JP2004268187A - Clamp device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a clamp device for surely performing clamp operation even if a manufacturing tolerance is relieved on a constitution for rotating an output rod by a prescribed angle. <P>SOLUTION: This clamp device 1 has a nut member 5 relatively movably fitted around the output rod 3, a rod operation regulating mechanism 9 for regulating advancing-retreating operation of the output rod 3 when rotating the output rod 3, and regulating rotary operation of the output rod 3 when advancing-retreating the output rod 3, and a rotation regulating mechanism 10 for regulating rotation of the nut member 5 to a clamp body 2. The rotation regulating mechanism 10 has a first groove part formed in the nut member 5, a second groove part continuing with the upper end of this first groove part, and having a groove width larger than the first groove part, and a rotation regulating member 10 for engaging with the first groove part in rotary operation of the output rod 3, and engaging with the second groove part in advancing-retreating operation of the output rod 3. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a clamping device, and more particularly, to a device for rotating an output rod by a predetermined angle and then driving the output rod to a clamping side to clamp a workpiece such as a workpiece.
[0002]
2. Description of the Related Art Conventionally, there are various types of clamp devices for fixing an object to be clamped such as a workpiece to be machined. Among them, there is an output rod which is attached to a clamp body so as to be movable forward and backward. Then, at the time of clamping, the output rod is rotated by a predetermined angle to rotate the clamp arm connected to the distal end of the output rod, and then the output rod is driven backward to clamp the object to be clamped via the clamp arm. Some are configured to do so. In such a clamp device, since the clamp arm can pivotally move between a position retracted from the clamp target and a position for clamping the clamp target, when the clamp target is set, the clamp target moves with the clamp arm. Does not interfere.
[0003]
Regarding this type of clamp device, the present applicant has already proposed the following clamp device (for example, see Patent Document 1). The clamp device includes a nut member externally fitted to the output rod, a ball screw mechanism for converting a relative movement of the nut member with respect to the output rod into a rotation operation of the output rod, and a plurality of spheres fixedly provided on the clamp body. And a plurality of arc grooves and a plurality of longitudinal grooves provided on the output rod and capable of engaging the plurality of spheres. During the rotation of the output rod, the plurality of spheres engage with the plurality of arc grooves, respectively, thereby restricting the advance / retreat operation of the output rod. And the rotation of the output rod is regulated.
[0004]
By the way, the nut member is provided with a sphere that regulates the rotation of the nut member, and the clamp body is formed with an engagement groove that is parallel to the advance and retreat direction of the output rod and engages the sphere. Then, at the time of clamping, the nut member moves relative to the output rod in a state where the sphere is engaged with the engagement groove and the rotation of the nut member is restricted, and further, the relative movement is performed by the ball screw mechanism. This is converted into a rotation operation, and the output rod is surely rotated by a predetermined angle. Further, after the output rod rotates by a predetermined angle, a plurality of spheres engage with the plurality of vertical grooves of the output rod to restrict the rotation operation of the output rod, and allow the output rod to advance and retreat, and The rod is retracted by a predetermined stroke, and the object to be clamped is clamped.
[0005]
[Patent Document 1] Japanese Patent Application Laid-Open No. 2002-187036 (Pages 3-6, FIGS. 1-6)
[0006]
In the clamping device disclosed in Patent Document 1, the sphere provided on the nut member is engaged with the engaging groove of the clamp body to restrict the rotation of the nut member. In this state, in order to restrict the rotation of the output rod when the output rod moves forward and backward, a plurality of spheres provided on the clamp body need to be respectively engaged with a plurality of vertical grooves provided on the output rod. However, if the circumferential positions (phases) of the plurality of vertical grooves and the plurality of spheres are slightly shifted in a state where the output rod is rotated by a predetermined angle due to a manufacturing error of the engagement groove or the plurality of vertical grooves, a plurality of When the sphere engages with a plurality of vertical grooves, the clamping force forces the sphere into the vertical groove, causing large friction between the sphere and the vertical groove, and the clamping force acting on the object to be clamped. May be reduced. That is, it is necessary to strictly control a manufacturing error relating to a configuration for rotating the output rod by a predetermined angle, such as an engagement groove or a vertical groove, which is disadvantageous in manufacturing cost.
[0007]
SUMMARY OF THE INVENTION An object of the present invention is to provide a clamping device capable of performing a reliable clamping operation even if a manufacturing tolerance for a configuration for rotating an output rod by a predetermined angle is relaxed.
[0008]
According to a first aspect of the present invention, there is provided a clamp apparatus having a clamp body and an output rod mounted on the clamp body so as to be capable of moving forward and backward. A clamp device configured to drive and return the output rod to the advance direction when the clamp is released, and to reversely rotate the output rod by the predetermined angle after the drive, and the output rod is disposed within the clamp body so as to be relatively movable in the advance / retreat direction of the output rod. A nut member externally movably fitted to the nut member, a clamp driving means capable of driving the nut member in the retreating direction, and a nut member capable of driving the nut member in the advancing direction to release the clamped state by the clamp driving means. Conversion means for converting the relative movement of the nut member with respect to the output rod into a rotation operation of the output rod. A rod operation regulating mechanism that regulates the forward / backward movement of the output rod when the output rod rotates, and regulates the rotational movement of the output rod when the output rod moves forward and backward, and a rotation that regulates the rotation of the nut member with respect to the clamp body. A rotation control mechanism, wherein the rotation restriction mechanism is connected to a first groove formed in one of the clamp body and the nut member in parallel with the axis of the output rod, and an end of the first groove on the side of the advancement direction. A second groove parallel to the first groove is fixedly provided on the other of the clamp body and the nut member, and engages with the first groove when the output rod rotates, and engages with the second groove when the output rod advances and retreats. And a rotation restricting member that fits in the groove, and the groove width of the second groove is formed to be larger than the groove width of the first groove.
[0009]
In this clamp device, when fixing an object to be clamped such as a work, first, the nut member is driven by the clamp driving means in the retreating direction of the output rod. At this time, since the output rod is restricted from moving forward and backward by the rod movement restricting mechanism, the nut member moves relative to the output rod in the retracting direction. At this time, in the rotation regulating mechanism, since the rotation regulating member provided on one of the clamp body and the nut member is engaged with the first groove portion, the rotation of the nut member with respect to the clamp body is regulated. Then, the relative movement of the nut member with respect to the output rod is converted into a rotation operation of the output rod by the conversion mechanism, and the output rod rotates by a predetermined angle.
[0010]
When the output rod rotates by a predetermined angle, the rod operation restricting mechanism allows the output rod to move forward and backward, and also restricts the rotation of the output rod, so that the nut driving member and the output rod are integrally retracted by the clamp driving means. Is driven. At this time, in the rotation restricting mechanism, the rotation restricting member provided on one of the clamp body and the nut member is engaged with the first groove to the second groove, and subsequently, the rotation of the nut member with respect to the clamp body is restricted. Will be. Here, since the groove width of the second groove is formed to be larger than the groove width of the first groove, the rotation restricting member can be easily engaged with the second groove, and the nut member is rotated after the output rod rotates by a predetermined angle. Can smoothly move relative to the clamp body together with the output rod.
[0011]
For example, the phase after the rotation of the output rod by the predetermined angle is changed from the phase in which the rod operation restricting mechanism allows the forward / backward movement due to a large manufacturing error of each component constituting the rod operation restricting mechanism. Even if there is a slight shift, the groove width of the second groove is formed to be larger than the groove width of the first groove, so that the output rod and the nut member rotate with respect to the clamp body by the phase shift. The phase shift can be absorbed in the second groove.
[0012]
Conversely, when releasing the clamped state of the object to be clamped, the nut member is driven by the clamp release means in the advance direction of the output rod. Then, the nut member and the output rod move in the advance direction by a predetermined stroke in a state where the rotation operation of the output rod is restricted by the rod operation restriction mechanism. When the output rod advances by a predetermined stroke, the rod operation restricting mechanism allows the rotation operation of the output rod and restricts the advance / retreat operation of the output rod. The relative movement of the nut member is converted into a rotation operation of the output rod by the conversion mechanism, and the output rod rotates by a predetermined angle in the direction opposite to the above-described clamping.
[0013]
According to a second aspect of the present invention, in the first aspect, the connecting groove connecting the first and second grooves is formed as a tapered groove that expands from the first groove to the second groove. It is assumed that. At the time of releasing the clamp, contrary to the clamp, the output rod moves with the nut member in the advance direction by a predetermined stroke, and then the advance operation is restricted by the rod operation restricting mechanism, and the output rod rotates reversely by the predetermined angle. At this time, the rotation restricting member engages with the first groove from the second groove to continuously restrict the rotation of the nut member. However, the connection groove connecting the first and second grooves is moved from the first groove to the first groove. Since it is formed in the tapered groove which expands toward the two groove portions, it becomes easier to continuously engage the rotation restricting member from the second groove portion having a large groove width to the first groove portion having a small groove width.
[0014]
According to a third aspect of the present invention, in the first or second aspect of the present invention, the rotation restricting member is formed of a sphere. Therefore, in a state where the rotation restricting member is engaged with the first groove portion and the second groove portion, the nut member can smoothly move relative to the clamp body, and further, the rotation restricting member has the first groove portion having a different groove width. It is also easy to move between the first groove and the second groove.
[0015]
According to a fourth aspect of the present invention, in the clamp apparatus according to any one of the first to third aspects, the rod operation regulating mechanism includes a plurality of spheres fixedly provided on a clamp body and a plurality of the plurality of spheres provided on the output rod. An annular groove that engages with the sphere and regulates the forward and backward movement of the output rod while allowing the rotational movement of the output rod, and a plurality of rotation regulating grooves formed in parallel with the axis of the output rod from the annular groove. And a plurality of rotation restricting grooves for restricting the rotation operation of the output rod while allowing the plurality of spheres to engage with each other to allow the output rod to move forward and backward.
[0016]
In a state where the plurality of spheres provided on the clamp body are engaged with the annular groove provided on the output rod, the output rod can rotate by a predetermined angle while its advancing / retreating operation is restricted. On the other hand, in a state where the plurality of spheres are respectively engaged with the plurality of rotation regulating grooves formed in parallel with the axis of the output rod from the annular groove, the output rod is in a state where its rotation operation is regulated, It is possible to move back and forth with respect to the clamp body. Here, as described above, since the groove width of the second groove portion of the rotation restricting mechanism is formed to be larger than the groove width of the first groove portion, the output rod is integrally retracted with the nut member after rotating the predetermined angle. When performing the operation, for example, even if the phase after rotation of the output rod by a predetermined angle is slightly deviated from the phase at which the plurality of spheres can be engaged with the plurality of rotation restricting grooves, the rotation restricting member retains the first groove portion. Since the above-described phase shift can be absorbed when engaging with the second groove portion having a larger groove width, a plurality of spheres can easily engage with the plurality of rotation regulating grooves.
[0017]
Embodiments of the present invention will be described. In this embodiment, the present invention is applied to a clamp device for fixing a work to be machined to a work pallet. In addition, for convenience, the following description will be made with the upper, lower, left and right in FIG.
[0018]
As shown in FIGS. 1, 2, 5, and 8, the clamp device 1 includes a clamp body 2, an output rod 3 attached to the clamp body 2 so as to be able to advance and retreat, and a distal end of the output rod 3. A clamp arm 4 that is connected and outputs a clamping force to the workpiece W, is disposed within the clamp body 2 so as to be relatively movable in the vertical direction (the direction in which the output rod 3 moves forward and backward), and is externally fitted to the output rod 3 so as to be relatively movable. Nut member 5, a first hydraulic cylinder 6 (clamp driving means) capable of driving the nut member 5 downward, and a nut member 5 capable of driving the nut member 5 upward to release the clamped state by the first hydraulic cylinder 6. A second hydraulic cylinder 7 (clamp release driving means), a conversion mechanism 8 for converting a relative movement of the nut member 5 with respect to the output rod 3 into a rotation operation of the output rod 3, A rod operation restricting mechanism 9 that restricts the forward / backward movement of the rod 3 and restricts the rotation of the output rod 3 when the output rod 3 moves forward and backward, and a rotation restricting mechanism 10 that regulates the rotation of the nut member 5 with respect to the clamp body 2. Have.
[0019]
When the work W is clamped by the clamp device 1, the output rod 3 is rotated 90 degrees in the direction of FIG. 2A at a predetermined vertical position from the unclamped state of FIG. As shown in FIG. 5, after the clamp arm 4 is turned horizontally from the retreat position where it does not interfere with the work W to the clamp position where it can abut on the work W, the output rod 3 is moved in the retreat direction as shown in FIG. When driven, a clamping force is applied to the work W via the clamp arm 4. On the other hand, when releasing the clamped state of the work W, the output rod 3 is driven to return in the advance direction from the state of FIG. 8, and the clamp arm 4 is separated from the work W as shown in FIG. As shown in FIG. 1, the output arm 3 is rotated 90 degrees in the direction of b in FIG. 2 to retract the clamp arm 4 to the retracted position.
[0020]
First, the clamp body 2 will be described.
As shown in FIGS. 1, 2, 5, and 8, the clamp body 2 is fixed to the work pallet 11 with four bolts. The clamp main body 2 has an upper main body 12 and a lower main body 13 which is attached to the lower end of the upper main body 12 so as to be fitted inside.
[0021]
As shown in FIG. 2, the upper main body 12 is a substantially block-shaped member having a rectangular shape in a plan view, and the upper approximately 1/3 portion of the upper main body 12 is more horizontal than the lower approximately 2/3 portion. It protrudes. The lower approximately 2/3 of the upper main body 12 is fitted into the receiving hole of the work pallet 11, and the upper approximately 1/3 of the upper main body 12 radially protrudes from the clamp main body 2 with respect to the work pallet 11. With the position determined, the clamp body 2 is fixed to the work pallet 11.
[0022]
A rod insertion hole 14 through which the output rod 3 is inserted is formed at the upper end of the upper main body 12. Above the rod insertion hole 14, foreign matter such as cutting chips is prevented from entering the clamp main body 2. Dust seal 15 is mounted. Inside the upper main body 12, a cylinder hole 16 connected to the lower end of the rod insertion hole 14 and a cylinder hole 17 connected to the lower end of the cylinder hole 16 and having a larger diameter than the cylinder hole 16 are formed. A step 18 is also formed between the two cylinder holes 16 and 17. A sphere 19 for restricting rotation of a nut member 5 described later is fixed to a portion of the right side portion of the cylinder hole 16 immediately above the step portion 18. A cylindrical hole 20 having substantially the same diameter is also formed at the lower end of the cylinder hole 17, and the large-diameter cylindrical portion 13 b of the lower main body 13 is fitted in the cylindrical hole 20.
[0023]
The lower body 13 has a small-diameter cylindrical portion 13a formed at an upper end thereof, a large-diameter cylindrical portion 13b connected to the lower end of the small-diameter cylindrical portion 13a and having a larger diameter than the small-diameter cylindrical portion 13a, and a large-diameter cylindrical portion 13b. It is formed integrally with the lower end wall 13c. The small-diameter cylindrical portion 13a and the large-diameter cylindrical portion 13b have the same inner diameter, and the large-diameter shaft portion 3b of the output rod 3 is partially provided on the inner surface side of the small-diameter cylindrical portion 13a and the large-diameter cylindrical portion 13b. An accommodation hole 13d for accommodating the housing is formed.
[0024]
As shown in FIGS. 1 and 4, three small through-holes 13 e are formed in the small-diameter cylindrical portion 13 a in the circumferential direction at three equally-divided positions in the circumferential direction. Three spheres 21 of the mechanism 9 are press-fitted. An annular member 22 for preventing the three spheres 21 from moving radially outward from the through hole 13e is provided between the outer peripheral surface of the small-diameter cylindrical portion 13a and the cylindrical hole 20, and the annular member 22 has a small diameter. The upward movement is locked by a retaining ring 23 attached to the upper end of the cylindrical portion 13a.
The large-diameter cylindrical portion 13b is fitted in the cylindrical hole 20 of the upper main body 12, and in this state, the end wall portion 13c is fixed to the upper main body 12 by a plurality of bolts (not shown).
[0025]
Next, the output rod 3 will be described.
As shown in FIGS. 1, 2, 5, and 8, the output rod 3 is inserted into the rod insertion hole 14 of the upper main body 12 and is mounted on the clamp main body 2 so as to be able to move up and down.
The output rod 3 includes a small-diameter shaft portion 3a of approximately 2/3 of the upper portion, and a large-diameter shaft portion 3b provided integrally with a lower end of the small-diameter shaft portion 3a and having a slightly larger diameter than the small-diameter shaft portion 3a. ing.
[0026]
A screw portion (not shown) is formed at the upper end of the small diameter shaft portion 3 a, and the clamp arm 4 is screwed to the screw portion and fixed with a nut 30. On the other hand, a plurality of thread grooves 3c forming a part of a conversion mechanism 8 described later are formed on the outer peripheral portion of the lower end of the small diameter shaft portion 3a.
The large-diameter shaft portion 3b is vertically slidably mounted in a housing hole 13d formed in the lower main body 13. As shown in FIG. 3, on the outer peripheral portion of the large-diameter shaft portion 3b, an annular groove 3d, which constitutes a part of the rod operation restricting mechanism 9, is parallel to the axis of the output rod 3 from the annular groove 3d. Are formed with three rotation restricting grooves 3e.
[0027]
The clamp arm 4 pivots in conjunction with the rotation operation of the output rod 3 and abuts on the work W to clamp the work W when the output rod 3 retreats. This clamp arm 4 is formed in a tapered shape tapering in plan view toward its distal end, and a bolt 31 is attached to the distal end of the clamp arm 4. As shown in FIG. The lower end of the bolt 31 contacts the upper end surface of the work W to clamp the work W. Incidentally, by adjusting the height position of the bolt 31, it is possible to clamp various works W having different heights.
[0028]
Next, the nut member 5 will be described.
The nut member 5 is fitted to the lower half of the small diameter shaft portion 3 a of the output rod 3 so as to be relatively movable, and is slidably mounted in the cylinder holes 16 and 17 of the clamp body 2.
The nut member 5 has an upper cylindrical portion 5a and an annular piston portion 5b integrally formed at a lower end of the cylindrical portion 5a. The annular piston portion 5b is a stepped portion between the two cylinder holes 16 and 17. Engaging with the part 18, the nut member 5 is locked so as not to move further upward. A plurality of thread grooves 5c corresponding to the plurality of thread grooves 3c of the output rod 3 are also formed in the inner portion of the nut member 5.
[0029]
As shown in FIGS. 1 and 3, a first groove portion 5 d formed vertically (parallel to the axis 33 of the output rod 3) is formed on an outer peripheral portion of a right portion of the cylindrical portion 5 a. A second groove 5e, which is continuous with the upper end of the groove 5d and is parallel to the first groove 5d, is formed. The first and second grooves 5e constitute a part of the rotation restricting mechanism 10, and the sphere 19 fixed to the clamp body 2 engages with the first and second grooves 5e as described later. Thus, the rotation of the nut member 5 with respect to the clamp body 2 is restricted.
[0030]
The first hydraulic cylinder 6 has cylinder holes 16 and 17 formed in the upper main body 12, an annular piston portion 5 b of the nut member 5, and a portion between the cylinder holes 16 and 17 and the nut member 5 above the annular piston portion 5 b. An oil chamber 40 and the like are formed. Oil pressure is supplied to and discharged from the oil chamber 40 with a hydraulic supply device (not shown) via a hydraulic supply / discharge port 41 formed in the upper main body 12. When hydraulic pressure is supplied to the oil chamber 40, a clamping force for driving the nut member 5 downward is generated in the oil chamber 40.
[0031]
The second hydraulic cylinder 7 includes a cylinder hole 17 formed in the upper main body 12, an annular piston portion 5b of the nut member 5, and a cylinder hole 17 and a large-diameter shaft portion of the output rod 3 below the annular piston portion 5b. 3b. The oil chamber 42 is supplied and discharged with a hydraulic supply device (not shown) through a hydraulic supply / discharge port 43 formed in the upper body 12. When the oil pressure is supplied to the oil chamber 42, a clamp release force for driving the nut member 5 upward to release the clamped state of the work W is generated in the oil chamber 42.
[0032]
Next, the conversion mechanism 8 will be described.
As shown in FIGS. 1, 5, and 8, the conversion mechanism 8 includes a plurality of screw grooves 3 c formed on the output rod 3, a plurality of screw grooves 5 c formed on the nut member 5, and these screws. A number of balls 50 are provided between the grooves 3c and 5c. The conversion mechanism 8 converts a relative movement of the nut member 5 with respect to the output rod 3 into a rotation operation of the output rod 3 based on the same principle as a general ball screw, and a friction between the output rod 3 and the nut member 5. And the conversion efficiency is high.
[0033]
As shown in FIG. 1, the nut member 5 is moved by the first hydraulic cylinder 6 from the state in which the annular piston portion 5 b of the nut member 5 is engaged with the step 18 in the upper body 12 and the nut member 5 is at the upper limit position. When the nut member 5 is driven downward with respect to the output rod 3, the rotation of the nut member 5 with respect to the clamp body 2 is regulated by a rotation regulating mechanism 10, which will be described later. The same effect as a general ball screw is obtained, and the output rod 3 rotates in the direction of a in FIG.
[0034]
As shown in FIG. 5, when the lower end of the annular piston portion 5b engages with the step 3f between the small-diameter shaft portion 3a and the large-diameter shaft portion 3b of the output rod 3, the nut member 5 is further moved. 3, the rotation of the output rod 3 ends.
Conversely, as shown in FIG. 4, the state in which the nut member 5 is engaged with the stepped portion 3 f and the forward / backward movement of the output rod 3 is regulated by the rod movement regulating mechanism 9 described below, When the nut member 5 is driven upward, the relative movement of the nut member 5 with respect to the output rod 3 is converted into a rotation operation of the output rod 3 by a plurality of thread grooves 3c, 5c and a large number of balls 50, and FIG. As shown in FIG. 2, the output rod 3 rotates in the direction of b in FIG.
[0035]
Next, the rod operation regulating mechanism 9 will be described.
The rod movement restricting mechanism 9 is configured such that three spheres 21 fixedly provided on the lower body 13 of the clamp body 2 and three spheres 21 provided on the small diameter shaft portion 3a of the output rod 3 are engaged with each other. An annular groove 3d for restricting the forward / backward movement of the output rod 3 while allowing the rotation operation of the output rod 3; and three rotation restricting grooves 3e formed from the annular groove 3d in parallel with the axis 33 of the output rod 3, respectively. And a plurality of rotation restricting grooves 3e which engage with the three spheres 21 to restrict the rotation of the output rod 3 while allowing the output rod 3 to move forward and backward.
[0036]
As shown in FIGS. 1 and 4, the three spheres 21 are press-fitted into three through-holes 13 e of the lower main body 13 at three equally-divided positions in the circumferential direction, respectively. Also partially protrude inward. On the other hand, as shown in FIGS. 3 and 4, the three rotation restricting grooves 3e are also formed so as to extend upward from the annular grooves 3d at positions equally divided in the circumferential direction of the outer peripheral portion of the small diameter shaft portion 3a. ing. Therefore, when the output rod 3 rotates relatively to the small diameter shaft portion 3a and reaches a predetermined position, the three spheres 21 are configured to engage with the three rotation restricting grooves 3e.
[0037]
As shown in FIGS. 1, 3, and 4, when the three spheres 21 are engaged with the annular grooves 3d, the output rod 3 rotates relatively to the small-diameter cylindrical portion 13a of the lower body 13. As a result, the rotation operation of the output rod 3 is allowed, but the advance / retreat operation of the output rod 3 is restricted. On the other hand, as shown in FIGS. 5 to 7, in a state where the three spheres 21 are engaged with the three rotation restricting grooves 3 e, the output rod 3 is relatively movable in the vertical direction with respect to the lower body 13. Therefore, the forward / backward movement of the output rod 3 is allowed, but the rotation of the output rod 3 is restricted.
[0038]
Next, the rotation regulating mechanism 10 will be described.
As shown in FIGS. 1 and 3, the rotation restricting mechanism 10 includes a first groove 5 d formed on the outer peripheral portion of the nut member 5 in parallel with the axis 33 of the output rod 3, and an upper end of the first groove 5 d. A second groove portion 5e that is continuous with the first groove portion 5d and is fixedly provided in the upper body 12 and engages with the first groove portion 5d when the output rod 3 rotates, and the second groove 5d when the output rod 3 moves forward and backward. And a sphere 19 (rotation restricting member) that engages with the groove 5e.
[0039]
As shown in FIGS. 1 and 3, when the sphere 19 of the clamp body 2 is engaged with the first groove 5 d of the nut member 5, the nut member 5 can move up and down relative to the output rod 3. In addition, the rotation of the nut member 5 with respect to the clamp body 2 is restricted, and the vertical movement of the nut member 5 with respect to the output rod 3 can be reliably converted to the rotation operation of the output rod 3 by the conversion mechanism 8. On the other hand, as shown in FIGS. 8 and 9, even when the sphere 19 is engaged with the second groove 5 e of the nut member 5, the rotation of the nut member 5 with respect to the clamp body 2 is restricted. Further, as shown in FIGS. 3, 6, and 9, the connection groove 5f that connects the first and second grooves 5e is formed as a tapered groove that expands from the first groove 5d toward the second groove 5e. I have.
[0040]
Here, when the output rod 3 rotates 90 degrees in the direction of a in FIG. 2 when clamping the work W, the three rods formed on the small-diameter shaft portion 3a of the output rod 3 in the rod operation regulating mechanism 9 described above. The rotation regulating groove 3e reaches a position where it can engage with the three spheres 21 of the lower body 13. At this time, in the rotation restricting mechanism 10, the sphere 19 on the clamp body 2 side is continuously engaged with the first groove 5d to the second groove 5e, and the state in which the rotation of the nut member 5 with respect to the clamp body 2 is regulated is maintained. . By the way, as shown in FIGS. 3, 6, and 9, the groove width of the second groove 5e is formed larger than the groove width of the first groove 5d, so that the rotation restricting groove 3e and the first and second grooves 5e are formed. In the state after the rotation operation of the output rod 3, the positions of the three rotation restricting grooves 3e are slightly displaced from the positions directly above the three spheres 21 due to a large manufacturing error of the grooves 5d and 5e. However, when the sphere 19 of the rotation restricting mechanism 10 engages with the second groove 5e having a larger groove width than the first groove 5d, the output rod 3 and the nut member 5 rotate slightly with respect to the clamp body 2. , Can be absorbed. Therefore, the three spheres 21 can smoothly engage with the three rotation restricting grooves 3e.
[0041]
Conversely, when releasing the clamped state of the workpiece W, as shown in FIG. 5, after the output rod 3 has advanced upward by a predetermined stroke, the three spheres 21 respectively engage with the annular grooves 3d and 3 is restricted, and the nut member 5 is driven upward by the second hydraulic cylinder 7 relative to the output rod 3, so that the output rod 3 is rotated in the direction of b in FIG. I do. At this time, in the rotation restricting mechanism 10, the sphere 19 on the clamp body 2 side is continuously engaged with the first groove 5d from the second groove 5e of the nut member 5, but the first and second grooves 5e are connected. Since the connecting groove 5f is formed as a tapered groove that expands from the first groove 5d toward the second groove 5e, the sphere 19 is moved from the second groove 5e having a large groove width to the first groove 5d having a small groove width. Can be easily engaged.
[0042]
Next, the operation of the clamp device 1 will be described.
First, the operation of the clamp device 1 during clamping will be described. In order to clamp the workpiece W from the clamp release state shown in FIGS. 1 to 4, the hydraulic pressure is discharged from the oil chamber 42 of the second hydraulic cylinder 7 and the oil of the first hydraulic cylinder 6 is supplied from a hydraulic supply device (not shown). When the oil pressure is supplied to the chamber 40, the nut member 5 is driven downward by the clamping force generated in the oil chamber 40. At this time, in the rod movement regulating mechanism 9, the three spheres 21 provided on the lower body 13 are engaged with the annular groove 3d of the output rod 3, and the rotation of the output rod 3 is allowed while the rotation of the output rod 3 is allowed. Forward and backward movements are regulated. Further, in the rotation restricting mechanism 10, the sphere 19 on the clamp body 2 side is engaged with the first groove 5 d of the nut member 5, thereby restricting the rotation of the nut member 5 with respect to the clamp body 2.
[0043]
Therefore, the nut member 5 is driven relatively downward with respect to the output rod 3 by the clamping force of the first hydraulic cylinder 6. Then, the relative movement of the nut member 5 with respect to the output rod 3 is converted into a rotation operation of the output rod 3 by the conversion mechanism 8, and the output rod 3 rotates 90 degrees in the direction of FIG.
[0044]
By the way, when the output rod 3 rotates 90 degrees as described above, as shown in FIGS. 5 to 7, the three spheres 21 are located almost directly below the three rotation restricting grooves 3 e, and the output rod 3 moves forward and backward. Will be tolerated. Accordingly, when the nut member 5 further moves downward in this state, the output rod 3 is also driven to retreat downward integrally with the nut member 5, and the three spheres 21 are engaged with the three rotation regulating grooves 3e.
[0045]
At this time, in the rotation restricting mechanism 10, the sphere 19 on the clamp body 2 side continuously engages from the first groove 5d to the second groove 5e having a larger groove width than the first groove 5d. That is, after the rotation of the output rod 3 by 90 degrees, in FIG. 6, even if the circumferential position (phase) of the rotation regulating groove 3e and the spherical body 21 is slightly shifted due to a manufacturing error or the like, the spherical body 19 has a groove width. When engaging with the second groove portion 5e having a large diameter, the above-described displacement can be absorbed, so that a large frictional force is applied between the sphere 21 and the rotation regulating groove 3e and between the sphere 19 and the second groove portion 5e. This does not occur, and the sphere 21 smoothly engages with the rotation restricting groove 3e, and at the same time, the sphere 19 also smoothly engages with the second groove 5e.
[0046]
Further, when the output rod 3 is driven to retract by the clamping force of the first hydraulic cylinder 6, the lower end of the bolt 31 attached to the clamp arm 4 comes into contact with the upper end surface of the work W, as shown in FIG. The work W is clamped by the clamping force acting on the work W.
[0047]
Next, the operation of the clamp device 1 when releasing the clamp will be described. When the oil pressure is discharged from the oil chamber 40 of the first hydraulic cylinder 6 and the oil pressure is supplied to the oil chamber 42 of the second hydraulic cylinder 7 from a hydraulic supply device (not shown) from the clamp state of FIG. Release force is generated. At this time, in the rod operation restricting mechanism 9, since the three spheres 21 are engaged with the three rotation restricting grooves 3e of the output rod 3, the output rod 3 is allowed to move forward and backward while the output rod 3 rotates. Regulated. On the other hand, in the rotation regulating mechanism 10, the sphere 19 is engaged with the second groove 5 e of the nut member 5.
[0048]
Accordingly, the nut member 5 and the output rod 3 are integrally driven upward by the clamp releasing force generated in the oil chamber 42, and the output rod 3 advances upward as shown in FIG. The four bolts 31 are separated. When the output rod 3 advances by a predetermined stroke, the three spheres 21 are engaged with the annular groove 3 d in the rod operation restricting mechanism 9, thereby restricting the advancement operation of the output rod 3 and the rotation operation of the output rod 3. Will be tolerated. Then, the nut member 5 is moved upward relative to the output rod 3 by the unclamping force of the oil chamber 42, and this relative movement is converted into a rotation operation of the output rod 3 by the conversion mechanism 8, and the output rod 3 is rotated. Rotates.
[0049]
At this time, in the rotation restricting mechanism 10, the sphere 19 is continuously engaged from the second groove 5e to the first groove 5d having a smaller groove width than the second groove 5e, and the rotation of the nut member 5 is restricted. However, at this time, since the connection groove 5f between the first groove 5d and the second groove 5e is formed as a tapered groove which expands toward the second groove 5e, the first groove 5f is moved from the second groove 5e to the first groove 5e. The sphere 19 easily engages with the groove 5d.
[0050]
In this state, as shown in FIG. 1, the nut member 5 moves relatively upward with respect to the output rod 3 until the annular piston portion 5b engages with the step portion 18 between the cylinder holes 16 and 17. Then, the output rod 3 rotates 90 degrees in the direction of b in FIG. 2 and pivots to a position where the clamp arm 4 is retracted from the work W.
[0051]
According to the clamp device 1 described above, the following effects can be obtained.
1) In the rotation restricting mechanism 10, since the groove width of the second groove 5e is formed to be larger than the groove width of the first groove 5d, the first hydraulic cylinder is rotated after the output rod 3 rotates 90 degrees during clamping. When the output rod 3 and the nut member 5 are integrally driven downward by the sphere 6, the sphere 19 can be easily engaged with the second groove 5e continuously from the first groove 5d.
[0052]
At this time, even if the circumferential position (phase) of the rotation restricting groove 3e and the spherical body 21 is slightly shifted due to a manufacturing error or the like, the spherical body 19 is inserted into the second groove 5e having a larger groove width than the first groove 5d. Can be absorbed when engaged with each other, so that no large friction occurs between the sphere 21 and the rotation restricting groove 3e and between the sphere 19 and the second groove 5e, and the clamp acting on the work W There is no loss of power. Therefore, even if the manufacturing tolerances regarding the configuration of the rotation restricting mechanism 10 and the rod operation restricting mechanism 9 such as the first and second groove portions 5d and 5e and the rotation restricting groove 3e are loosened, the clamping device 1 (particularly, the rod operation restricting mechanism) 9) can be operated normally, which is advantageous in terms of manufacturing cost.
[0053]
2) Since the connection groove portion 5f connecting the first and second groove portions 5e is formed as a tapered groove expanding from the first groove portion 5d toward the second groove portion 5e, the output rod 3 is turned by 90 degrees when the clamp is released. After the rotation, the spherical body 19 can be smoothly engaged with the second groove 5e having a large groove width and the first groove 5d having a small groove width.
[0054]
Next, modified embodiments in which various modifications are made to the above-described embodiment will be described.
1] The conversion mechanism is not limited to the configuration using the above-described ball screw principle, but includes a male screw portion formed on the outer peripheral portion of the output rod 3 and an internal screw portion formed on the inner peripheral portion of the nut member 5. The relative movement of the nut member 5 with respect to the output rod 3 may be converted into a rotation operation of the output rod 3 with the screwable female screw portion.
[0055]
2] The rotation angle of the output rod 3 is not limited to 90 degrees, and an appropriate rotation angle can be selected according to conditions such as the shape of the work W and the working environment.
3] As the rotation restricting member that engages with the first and second grooves 5d and 5e, the first and second grooves 5d and 5e protrude inside the clamp body 2 such as a key in addition to the sphere 19 of the above embodiment. Various things can be adopted as long as they can be engaged with. Contrary to the above-described embodiment, the first and second grooves are formed on the inner peripheral side of the cylinder hole 16 of the clamp body 2, and are engaged with the first and second grooves on the outer peripheral part of the nut member 5. A rotation restricting member may be provided.
[0056]
4] Clamp driving means for driving the nut member 5 in the retreating direction of the output rod 3 and clamp releasing means for driving the nut member 5 in the advancing direction of the output rod 3 to release the clamped state by the clamp releasing means. Are not limited to hydraulic cylinders. That is, various types such as an air cylinder, a gas spring filled with a compressed gas such as nitrogen, or a spring member such as a coil spring or a disc spring can be employed.
[0057]
According to the first aspect of the present invention, in the rotation restricting mechanism, the groove width of the second groove is formed to be larger than the groove width of the first groove. When the output rod and the nut member are integrally driven by the clamp driving means in the retreating direction of the output rod, the rotation restricting member can be easily engaged with the second groove portion continuously from the first groove portion, Since the friction between the rotation restricting member and the second groove is reduced, the nut member can smoothly move relative to the clamp body.
[0058]
Further, in the case where there is a large manufacturing error with respect to each component constituting the rod operation restricting mechanism and the rotation restricting mechanism, the position after the output rod is rotated by a predetermined angle is shifted from the position at which the rod operation restricting mechanism allows the advance / retreat operation. Even if the phase is slightly shifted, since the groove width of the second groove is formed to be larger than the groove width of the first groove, the output rod and the nut member are relative to the clamp body by the phase shift. And the phase shift can be absorbed in the second groove portion. Therefore, even if the manufacturing tolerance for each component constituting the rod operation restricting mechanism and the rotation restricting mechanism is loosened, the rod operation restricting mechanism can be normally operated, which is advantageous in terms of manufacturing cost.
[0059]
According to the second aspect of the present invention, since the connection groove connecting the first and second grooves is formed in the tapered groove which expands from the first groove to the second groove, the output rod can be moved by a predetermined stroke when the clamp is released. When rotating by a predetermined angle after the advance, it becomes easier for the rotation restricting member to subsequently engage from the second groove having the larger groove width to the first groove having the smaller groove width.
[0060]
According to the third aspect of the present invention, since the rotation restricting member is formed of a sphere, the nut member smoothly moves relative to the clamp body when the rotation restricting member is engaged with the first groove and the second groove. It is possible to easily move the rotation restricting member between the first groove portion and the second groove portion having different groove widths.
[0061]
According to the fourth aspect of the present invention, the rod operation regulating mechanism is formed in such a manner that the plurality of spheres provided in the clamp body, the annular groove provided in the output rod, and the annular groove are respectively formed in parallel with the axis of the output rod. Since the plurality of rotation restricting grooves are provided, it is possible to restrict the forward and backward movement of the output rod when the output rod rotates, and to restrict the rotation of the output rod when the output rod moves forward and backward with a simple structure.
[0062]
Further, as described above, since the groove width of the second groove of the rotation restricting mechanism is formed to be larger than the groove width of the first groove, the output rod is integrally formed with the nut member after the output rod has rotated a predetermined angle. When performing the retreat operation, the plurality of spheres can easily engage with the plurality of rotation restricting grooves to reliably restrict the rotation operation of the output rod.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view of a clamp device (unclamped state) according to an embodiment of the present invention.
FIG. 2 is a plan view of the clamp device.
FIG. 3 is a right side view of a lower half of an output rod and a nut member in a clamp release state.
FIG. 4 is a sectional view taken along line IV-IV of FIG. 3;
FIG. 5 is a view corresponding to FIG. 1 after the output rod is rotated 90 degrees.
FIG. 6 is a diagram corresponding to FIG. 3 after the output rod is rotated 90 degrees.
FIG. 7 is a sectional view taken along line VII-VII of FIG. 6;
FIG. 8 is a diagram corresponding to FIG. 1 in a clamped state.
FIG. 9 is a diagram corresponding to FIG. 3 in a clamped state.
[Explanation of symbols]
1 Clamping device
2 Clamp body
3 Output rod
3d annular groove
3e Rotation regulating groove
5 Nut member
5d first groove
5e Second groove
5f Connection groove
6 First hydraulic cylinder
7 Second hydraulic cylinder
8 Conversion mechanism
9 Rod movement regulation mechanism
10 Rotation regulation mechanism
18 steps
19 sphere
21 sphere

Claims (4)

A clamp body and an output rod attached to the clamp body so as to be able to move forward and backward, the output rod is driven in a retracting direction after rotating a predetermined angle during clamping, and the output rod is driven in a retracting direction when the clamp is released, and the output rod is returned to the advance direction. In the clamping device configured to rotate the angle in reverse,
A nut member disposed in the clamp body so as to be relatively movable in the advance / retreat direction of the output rod, and externally fitted to the output rod so as to be relatively movable;
A clamp driving means capable of driving the nut member in the retreating direction, and a clamp release driving means capable of driving the nut member in the advancing direction to release a clamped state by the clamp driving means;
A conversion mechanism that converts the relative movement of the nut member with respect to the output rod into a rotation operation of the output rod,
A rod operation regulating mechanism that regulates the forward / backward movement of the output rod during rotation of the output rod and regulates the rotational movement of the output rod during forward / backward movement of the output rod;
A rotation restricting mechanism that restricts rotation of the nut member with respect to the clamp body, wherein the rotation restricting mechanism includes:
A first groove formed in one of the clamp body and the nut member in parallel to the axis of the output rod, a second groove connected to an end of the first groove on the side of the advance direction and parallel to the first groove; A rotation restricting member fixedly provided on the other of the main body and the nut member and engaging with the first groove during the rotation operation of the output rod and engaging with the second groove during the forward / backward operation of the output rod;
The groove width of the second groove portion is formed to be larger than the groove width of the first groove portion. The clamping device according to claim 1, wherein the connection groove connecting the first and second grooves is formed as a tapered groove that expands from the first groove to the second groove. The clamping device according to claim 1, wherein the rotation restricting member is formed of a sphere. The rod operation restricting mechanism includes a plurality of spheres fixedly provided on the clamp body and a plurality of the spheres provided on the output rod, respectively, and each of the plurality of spheres is engaged with each other to allow the output rod to rotate and move. An annular groove for regulating the operation, and a plurality of rotation regulating grooves formed in parallel with the axis of the output rod from the annular groove, wherein the plurality of spheres respectively engage to allow the output rod to advance and retreat. The clamping device according to any one of claims 1 to 3, further comprising a plurality of rotation restricting grooves for restricting a rotation operation of the output rod.

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