral surface of a hole of the housing 15 for accommodating the intermediate sleeve 94 is formed an appropriate gap. Due to this gap, the intermediate sleeve 94 is allowed to move radially. Between the outer sleeve 21 and the intermediate sleeve 94 is formed the annular gap 92. The inner sleeve 31 is wedge-engaged with the outer sleeve 21 from above.
In the third socket means 13 of this sixth embodiment, the inner peripheral surface of the intermediate sleeve 94 serves as the inner peripheral surface 24 of the guide hole 20. Therefore, according to radial movements of the intermediate sleeve 94, the inner peripheral surface 24 of the guide hole 20 is allowed to move radially. As a result, radial misalignment between the axis of the plug portion 3 and the axis of the guide hole 20 can be absorbed by radial movements of the intermediate sleeve 94.
It is noted that the structure including this intermediate sleeve 94 can be used for the aforementioned various third socket means. For example, in the third socket means shown in the first embodiment (
In this mode, a rubber ring as a resistance means 96 is attached to an outer periphery of the outer sleeve 21. This resistance means 96 is adapted to increase resistance force when the outer sleeve 21 is diametrically expanded.
It is noted that plastic or metal can be employed as the resistance means 96, instead of the illustrated rubber. This resistance means 96 can be attached to an inner periphery of the guide hole 20 instead of (or in addition to) being attached to the outer periphery of the outer sleeve 21.
This seventh embodiment is an exemplified variation of the fifth embodiment (
[Changed Modes]
The first through seventh embodiments and various exemplified variations of the present invention are shown above, and the present invention can be further changed as follows and carried out.
(1) In the clamping system, the number of socket means 13 having only a locking function may be only one instead of the illustrated two (
(2) The drive methods of the socket means 11, 12 and 13 are all hydraulic double-acting methods in the embodiments described above, however, instead of these, a spring-lock and hydraulic-release method or a hydraulic-lock and spring-release method may also be employed. The pressurized fluid to be used for locking or releasing may be gas such as compressed air in place of the exemplified pressurized oil. The pressurized fluid supplied for cleaning (fluid to be supplied to the blow port 60) may be gas such as nitrogen or may be liquid such as cutting oil in place of the exemplified compressed air.
(3) In this clamping system, it is possible that a plurality of third socket means 13 described above are provided and a plurality of second socket means 12 described above are provided. Furthermore, it is also possible that either the first socket means 11 or the second socket means 12 is provided in plural while the other is not provided at all. The direction of arranging the plurality of socket means may be circumferential or straight.
(4) The support surfaces 1a may be provided on the base plate 4 instead of being provided on the upper surface of the flange 16 of the housing 15.
(5) The guide hole 20 is formed integrally with the housing 15, however, instead of this, the guide hole 20 may be formed in another member fixed to the housing 15.
(6) In addition, the housing 15 and the base plate 4 may be formed integrally with each other instead of being formed separately from each other.
(7) The combination of the reference block and the movable member may be a combination of a table of a machine tool and a work pallet, a combination of a work pallet and a jig base, a combination of a jig base and a work piece or a combination of a working jig such as a welding jig and a working article such as a work piece instead of the illustrated combination of the base plate 4 and the work pallet 2. The present invention can also be applied to the positioning of work piece, tools and the like of various kinds of processing machines such as laser processing machines and electric discharge processing machines.
(8) It is noted that, it is a matter of course that the clamping apparatus of the present invention can be used in one set instead of a plurality of sets as presented.
Number | Date | Country | Kind |
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2003-299560 | Aug 2003 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP04/11471 | 8/10/2004 | WO | 2/22/2006 |