JP5212830B2 - Clamping device - Google Patents

Description

  The present invention relates to a clamp device capable of clamping a workpiece via a clamp arm that rotates by a predetermined angle under the displacement action of a piston.

  Conventionally, for example, when a component such as an automobile is welded, a clamping device is used to clamp the component.

  The clamp device includes a main body, a clamp arm that rotates by a predetermined angle via a link mechanism provided in the main body, and a locating pin through which a workpiece positioning hole is inserted. Then, after positioning is performed by inserting a positioning hole provided in the workpiece into the locating pin, the rod disposed in the main body is displaced along the axial direction, thereby via a link mechanism connected to the rod. Thus, the clamp arm is rotated at a predetermined angle, and the workpiece is clamped according to the rotation direction.

  However, a workpiece to be clamped by such a clamping device may have positioning holes with different hole diameters depending on the type and application. In this case, since it becomes necessary to prepare a clamping device having a locating pin corresponding to the hole diameter of the positioning hole each time, a workpiece having positioning hole diameters of various hole diameters can be clamped by a single clamping device. It was desired.

  In order to meet such a demand, a clamping device that can handle a plurality of types of workpieces having different positioning hole diameters is known.

  In this clamp device, a cylindrical body is provided inside the cylindrical first body so as to be displaceable, and a locating pin is connected to an upper end portion of the cylindrical body, and a pressure fluid is connected to the other end portion of the cylindrical body. A first piston that is displaced in the axial direction is connected under the supply action. This locating pin is formed in a stepped shape from a small diameter portion provided at the tip end portion and a large diameter portion connected to the cylindrical body by expanding the diameter relative to the small diameter portion. In addition, a piston rod is inserted in the cylinder so as to be displaceable. A clamp arm is rotatably held at the upper end of the cylinder, and the other end is axially moved under pressure fluid. The displaced second piston is connected.

  And according to the hole diameter of the positioning hole of the workpiece, the first piston is pressed by the pressure fluid to be displaced in the vertical direction, and the locating pin is moved forward and backward to thereby move the large diameter portion or the small diameter portion corresponding to the positioning hole. The workpiece is positioned, and then the second piston is displaced under the pressure fluid supply action to rotate the clamp arm and clamp the workpiece.

JP 9-192968 A

  However, in the prior art according to Patent Document 1, the driving means for moving the locating pin forward and backward and the driving means for clamping the work by rotating the clamp arm are configured separately. There are problems that the structure becomes complicated and the clamp device is enlarged.

  Further, since the locate pin itself moves upward, there is a concern that the cross-sectional shape of the workpiece to be positioned is restricted.

  The present invention has been made in consideration of the above-described problems, and provides a clamping device capable of efficiently positioning a plurality of workpieces having positioning holes having different hole diameters with a simple configuration. The purpose is to do.

In order to achieve the above-described object, the present invention provides a clamp apparatus that converts a linear motion output from a drive unit into a rotational motion and clamps a workpiece via a clamp arm.
A main body having a placement portion on which the workpiece is placed;
A clamp arm supported rotatably with respect to the main body,
A first locating part that protrudes from the mounting part and through which a positioning hole formed in the workpiece is inserted;
A second locating portion provided inside the main body portion so as to be displaceable along the axial direction, and projecting to an outer peripheral side of the first locating portion at an end surface of the mounting portion;
A first displacement body, which is provided in the main body portion and is displaceable along an axial direction under a pressure fluid supply action and connected to the clamp arm; and a second displacement body coupled to the second locating portion. A drive unit having,
With
The first displacement body and the second displacement body are provided so as to be relatively displaceable.

  According to the present invention, the positioning hole of the work is inserted into the first locating part, and after placing the work on the placing part, the pressure fluid is supplied to the main body part to displace the first displacement body. Thus, the clamp arm is rotated with respect to the main body portion, and the workpiece positioned at the first locating portion is clamped. On the other hand, when clamping another workpiece having a different positioning hole diameter from that of the workpiece, the second displacement body is displaced using the pressure fluid, and the second locating portion is the outer periphery of the first locating portion. By projecting from the mounting portion on the side, another workpiece having a different hole diameter can be positioned by the second locating portion having a diameter larger than that of the first locating portion.

  Therefore, since the rotation operation of the clamp arm and the displacement operation of the second locating part can be performed together by a single drive unit, the configuration can be simplified compared with the conventional clamping device, Accordingly, the clamp device can be reduced in size. In addition, since a plurality of types of workpieces can be clamped with a single clamping device, it is not necessary to replace the clamping device for each workpiece, and work can be performed efficiently.

  And a displacement restricting means for restricting a displacement along the axial direction of the second locating part, wherein the displacement restricting means is capable of displacing the second locating part under the action of supplying the pressure fluid. It is preferable to switch between a state in which the displacement of the two locate portions is restricted.

  Furthermore, the first displacement body includes a piston that is pressed by a pressure fluid, and a piston rod that is coupled to the piston and rotatably supports the end of the clamp arm, and the second displacement body. The cylinder tube with the piston built therein, a head cover that closes one end of the cylinder tube, and a rod cover that closes the other end of the cylinder tube may be used.

  The second locating portion includes a plurality of pins provided on the same circle with respect to the center of the second displacement body, and the circumscribed circle of the plurality of pins has a diameter corresponding to the hole diameter of the positioning hole of the workpiece. It is good to set.

  According to the present invention, the following effects can be obtained.

  That is, since the rotation operation of the clamp arm and the displacement operation of the second locating unit can be performed together by a single driving unit, the configuration can be simplified compared with the conventional clamping device, The clamp device can be reduced in size.

It is an external appearance perspective view of the clamp device concerning this embodiment. It is a disassembled perspective view of the clamp apparatus shown in FIG. It is a top view of the clamp apparatus shown in FIG. It is a whole longitudinal cross-sectional view which shows the unclamped state of the clamp apparatus of FIG. 5A is a cross-sectional view taken along line VA-VA in FIG. 4, and FIG. 5B is a cross-sectional view taken along line VB-VB in FIG. It is an expansion perspective view which shows the cap vicinity in FIG. It is sectional drawing along the VII-VII line of FIG. FIG. 5 is an overall longitudinal sectional view showing a clamped state in which the clamping device of FIG. 4 grips a workpiece via a clamp arm. 9A is a cross-sectional view taken along line IXA-IXA in FIG. 8, and FIG. 9B is a cross-sectional view taken along line IXB-IXB in FIG. FIG. 8 is an overall longitudinal sectional view showing a state where the displacement restriction state of the locking shaft is released by the pressure fluid supplied to the switching port after the workpiece is taken out from the clamping device of FIG. 7. 11A is a cross-sectional view taken along the line XIA-XIA in FIG. 10, and FIG. 11B is a cross-sectional view taken along the line XIB-XIB in FIG. FIG. 12 is an overall longitudinal sectional view showing an unclamped state in which the sub-locating pin protrudes upward and the workpiece is positioned by the sub-locating pin in the clamping device of FIG. 11. 13A is a cross-sectional view taken along line XIIIA-XIIIA in FIG. 12, and FIG. 13B is a cross-sectional view taken along line XIIIB-XIIIB in FIG. It is an expansion perspective view which shows the cap vicinity in FIG. FIG. 8 is an enlarged cross-sectional view illustrating a state in which the sub-locate pin protrudes from a state in which the sub-locate pin illustrated in FIG. It is a whole longitudinal cross-sectional view which shows the clamped state which the clamp apparatus of FIG. 12 hold | gripped the workpiece | work via the clamp arm. 17A is a cross-sectional view taken along line XVIIA-XVIIA in FIG. 16, and FIG. 17B is a cross-sectional view taken along line XVIIB-XVIIB in FIG.

  Preferred embodiments of the clamping device according to the present invention will be described below and described in detail with reference to the accompanying drawings.

  In FIG. 1, reference numeral 10 indicates a clamping device according to an embodiment of the present invention.

  As shown in FIGS. 1 to 4, the clamp device 10 is provided inside a hollow cylindrical body (main body portion) 12 and the body 12, and is supplied with pressure fluid (for example, compressed air). A cylinder portion 16 having a piston 14 that is displaced to a position, a clamp portion 18 that is provided at the upper portion of the body 12 and can hold a workpiece W1 (see FIG. 4), and provided at the lower portion of the body 12, 16 and a lock switching mechanism (displacement restricting means) 24 capable of restricting displacement of the head cover 20 and the rod cover 22.

  In addition, the workpiece | work W1 hold | maintained by this clamp apparatus 10 is a panel for motor vehicles consisting of a board | plate material, for example, and the said clamp apparatus 10 is used for the manufacturing line which hold | maintains this motor vehicle panel and performs a welding operation.

  The body 12 has a first hole portion 26 having a circular cross section and penetrating along the axial direction, and a pair of first and second fluid ports 28 through which pressure fluid is supplied and discharged. , 30 are formed. The first and second fluid ports 28 and 30 respectively communicate with the first hole 26 and are connected to a pressure fluid supply source (not shown) via, for example, a tube and a switching valve (not shown). The first fluid port 28 is provided on the lower side of the body 12 (in the direction of arrow A), and the second fluid port 30 is provided on the upper side of the body 12 (in the direction of arrow B).

  That is, the pressure fluid is introduced into the first hole portion 26 via the first and second fluid ports 28 and 30, and the pressure fluid introduced into the first hole portion 26 is the first and second fluid ports. The fluid ports 28 and 30 are discharged to the outside. The first hole portion 26 penetrates along the axial direction of the body 12 (the directions of arrows A and B).

  The cylinder portion 16 is accommodated in the first hole portion 26 of the body 12 and has a cylindrical cylinder tube (second displacement body) 32 and a head cover (second displacement body) connected to the lower end portion of the cylinder tube 32. 20, a rod cover (second displacement body) 22 connected to the upper end portion of the cylinder tube 32, a piston (first displacement body) 14 that is displaceably provided inside the cylinder tube 32, and the piston 14 And a piston rod (first displacement body) 34 supported by the rod cover 22.

  The cylinder tube 32 is made of, for example, a tube material having a constant thickness, is formed with a small diameter with respect to the first hole portion 26 of the body 12, and is disposed coaxially with the first hole portion 26. The cylinder tube 32 is spaced from the inner peripheral surface of the first hole 26 by a predetermined distance, and a supply chamber to which pressure fluid is supplied between the outer peripheral surface and the inner peripheral surface of the first hole 26. 36 is formed. The supply chamber 36 is formed to be able to communicate with the second fluid port 30.

  The head cover 20 and the rod cover 22 are formed of a block body having a circular cross section, and are connected to each other in a straight line by fitting cylinder tubes 32 provided therebetween, and the first hole portion 26 of the body 12. Along the axis direction (arrow A, B direction).

  The head cover 20 is formed with a first communication passage 38 extending from the outer peripheral surface in the radial inward direction and then bent at a right angle toward the cylinder tube 32 (arrow B direction). The first communication path 38 is formed in an L-shaped cross section and communicates the outer peripheral surface and the end of the head cover 20 with each other.

  In addition, a concave portion that faces the opening of the first communication passage 38 and is recessed in the radially inward direction is formed in an annular shape on the outer peripheral surface of the head cover 20, and a pair of first seal members 40 are formed at the ends of the concave portion. It is provided and is in sliding contact with the inner peripheral surface of the first hole portion 26. The pair of first seal members 40 blocks the flow of the pressure fluid between the first hole portion 26 of the body 12 and the first communication path 38.

  A lock shaft 100 of a lock switching mechanism 24 described later is connected to the lower end portion of the head cover 20.

  On the other hand, the rod cover 22 has a rod hole 42 through which the piston rod 34 is inserted at the center, and an annular rod packing 44 provided inside is in sliding contact with the outer peripheral surface of the piston rod 34. The rod cover 22 is formed with a second communication passage 46 that extends radially inward from the outer peripheral surface thereof and then bends at a right angle toward the cylinder tube 32 (arrow A direction). . Further, the outer peripheral surface of the rod cover 22 is formed such that a portion facing the opening of the second communication passage 46 is cut away in the radial inward direction so that the second communication passage 46 and the supply chamber 36 communicate with each other. .

  In other words, the seal member is not provided between the opening of the second communication passage 46 and the cylinder tube 32 on the outer peripheral surface of the rod cover 22, and the pressure fluid supplied to the supply chamber 36 is always the first. The pressure fluid supplied to the second communication passage 46 can also be introduced into the supply chamber 36 at the same time.

  On the outer peripheral surface of the rod cover 22, an annular second seal member 48 is provided above the opening of the second communication passage 46, and is in sliding contact with the inner peripheral surface of the first hole 26 in the body 12. The leakage of the pressure fluid to the upper side (arrow B direction) side from the second communication path 46 is prevented.

  In addition, a plurality of (for example, four) connecting rods 50 extending in a direction away from the cylinder tube 32 (in the direction of arrow B) are connected to the upper end surface of the rod cover 22. The connecting rod 50 is provided on the same circle provided radially outward with respect to the center of the rod cover 22, and the end of the connecting rod 50 is substantially parallel to the end surface of the rod cover 22 and has a predetermined interval. A disk-shaped plate 52 is connected at a distance.

  The plate 52 is formed with an arm hole 54 having a rectangular cross section through which a clamp arm 66 (described later) is inserted at the center, and a plurality of (for example, four) sub-locating pins (second locating portion) on the upper surface thereof. ) 56 is provided so as to protrude upward (in the direction of arrow B). The sub-locating pin 56 is formed at the same height with respect to the plate 52, and its tip is formed in a hemispherical shape. Further, the sub-locating pins 56 are arranged on the same circumference in the plate 52 so as to be spaced apart from each other at equal intervals.

  The piston 14 is formed in a disc shape, and an annular piston packing 58 mounted on the outer peripheral surface thereof is provided so as to be in sliding contact with the inner peripheral surface of the cylinder tube 32, and a piston rod 34 is formed in a hole penetrating in the center thereof. One end of each is inserted and crimped integrally. As a result, the piston 14 is connected to one end of the piston rod 34. In the cylinder tube 32, a first cylinder chamber 60 is formed between the piston 14 and the head cover 20, and a second cylinder chamber 62 is formed between the rod cover 22.

  The piston rod 34 is inserted into the rod hole 42 of the rod cover 22 and is inserted into the sub body 64 constituting the clamp portion 18. Further, an arm holding portion 68 that is bifurcated and can hold the clamp arm 66 so as to be rotatable is formed at the other end of the piston rod 34. A pin hole 72 (see FIG. 2) through which a support pin 70 for rotatably supporting the clamp arm 66 is passed through the arm holding portion 68 in a direction orthogonal to the axis of the piston rod 34. The other end of the piston rod 34 is disposed so as to protrude from the end of the rod cover 22 and be surrounded by the connecting rod 50 (see FIG. 2).

  That is, in the cylinder portion 16 described above, the head cover 20 including the piston 14 and the piston rod 34, the rod cover 22 and the cylinder tube 32 are provided to be displaceable along the inside of the body 12, and the piston 14 and the piston rod 34 are provided. The cylinder tube 32, the head cover 20 and the rod cover 22 are provided so as to be relatively displaceable.

  The clamp portion 18 is provided in the sub body 64 connected to the upper portion of the body 12, a cap 74 attached to the upper portion of the sub body 64, the sub body 64 and the cap 74, and rotates under the displacement action of the piston 14. And a clamp arm 66 that moves. The clamp portion 18 is connected to each other by a plurality of bolts 76 a inserted through the cap 74 being screwed into the sub body 64.

  The sub body 64 is formed in a cylindrical shape having a second hole 78 at the center, and is coaxially connected to the upper portion of the body 12. The second hole 78 communicates with the first hole 26 of the body 12. The other end of the piston rod 34 is inserted into the second hole 78, and a clamp arm 66 connected to the piston rod 34 is provided. It is inserted.

  The cap 74 is provided so as to close the upper portion of the sub body 64, and a main body portion 80 projecting in a columnar shape upward and projecting at a predetermined height with respect to the main body portion 80. The locating portion (first locating portion) 82 is provided, and a slit hole 84 through which a part of the clamp arm 66 can be exposed to the outside is provided on the side surface of the locating portion 82. The slit hole 84 is formed at a predetermined height from the end surface of the main body 80 along the axial direction of the cap 74 (the directions of arrows A and B).

  A plurality of (for example, four) locate pin holes 86 are formed in the main body portion 80 on the same circumference that is slightly larger than the outer diameter of the locate portion 82 with the locate portion 82 as the center (see FIG. 3). ). The locating pin hole 86 is formed so as to be spaced apart from each other at equal intervals around the locating portion 82 and penetrates to the inside of the cap 74, and the locating portion 82 has a portion facing above the locating pin hole 86 facing upward. It is cut out.

  In addition, the locating pin hole 86 is formed on the same circumference as the sub locating pin 56 provided in the plate 52 constituting the cylinder portion 16, and is formed so that the sub locating pin 56 can be inserted.

  The locate portion 82 is formed so as to be gradually reduced in diameter in the direction away from the main body portion 80 (the direction of arrow B), and the tip portion thereof is formed in a spherical shape. For example, when the locating portion 82 holds a workpiece W1 such as an automobile panel, the positioning of the workpiece W1 is performed by inserting a positioning hole C1 provided in the workpiece W1.

  The clamp arm 66 has a predetermined length along the longitudinal direction, and one end of the clamp arm 66 is inserted into the arm holding portion 68 of the piston rod 34 inside the sub body 64, and is inserted into the pin hole 72 of the sub body 64 and the piston rod 34. By inserting the inserted support pin 70, the support pin 70 is rotatably supported. On the other hand, a claw portion 88 bent at a right angle to the longitudinal direction of the clamp arm 66 is provided at the other end portion of the clamp arm 66, and the claw portion 88 is slit when the clamp arm 66 is rotated. Projecting outward from the hole 84, the workpiece W <b> 1 can be held between the main body 80.

  Further, a substantially central portion along the longitudinal direction of the clamp arm 66 has a first groove portion substantially parallel to the longitudinal direction of the clamp arm 66 and a second groove joined to the lower portion of the first groove portion and bent at a predetermined angle. A link groove 94 composed of a groove is formed. The link pin 96 is inserted into the link groove 94 in a state where the clamp arm 66 is disposed inside the sub body 64.

  The lock switching mechanism 24 is connected to the lower end portion of the body 12, and is provided inside the housing 98, and is a lock shaft that can be displaced along the axial direction (arrow A and B directions) together with the cylinder portion 16. 100, first and second chucks 102, 104 capable of regulating displacement of the locking shaft 100, and switching capable of switching displacement regulating states of the locking shaft 100 by the first and second chucks 102, 104 Piston 106.

  The housing 98 is provided on the first housing 108 having a switching port 124 to which pressure fluid is supplied, the second housing 110 connected to the upper part of the first housing 108, and the upper part of the second housing 110, And a connection plate 112 coupled to the lower end of the body 12.

  A plurality of bolts 76b (see FIG. 2) inserted from below the first housing 108 are screwed into the sub body 64 in the clamp portion 18 through the second housing 110, the connection plate 112, and the body 12, thereby The housing 98 and the body 12 are connected to the lower part of the clamp part 18.

  A shaft hole 114 through which the locking shaft 100 is inserted is formed in the center of the first housing 108, the second housing 110, and the connection plate 112 along the axial direction (arrow A, B direction). A piston hole 116 through which the switching piston 106 is inserted is formed along the axial direction (directions of arrows A and B) at positions spaced apart from each other by a predetermined distance toward the switching port 124 described later. The shaft hole 114 and the piston hole 116 are provided substantially in parallel, and the shaft hole 114 is formed with a large diameter with respect to the piston hole 116. The shaft hole 114 and the piston hole 116 are formed so as to penetrate the connection plate 112, the first housing 108 and the second housing 110.

  A pair of shaft holes 120 into which the pair of support shafts 118 are inserted are formed at positions closer to the switching port 124 side than the piston holes 116. The shaft hole 120 penetrates from the connecting plate 112 to the second housing 110 through the first housing 108 in a straight line, and is spaced at a predetermined interval in a direction orthogonal to the line segment connecting the centers of the shaft hole 114 and the piston hole 116. Provided. A support shaft 118 inserted into the shaft hole 120 supports first and second chucks 102 and 104, which will be described later, in a freely openable / closable manner, and the connection plate 112, the first housing 108, and the second housing through the shaft hole 120. 110 is penetrated.

  The first housing 108 is formed of a block body having a storage chamber 122 that opens upward. The storage chamber 122 is closed by a second housing 110 provided on the upper portion of the first housing 108. The pair of first chucks 102 are arranged in a substantially horizontal direction.

  A switching port 124 to which pressure fluid is supplied opens on the side surface of the first housing 108, and the switching port 124 communicates with the piston hole 116. Then, the pressure fluid supplied from the pressure fluid source is supplied into the piston hole 116 through the switching port 124.

  The first chuck 102 is formed in a plate shape having a rectangular cross section and is arranged in parallel inside the storage chamber 122. At one end along the longitudinal direction of the first chuck 102, a support shaft 118 is inserted through a hole. The support shaft 118 is rotatably provided by a predetermined angle with the support shaft 118 as a fulcrum. Further, on one side surface in the longitudinal direction of the first chuck 102, a first gripping portion 126 with which the switching piston 106 abuts and a second gripping portion 128 with which the locking shaft 100 abuts are formed. The pair of first chucks 102 are disposed so that the first and second gripping portions 126 and 128 face each other.

  The first gripping portion 126 is formed on one end portion side of the first chuck 102, is slightly depressed with respect to one side surface of the first chuck 102, and is formed in a planar shape parallel to the one side surface.

  The second grip 128 is provided on the other end of the first housing 108 with a predetermined distance from the first grip 126, and is further recessed with respect to the first grip 126. It is formed in a shape. In the housing chamber 122, the switching piston 106 and the locking shaft 100 are disposed so as to be between the pair of first chucks 102, and the switching piston 106 is held by the pair of first gripping portions 126. The outer peripheral surface of the locking shaft 100 is held by the pair of second grips 128 (see FIG. 5B).

  In other words, the first grip 126 is formed at a position facing the switching piston 106 provided in the first housing 108, while the second grip 128 is a locking shaft that is inserted into the first housing 108. It is formed at a position facing 100.

  On the other hand, on the other side surface of the first chuck 102 along the longitudinal direction, a spring receiving portion 130 that is slightly depressed toward the first gripping portion 126 side is formed, and the spring receiving portion 130 and the inner wall surface of the accommodating chamber 122 are formed. Springs 132 are interposed between the two. The spring 132 is formed of, for example, a coil spring, and is disposed so as to be orthogonal to the inner wall surface of the housing chamber 122. One end of the first chuck 102 is supported on one end side supported by the support shaft 118. The urging force is applied in the direction of approaching each other.

  Similar to the first housing 108, the second housing 110 is formed with a storage chamber 134 having a substantially rectangular cross section and opening upward. The storage chamber 134 is formed by a connection plate 112 provided on the upper portion thereof. Blocked. In addition, a pair of second chucks 104 are disposed in a substantially horizontal direction inside the storage chamber 134.

  The second chuck 104 is formed in substantially the same shape as the first chuck 102, and is formed in a plate shape having a rectangular cross section, like the first chuck 102, and is disposed substantially parallel to the inside of the storage chamber 134.

  A support shaft 118 is inserted into one end portion of the second chuck 104 along the longitudinal direction through a hole, and is rotatably provided by a predetermined angle with the support shaft 118 as a fulcrum. Further, on one side surface along the longitudinal direction of the second chuck 104, a first gripping portion 136 with which the switching piston 106 abuts and a second gripping portion 138 with which the locking shaft 100 abuts are formed. Note that one and the other of the second chuck 104 are disposed so that the first and second gripping portions 136 and 138 face each other.

  The first holding part 136 is slightly recessed with respect to one side surface of the second housing 110 and is formed in a planar shape parallel to the one side surface. The second grip 138 is provided on the other end side of the second housing 110 at a predetermined interval with respect to the first grip 136 and is a semicircular cross section that is further recessed with respect to the first grip 136. It is formed in a shape. That is, the switching piston 106 and the locking shaft 100 are disposed so as to be between the pair of second chucks 104, and the switching piston 106 is held by the pair of first gripping portions 136 and the locking shaft 100 is An outer peripheral surface is hold | maintained by a pair of 2nd holding part 138 (refer FIG. 5A).

  In other words, the first gripping part 136 is formed at a position facing the switching piston 106 provided in the first and second housings 108 and 110, while the second gripping part 138 is formed of the first and second housings. It is formed at a position facing the locking shaft 100 inserted through 108 and 110.

  On the other hand, on the other side surface of the second chuck 104 along the longitudinal direction, spring receiving portions 140 that are slightly depressed toward the first gripping portion 136 are formed, respectively. A pair of springs 142 are interposed between the wall surfaces. The spring 142 is formed of, for example, a coil spring, and is disposed so as to be orthogonal to the inner wall surface of the storage chamber 134, and one end side of the second chuck 104 is supported by the support shaft 118. The urging force is applied in the direction of approaching each other.

  The switching piston 106 is formed of a shaft body having the same diameter, and is provided so as to straddle the first and second housings 108 and 110 and the connection plate 112 via the piston hole 116, and is displaced along the piston hole 116. While being provided freely, it is inserted so that it may be clamped by the 1st holding parts 126 and 136 in the 1st and 2nd chuck | zipper 102,104.

  A lower end portion of the switching piston 106 is provided inside the first housing 108, and an annular seal member 144 is attached to the outer peripheral surface thereof. The seal member 144 is in sliding contact with the inner peripheral surface of the piston hole 116, whereby leakage of the pressure fluid supplied from the switching port 124 to the piston hole 116 is prevented. That is, it is avoided that the pressure fluid flows in the piston hole 116 toward the second housing 110 and the connection plate 112 (arrow B direction).

  Then, the switching piston 106 is pushed upward by the pressure fluid introduced into the switching port 124 and displaced.

  Further, on the outer peripheral surface of the switching piston 106, first and second recesses 146 and 148 that are substantially rectangular and recessed to a certain depth are formed at positions that are symmetrical about the axis of the switching piston 106. The first recess 146 is formed on the lower end side (arrow A direction) of the switching piston 106, and the second recess 148 is formed at a position spaced apart from the first recess 146 upward (arrow B direction) by a predetermined interval. The Under the first and second recesses 146 and 148, taper portions 150a and 150b are respectively formed so as to be gradually shallower downward (in the direction of arrow A) and joined to the outer peripheral surface. .

  That is, the switching piston 106 is formed such that the portion where the first and second recesses 146 and 148 are formed is narrower than the portion where the first and second recesses 146 and 148 are not provided. Has been.

  The switching piston 106 is arranged such that the first and second recesses 146 and 148 face the springs 132 and 142 provided in the storage chambers 122 and 134, respectively (see FIGS. 5A and 5B). Specifically, the first recess 146 is disposed so as to face the first grip portion 126 in the first chuck 102, and the second recess 148 is disposed so as to face the first grip portion 136 in the second chuck 104. Yes.

  The locking shaft 100 is screwed into the central portion of the lower end surface of the head cover 20, protrudes downward with a predetermined length with respect to the lower end surface, and the shaft hole 114 of the connection plate 112, the first and second housings 108, 110. Is inserted. The locking shaft 100 is provided coaxially with the piston 14 and the piston rod 34.

  The locking shaft 100 includes a large-diameter portion 152 and a set of small-diameter portions 154 whose diameter is reduced inward in the radial direction with respect to the large-diameter portion 152. A large-diameter portion 152 is formed so as to be adjacent to the small-diameter portion 154 at a predetermined interval along the axial direction. In other words, the locking shaft 100 is formed such that the small-diameter portions 154 and the large-diameter portions 152 are alternately arranged along the axial direction (arrows A and B directions). Specifically, a large diameter portion 152 is formed at the lower end portion of the locking shaft 100, and a small diameter portion 154, a large diameter portion 152, a small diameter portion 154, and a large diameter portion 152 are formed in this order upward. .

  The locking shaft 100 is provided so as to face the second gripping portions 128 and 138 of the first and second chucks 102 and 104 when inserted into the shaft hole 114.

  The clamp device 10 according to the embodiment of the present invention is basically configured as described above. Next, the operation and effects thereof will be described.

  First, the clamping device 10 is fixed at a predetermined position via a fixing means (not shown), and a pipe (not shown) connected to a pressure fluid supply source is connected to the first and second fluid ports 28 and 30 and the switching port 124. Connect each one. 4 shows the clamping device 10 in an unclamped state, and FIG. 8 shows the clamping device 10 in an unclamped state. Hereinafter, the above-described unclamped state will be described as an initial state.

  In this initial state, as shown in FIG. 4, the pressure fluid is supplied from the first fluid port 28 into the first cylinder chamber 60, and the second fluid port 30 and the switching port 124 are opened to the atmosphere. Therefore, the piston 14 is displaced upward (in the direction of arrow B) under the pressure action of the pressure fluid and is in contact with the end surface of the rod cover 22, and the locking shaft 100 is lowered together with the head cover 20. The small diameter portion 154 is gripped by the second chuck 104 (see FIG. 5A), the large diameter portion 152 is gripped by the first chuck 102 (see FIG. 5B), the head cover 20 including the locking shaft 100, the cylinder tube 32 and the rod cover 22 are in a state where displacement is restricted in a lowered state.

  In the clamping device 10 in the initial state shown in FIG. 4, the work W <b> 1 is transported by a transport device or the like (not shown), and the work W <b> 1 is a main body portion of the cap 74 so that the positioning hole of the work W <b> 1 is inserted into the locate portion 82. 80 (see the two-dot chain line shape in FIGS. 4 and 6). In this case, since the sub-locating pin 56 is lowered together with the head cover 20, the cylinder tube 32 and the rod cover 22, the sub locating pin 56 is accommodated inside the cap 74 without protruding from the main body 80 of the cap 74. It is in a state (see FIG. 7).

  After the placement of the workpiece W1 is confirmed, the pressure fluid supplied from the pressure fluid supply source to the first fluid port 28 is supplied to the second fluid port 30 under the switching action of a not-shown switching valve. The first fluid port 28 is opened to the atmosphere. In this case as well, the switching port 124 is in the atmosphere open state.

  As shown in FIG. 8, the pressure fluid supplied to the second fluid port 30 is supplied to the supply chamber 36 and supplied to the inside of the second cylinder chamber 62 through the second communication passage 46 of the rod cover 22. As a result, the piston 14 is pressed downward (in the direction of arrow A) by the pressure fluid. As a result, the clamp arm 66 connected to the piston rod 34 is pulled downward, and the clamp arm 66 is inserted into the link groove 94 so that the link pin 96 is inserted along the link pin 96. It moves from the second groove to the first groove. As a result, the clamp arm 66 rotates counterclockwise by a predetermined angle with the portion pivotally supported by the support pin 70 as a fulcrum, and the claw portion 88 of the clamp arm 66 protrudes to the outside through the slit hole 84 and the main body portion 80. And the workpiece W1 is clamped.

  In this case, since the pressure fluid is not supplied to the switching port 124 in the lock switching mechanism 24, the lock shaft 100 is held by the first and second chucks 102 and 104 as shown in FIGS. 9A and 9B. Since the displacement of the locking shaft 100 is regulated without changing the state, the head cover 20, the rod cover 22 and the cylinder tube 32 are not displaced along the inside of the body 12, and the sub-locating pin 56 is still housed in the cap 74.

  Then, with the workpiece W1 positioned and clamped by the clamping device 10, for example, a welding operation for an automotive panel which is the workpiece W1 is performed.

  Next, when the clamp arm 66 is rotated again from the clamped state described above to switch to the unclamped state where the clamped state of the workpiece W1 is released, the second fluid port 30 is operated under the switching action of a switching valve (not shown). Is supplied to the first fluid port 28, and the second fluid port 30 is opened to the atmosphere.

  As a result, the piston 14 and the piston rod 34 are lifted by the pressure fluid supplied to the first cylinder chamber 60, and accordingly, the clamp arm 66 rotates clockwise with one end portion supported by the support pin 70 as a fulcrum. To do. As a result, the claw portion 88 of the clamp arm 66 is separated from the work W1, and the gripping state of the work W1 held between the claw portion 88 and the main body 80 is released (FIG. 4). reference). Since the claw portion 88 is accommodated in the cap 74 through the slit hole 84 of the locating portion 82 under the rotating action of the clamp arm 66, it becomes a hindrance when taking out the workpiece W1 upward by a conveying device (not shown). There is nothing.

  Next, a case where another work W2 having a positioning hole C2 having a larger diameter than that of the work W1 described above is clamped by the clamp device 10 will be described. In this case, the unclamped state shown in FIG. 4 will be described as an initial state.

  In this initial state, as shown in FIG. 10, first, by supplying the pressure fluid to the switching port 124, the switching piston 106 rises, and the pair of second chucks 104 have their first gripping portions. From the state in which the second recess 148 is inserted between the first recesses 136 (see FIG. 9A), the taper portions 150a and 150b that gradually become wider with respect to the second recess 148 are inserted (see FIG. 11A). ). As a result, the second chuck 104 rotates with the support shaft 118 as a fulcrum so that the other end is separated from the springs 132 and 142 against the elastic force of the springs 132 and 142. An open state in which the gripping state 100 is released is obtained. As a result, the head cover 20, the rod cover 22, and the cylinder tube 32 by the second chuck 104 become displaceable along the inside of the body 12 by the pressing force of the pressure fluid. In other words, the displacement restriction state for the head cover 20, the rod cover 22, and the cylinder tube 32 by the lock switching mechanism 24 is released.

  Thereafter, pressure fluid is supplied from a pressure fluid supply source (not shown) to the second fluid port 30, and the pressure fluid is introduced into the second cylinder chamber 62, so that the piston 14 is pressed by the pressure fluid. The clamp arm 66 is displaced downward (in the direction of arrow A), the clamp arm 66 rotates counterclockwise with the support pin 70 as a fulcrum under the link action of the link groove 94, and the claw portion 88 projects from the slit hole 84. It becomes.

  The piston 14 is in a state in which further downward displacement is restricted because the clamp arm 66 is in the clamped state, and by continuing to supply the pressure fluid to the second cylinder chamber 62 in this state, the pressure is reduced. The rod cover 22 is pressed upward (in the direction of arrow B) by the fluid, and the head cover 20, the cylinder tube 32, and the rod cover 22 are integrally raised. As a result, the sub-locating pin 56 rises, and the tip of the sub-locating pin 56 protrudes at a predetermined height from the upper surface of the main body 80 through the locating pin hole 86 of the cap 74 (see FIGS. 12, 14, and 15). .

  In the state where the sub-locating pin 56 protrudes from the main body 80, the supply of the pressure fluid supplied to the switching port 124 is stopped. As a result, the upward pressing force urged by the switching piston 106 is extinguished, so that the first and second chucks 102 and 104 use the support shaft 118 as a fulcrum under the elastic action of the springs 132 and 142. The switching piston 106 is pushed down by the second gripping portions 128 and 138 through the tapered portions 150a and 150b.

  The small diameter portion 154 of the locking shaft 100 is gripped by the second gripping portion 128 of the first chuck 102, and displacement along the axial direction of the locking shaft 100 is regulated (see FIG. 11B). Therefore, the sub locate pin 56 is held in a state of protruding from the main body 80. At this time, the second chuck 104 holds the large-diameter portion 152 of the locking shaft 100 by the second holding portion 138 (see FIG. 11A).

  Then, as described above, with the sub-locating pin 56 protruding to the outer peripheral side of the locating portion 82, as shown in FIG. 12, the pressure fluid supplied to the second fluid port 30 is changed to the first fluid port 28. And the second fluid port 30 is opened to the atmosphere, whereby the piston 14 is raised and the clamp arm 66 is rotated in the clockwise direction. That is, it becomes a preparation state in which another workpiece W2 having the large-diameter positioning hole C2 can be placed on the cap 74.

  Next, in this preparatory state, another workpiece W2 is conveyed by a conveying device or the like (not shown), and the positioning hole C2 of the other workpiece W2 is located on the locating portion 82 and on the radially outer side of the locating portion 82. The workpiece W2 is lowered so as to be inserted into the pin 56, and placed on the upper surface of the main body 80 in the cap 74 (see the two-dot chain line shape in FIGS. 12, 14, and 15).

  As shown in FIGS. 14 and 15, the workpiece W2 is set so that the diameter of the positioning hole C2 is substantially the same as the circumscribed circle D (see FIG. 3) composed of the plurality of sublocate pins 56. Therefore, the positioning hole C2 of the workpiece W2 is positioned by the sub-locating pin 56.

  Then, as shown in FIG. 16, after the positioning and placement of the workpiece W2 is confirmed, the pressure fluid that has been supplied from the pressure fluid supply source to the first fluid port 28 under the switching action of the switching valve (not shown). Is supplied to the second fluid port 30 and the first fluid port 28 is opened to the atmosphere. Also in this case, the switching port 124 is opened to the atmosphere.

  The pressure fluid supplied to the second fluid port 30 is supplied to the inside of the second cylinder chamber 62, and the piston 14 is pressed downward (in the direction of arrow A) by the pressure fluid, whereby the piston rod 34 The connected clamp arm 66 is pulled downward, and the clamp arm 66 is rotated counterclockwise by a predetermined angle via the link groove 94 through which the link pin 96 is inserted. Another workpiece W2 is gripped in the meantime.

  In this case, since the pressure fluid is not supplied to the switching port 124 in the lock switching mechanism 24, the lock shaft 100 is held by the first and second chucks 102 and 104 as shown in FIGS. 17A and 17B. Since the displacement of the locking shaft 100 is regulated without changing the state, the head cover 20, the rod cover 22 and the cylinder tube 32 are not displaced along the inside of the body 12, and the sub-locating pin 56 is still housed in the cap 74.

  Finally, when the clamp arm 66 is rotated again from the clamped state described above to release the clamp of another workpiece W2, the pressure fluid supplied to the second fluid port 30 is changed to the first fluid. While supplying the fluid port 28, the second fluid port 30 is opened to the atmosphere.

  As a result, the piston 14 and the piston rod 34 are lifted by the pressure fluid supplied to the first cylinder chamber 60, and accordingly, the clamp arm 66 rotates clockwise with one end portion supported by the support pin 70 as a fulcrum. To do. As a result, the claw portion 88 of the clamp arm 66 is separated from the workpiece W2, and the gripping state of the workpiece W2 held between the claw portion 88 and the main body portion 80 is released and the unclamped state is achieved. Another work W2 is taken out upward and conveyed by the apparatus or the like.

  Further, when the sub-locating pin 56 is lowered again and the workpiece W1 having the small-diameter positioning hole C1 is clamped only by the locating portion 82 provided in the cap 74, pressure fluid is supplied to the switching port 124. By raising the switching piston 106, the first and second chucks 102, 104 are opened against the elastic force of the springs 132, 142, and the displacement regulating state of the locking shaft 100 by the lock switching mechanism 24 is released. .

  After that, by supplying the pressure fluid to the first fluid port 28, the piston 14 is not displaced because the clamp arm 66 is in the unclamped state, so that the pressure fluid introduced into the first cylinder chamber 60 The head cover 20 is pressed downward together with the cylinder tube 32 and the rod cover 22 to be displaced. As a result, the sub-locating pin 56 is accommodated inside the cap 74 through the locating pin hole 86, and the locking shaft 100 lowered together with the head cover 20 stops supplying the pressure fluid to the switching port 124, thereby reducing the small diameter portion. The second chuck 104 facing 154 is closed under the elastic action of the spring 142, and the second grip portion 138 grips the small diameter portion 154 of the locking shaft 100.

  Thereby, the displacement along the axial direction of the locking shaft 100 is regulated by the second chuck 104 constituting the lock switching mechanism 24, and the sub-locating pin 56 is lowered and held in the cap 74. The

  As described above, in the present embodiment, by supplying the pressure fluid to the first and second fluid ports 28 and 30, the piston 14 is displaced along the inside of the cylinder tube 32 and is held by the piston rod 34. The clamp arm 66 is rotated so that the clamped / unclamped state of the workpieces W1 and W2 can be switched, and the head cover 20, the rod cover 22 and the cylinder tube 32 constituting the cylinder portion 16 are made available using the pressure fluid. By displacing along the inside of the body 12 and projecting / accommodating the sub-locating pin 56 provided on the upper portion thereof with respect to the cap 74, the workpieces W1 and W2 positioned by the sub-locating pin 56 together with the locating portion 82 are stored. This can correspond to the positioning hole diameter.

  That is, with a simple configuration, the clamp arm 66 is rotated by the pressure fluid supplied to the cylinder portion 16, and the sub-locating pin 56 is moved up and down, so that a plurality of positioning holes C1 and C2 having different hole diameters are provided. The types of workpieces W1 and W2 can be clamped, and the size of the clamping device 10 can be reduced.

  Further, the complicated work of replacing the clamping device 10 each time corresponding to the workpieces W1 and W2 having different hole diameters is not required, and the workpieces W1 and W2 can be efficiently clamped to perform operations such as welding. .

  Further, since the locating portion 82 provided on the cap 74 is not lifted or lowered, the workpieces W1 and W2 having various shapes can be positioned and clamped.

  Further, since the lock switching mechanism 24 is provided, it is possible to prevent the head cover 20, the rod cover 22, and the cylinder tube 32 from being displaced accidentally even when no pressure fluid is supplied to the switching port 124. Therefore, it is possible to fix the sub-locating pin 56 that is raised and lowered according to the positioning hole diameters of the workpieces W1 and W2, and to prevent the sub-locating pin 56 from being raised and lowered by mistake.

  The clamping device according to the present invention is not limited to the above-described embodiment, and can of course take various configurations without departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 10 ... Clamp apparatus 12 ... Body 14 ... Piston 16 ... Cylinder part 18 ... Clamp part 20 ... Head cover 22 ... Rod cover 24 ... Lock switching mechanism 26 ... 1st hole 28 ... 1st fluid port 30 ... 2nd fluid port 32 ... Cylinder tube 34 ... Piston rod 36 ... Supply chamber 56 ... Sublocate pin 60 ... First cylinder chamber 62 ... Second cylinder chamber 64 ... Subbody 66 ... Clamp arm 74 ... Cap 80 ... Main body part 82 ... Locate part 98 ... Housing 100 ... Shaft for locking 102 ... first chuck 104 ... second chuck 106 ... switching piston 124 ... switching port 126,136 ... first gripping portion 128,138 ... second gripping portion 132,142 ... spring 146 ... first recess 148 ... first 2 concave portions 150a, 150b ... tapered portion 152 ... large diameter portion 15 ... the small-diameter portion

Claims (3)

In the clamp device that converts the linear motion output from the drive unit into a rotational motion and clamps the workpiece via the clamp arm,
A main body having a placement portion on which the workpiece is placed;
A clamp arm supported rotatably with respect to the main body,
A first locating part that protrudes from the mounting part and through which a positioning hole formed in the workpiece is inserted;
A second locating portion provided inside the main body portion so as to be displaceable along the axial direction, and projecting to an outer peripheral side of the first locating portion at an end surface of the mounting portion;
A first displacement body, which is provided in the main body portion and is displaceable along an axial direction under a pressure fluid supply action and connected to the clamp arm; and a second displacement body coupled to the second locating portion. A drive unit having,
With
The first displacement body includes a piston pressed by the pressure fluid, and a piston rod connected to the piston and rotatably supporting an end of the clamp arm, and the second displacement body is And a cylinder cover in which the piston is housed, a head cover that closes one end of the cylinder tube, and a rod cover that closes the other end of the cylinder tube, and the first displacement body and the second displacement body. Is provided so as to be relatively displaceable. The clamping device according to claim 1,
Displacement restricting means for restricting displacement along the axial direction of the second locating part, the displacement restricting means being capable of displacing the second locating part under the action of supplying the pressure fluid; A clamp device that switches between a state in which the displacement of the locate portion is restricted. The clamping device according to claim 1 or 2 ,
The second locating portion includes a plurality of pins provided on the same circle with respect to the center of the second displacement body, and a circumscribed circle of the plurality of pins has a diameter corresponding to a hole diameter of the positioning hole of the workpiece. A clamping device characterized by being set by

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