JP6507134B2 - Actuator - Google Patents

Description

  The present invention relates to an actuator having an end plate attached to the projecting end of a pair of rods.

  For example, a twin rod cylinder having a pair of rods as disclosed in Patent Document 1 is a type of actuator. The twin rod cylinder includes a guide block having a pair of rod holes through which a pair of rods can be inserted and withdrawn. End plates are attached to the projecting ends of the pair of rods. The end plate is attached to the projecting ends of the pair of rods using, for example, attachment members such as screws and pins. The end plate is used, for example, to attach a jig or the like. Then, the end plate is moved integrally with the pair of rods as the pair of rods are inserted into and retracted from the rod holes. Since the pair of rods are connected via the end plate, the rotation of each rod is prevented by the end plate. Such a twin-rod cylinder having an end plate attached to the projecting end of a pair of rods does not require a separate mechanism for preventing the rotation of each rod. Furthermore, a twin rod cylinder having a pair of rods can obtain a larger thrust than a cylinder with one rod.

Utility Model Registration No. 3189897

  By the way, if the material of the end plate or the jig attached to the end plate is different from the material of the guide block or the attachment target to which the guide block is attached and there is a difference in the coefficient of linear expansion, the temperature changes around. The degree of expansion and contraction of each of the accompanying end plates, guide blocks, and members to which they are attached differs. Then, in the pair of rods, prying may occur, and the sliding resistance of the pair of rods may increase. In addition, if there is backlash between the pair of rods and the end plate in the protrusion / retraction direction of the pair of rods, for example, the position of the end plate when the pair of rods reaches the stroke end deviates from the desired position. There is a risk of

  The present invention has been made to solve the above-mentioned problems, and an object thereof is to ensure high positioning accuracy without increasing the sliding resistance of a pair of rods even if the operating temperature changes. To provide an actuator that can

  The actuator for solving the above problems includes a guide block having a pair of rod holes, a pair of rods inserted in the respective rod holes so as to be able to project and retract respectively, and an end plate attached to the projecting end of the pair of rods. An actuator comprising a pair of connecting pins respectively connecting the rods and the end plate, the end plate being a pair of insertion holes into which the projecting end portions of the rods are respectively inserted; A pair of first pin insertion holes which extend in a direction perpendicular to the direction in which the rods come and go and orthogonal to the direction in which the pair of rods are arranged to communicate with the respective insertion holes and into which the respective connection pins are respectively inserted , And the projecting end of each rod is orthogonal to the direction in which the rods extend and retract, and in the direction orthogonal to the direction in which the pair of rods are juxtaposed And a second pin insertion hole respectively communicating with the first pin insertion holes and into which the connection pins are respectively inserted, and the connection pins are inserted into the first pin insertion holes and the second pins. A fixed portion fixed to one of the holes and a portion on the outer peripheral surface of the connection pin that is paired in the projecting and retracting direction of the rod, and the other inner periphery of the first pin insertion hole and the second pin insertion hole And a pair of press-fit parts press-fit into the part that is paired in the projection and retraction direction of the rod with respect to the surface, and the other of the first pin insertion hole and the second pin insertion hole has the pair Of the first pin insertion hole and the second pin insertion hole in the connection pin in a state where the press-fit portion of the second pin insertion hole is press-fitted into the other inner peripheral surface of the first pin insertion hole and the second pin insertion hole. Permissible relative movement of the pair of rods in the parallel direction Between are provided.

  In the actuator, there is a pair of central axes of a virtual cylinder through which the press-fit portions of the other inner peripheral surfaces of the first pin insertion hole and the second pin insertion hole and the pair of press-fit portions pass. Assuming that a virtual surface passing the axis is a first virtual surface, in each of the connection pins, the press-fit portions of the other inner peripheral surfaces of the first pin insertion hole and the second pin insertion hole and the pair of press-fit portions A shape symmetrically disposed with respect to the first virtual surface, passing through a center between the pair of central axes in the arrangement direction of the pair of rods, and orthogonal to the first virtual surface Of the other inner peripheral surface of the first pin insertion hole and the second pin insertion hole and the pair of press-fit portions with respect to the second virtual surface. It may be shaped symmetrically.

In the actuator, both end portions of each of the connection pins may be inlay portions for the first pin insertion holes.
In the actuator, an inner circumferential surface of each of the rod holes may function as a bearing surface for supporting the respective rods.

  In the actuator, each rod has a small diameter portion which is a projecting end portion inserted into the insertion hole, a large diameter portion whose outer diameter is larger than the small diameter portion, an outer peripheral surface of the small diameter portion and the large diameter And the step portion is disposed opposite to the end plate via a gap, and the end plate can be brought into contact with the step portion. Good.

  In the actuator, there is a gap between the outer peripheral surface of the projecting end and the inner peripheral surface of the insertion hole, and the outer peripheral surface of the projecting end and the inner peripheral surface of the insertion hole can be in contact with each other. May be

The actuator may be provided with a retaining member for preventing the connection pin from coming off the first pin insertion hole and the second pin insertion hole.
The actuator may be a twin rod cylinder that moves the pair of rods by fluid pressure.

  According to the present invention, high positioning accuracy can be ensured without an increase in the sliding resistance of the pair of rods even if the operating temperature changes.

Sectional drawing which shows the twin rod cylinder in 1st Embodiment. The disassembled perspective view of an end plate periphery. Line 3-3 in FIG. 1 sectional drawing. FIG. 4 is a cross-sectional view taken along line 4-4 in FIG. The disassembled perspective view of the end plate periphery in 2nd Embodiment. Sectional drawing which shows the connection part of an end plate and a rod. 7 is a cross-sectional view taken along line 7-7 in FIG. Sectional drawing which shows the connection part of the end plate in another embodiment, and a rod. Sectional drawing which shows the connection part of the end plate in another embodiment, and a rod. Sectional drawing which shows the connection part of the end plate in another embodiment, and a rod.

First Embodiment
Hereinafter, a first embodiment in which the actuator is embodied in a twin rod cylinder will be described according to FIGS. 1 to 4.

  As shown in FIG. 1, the twin rod cylinder 10 includes a guide block 11 having a pair of rod holes 11 a. The guide block 11 is made of, for example, aluminum. The pair of rod holes 11a are round holes and extend in parallel with each other. The twin rod cylinder 10 is provided with a pair of rods 12 inserted in the respective rod holes 11 a so as to be able to protrude and retract. An annular piston 13 is attached to an end of each rod 12.

  The guide block 11 is attached with a pair of cylinder tubes 14 that accommodates the respective pistons 13 in a reciprocating manner. The pair of cylinder tubes 14 are cylindrical. Each cylinder tube 14 is attached to the guide block 11 such that the axial center of each cylinder tube 14 coincides with the axial center of each rod hole 11a. A head cover 15 is attached to the side of each cylinder tube 14 opposite to the guide block 11. An opening on the side opposite to the guide block 11 in each cylinder tube 14 is closed by a head cover 15.

  The inside of each cylinder tube 14 is divided by the pistons 13 into a first pressure application chamber 14 a on the head cover 15 side and a second pressure application chamber 14 b on the guide block 11 side. On the outer peripheral surface of each piston 13, a rubber piston packing 13s is mounted which seals between the first pressure application chamber 14a and the second pressure application chamber 14b.

  The head cover 15 is formed with a pair of first fluid supply / discharge flow paths 16 respectively communicating with the respective first pressure action chambers 14 a. Further, the head cover 15 is formed with a first connection passage 16 a connecting the pair of first fluid supply and discharge channels 16 with each other. The guide block 11 is formed with a pair of second fluid supply / discharge channels 17 communicating with the respective second pressure action chambers 14b. Further, the guide block 11 is formed with a second connection passage 17 a connecting the pair of second fluid supply / discharge channels 17 with each other.

  When fluid is supplied from the pair of first fluid supply / discharge flow paths 16 to the respective first pressure action chambers 14 a, the respective pistons 13 start to move toward the guide block 11. Then, the fluid in the second pressure action chamber 14 b is discharged to the outside through the pair of second fluid supply / discharge channels 17, and each piston 13 moves until it reaches the stroke end on the guide block 11 side. Thereby, each rod 12 moves in the direction which protrudes with respect to each rod hole 11a.

  When fluid is supplied from the pair of second fluid supply / discharge flow paths 17 to the respective second pressure action chambers 14 b, the respective pistons 13 start to move toward the head cover 15. Then, the fluid in the first pressure application chamber 14 a is discharged to the outside through the pair of first fluid supply / discharge flow paths 16, and each piston 13 moves until it reaches the stroke end on the head cover 15 side. Thereby, each rod 12 moves in the direction in which it sinks into each rod hole 11a. Therefore, the twin rod cylinder 10 of the present embodiment moves the pair of rods 12 by fluid pressure.

  The end of each rod 12 opposite to the end where the piston 13 is attached is a protruding end that protrudes from each rod hole 11a. Each rod 12 connects a small diameter portion 12a which is a projecting end, a large diameter portion 12b whose outer diameter is larger than that of the small diameter portion 12a, and an outer peripheral surface of the small diameter portion 12a and an outer peripheral surface of the large diameter portion 12b. And a stepped portion 12c. Each step portion 12 c has an annular shape extending in the radial direction of each rod 12.

  The twin rod cylinder 10 includes an end plate 20 attached to the small diameter portions 12 a of the pair of rods 12. The end plate 20 is made of, for example, iron. The end plate 20 has a pair of insertion holes 20a into which the small diameter portions 12a of the rods 12 are respectively inserted. Each insertion hole 20a is circular. There is a gap C1 between the outer peripheral surface of the small diameter portion 12a and the inner peripheral surface of the insertion hole 20a. Therefore, the small diameter portion 12a is clearance fit to the insertion hole 20a. The outer peripheral surface of the small diameter portion 12a and the inner peripheral surface of the insertion hole 20a can be in contact with each other. The stepped portion 12c of each rod 12 is disposed to face the end plate 20 with a gap C2 therebetween. The end plate 20 can be in contact with each step 12c.

  In the pair of rod holes 11a, the pair of rod holes 11a are simultaneously processed in the guide block 11 in the same temperature environment in order to improve the pitch accuracy of each other, and the inner peripheral surface of each rod hole 11a supports each rod 12 Function as a bearing surface 11b. Furthermore, the rod hole 11a and the insertion hole 20a are respectively formed in the guide block 11 or the end plate 20 so that the central axis of the rod hole 11a and the central axis of the insertion hole 20a coincide with each other. Therefore, the mutual pitch of the pair of rod holes 11a and the mutual pitch of the pair of insertion holes 20a coincide with each other in the temperature environment at the time of processing.

  As shown in FIG. 2, the twin rod cylinder 10 is provided with a pair of connecting pins 30 that connect the rods 12 and the end plate 20 respectively. Each connection pin 30 is substantially cylindrical. The end plate 20 has a pair of first pin insertion holes 21 extending in a direction perpendicular to the projecting and retracting direction of the rods 12 and orthogonal to the arranging direction of the pair of rods 12. Each first pin insertion hole 21 communicates with each insertion hole 20a, and each connection pin 30 is inserted. Each first pin insertion hole 21 is circular.

  As shown in FIG. 3, each first pin insertion hole 21 is an end on both sides of each insertion hole 20 a in a direction perpendicular to the direction in which the rods 12 appear and perpendicular to the arrangement direction of the pair of rods 12. It is comprised by the 1st hole 21a and the 2nd hole 21b which penetrate the plate 20. As shown in FIG.

  The small diameter portion 12 a of each rod 12 has a second pin insertion hole 22 which is orthogonal to the direction in which the rods 12 appear and retracts, and orthogonal to the direction in which the pair of rods 12 are arranged. Each second pin insertion hole 22 communicates with each first pin insertion hole 21 and each connection pin 30 is inserted. Each second pin insertion hole 22 is circular. The hole diameters of the first pin insertion holes 21 and the second pin insertion holes 22 are set to be the same.

  Each connecting pin 30 has a fixing portion 31 fixed by being pressed into the second pin insertion hole 22. The fixing portion 31 is disposed at the axial center of the connecting pin 30. The fixing portion 31 is press-fitted over the entire inner peripheral surface of the second pin insertion hole 22. Therefore, each connection pin 30 is fixed to the small diameter portion 12 a of each rod 12. Further, an annular groove 31 a is formed in the fixing portion 31. The groove 31 a is provided at the central portion of the fixed portion 31 in the axial direction of the connection pin 30.

  As shown in FIG. 4, each connecting pin 30 is present at a portion forming a pair in the projecting and retracting direction of the rod 12 on the outer peripheral surface of the connecting pin 30. It has a pair of press-fit parts 32 press-fit in the part which becomes a pair in the direction of emergence. The outer surfaces of the pair of press-fit portions 32 are curved in an arc along the inner peripheral surface of the first pin insertion hole 21 and have a symmetrical shape. Therefore, the shapes of the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are symmetrical.

  Since the twin rod cylinder 10 of the present embodiment includes the pair of connection pins 30, a virtual cylinder (in the present embodiment, the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the pair of press-fit portions 32 pass through) There is a pair of central axis L1 of a circle drawn by the inner peripheral surface of the first pin insertion hole 21). Here, assuming that a virtual surface passing through the pair of central axes L1 is a first virtual surface S1, in each connection pin 30, the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are The shape is arranged symmetrically with respect to the first virtual surface S1.

  Further, assuming that each virtual plane passing through each central axis L1 and orthogonal to the first virtual plane S1 is a third virtual plane S3, the inner peripheral surface of the first pin insertion hole 21 and each connecting pin 30 The press-fit portions with the pair of press-fit portions 32 are shaped so as to be arranged symmetrically with respect to each third virtual surface S3.

  Further, a virtual surface passing through the center between the pair of central axes L1 in the direction in which the pair of rods 12 is arranged and orthogonal to the first virtual surface S1 is taken as a second virtual surface S2. Then, in each connection pin 30, the press-fit portions of the inner circumferential surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are arranged symmetrically with respect to each third virtual surface S3. Thus, the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are arranged symmetrically with respect to the second virtual surface S2.

  As shown in FIG. 2, the pair of press-fit portions 32 are respectively provided on both sides of the fixing portion 31 in the axial direction of the connection pin 30, and the second pin-in hole 21 a of the first pin insertion hole 21 and the second They are respectively disposed inside the holes 21b. The outer surfaces of the pair of press-fit portions 32 are continuous with the outer peripheral surface of the fixed portion 31 in the axial direction of the connection pin 30. The outer surfaces of the pair of press-fit portions 32 extend in the same plane as the outer peripheral surface of the fixed portion 31.

  As shown in FIG. 4, each connection pin 30 has a pair of relief portions 33 that are continuous with the pair of press-fit portions 32 in the circumferential direction of the connection pin 30 and connect the pair of press-fit portions 32 with each other. The pair of relief portions 33 have a mountain shape, and the outer surface of the relief portions 33 extends in a straight line. The pair of relief portions 33 are present at the pair of connecting pins 30 in the juxtaposed direction of the pair of rods 12.

  The outer surfaces of the pair of relief portions 33 are located radially inward of the connecting pin 30 with respect to a virtual cylinder through which the outer peripheral surface of the fixed portion 31 and the outer surfaces of the pair of press-fit portions 32 pass. Thus, the outer surfaces of the pair of relief portions 33 do not contact the inner peripheral surface of the first pin insertion hole 21. Then, in a state in which the pair of press-fit portions 32 are press-fitted into the inner peripheral surface of the first pin insertion hole 21 inside the first pin insertion hole 21, the pair of rods for the first pin insertion hole 21 in the connection pin 30 An allowance space 34 is provided to allow relative movement in the parallel arrangement direction of twelve.

  As shown in FIG. 3, both end portions of each connection pin 30 are a first inlay portion 35 a and a second inlay portion 35 b as an inlay portion for each first pin insertion hole 21. The outer diameters of the first inlay portion 35 a and the second inlay portion 35 b are set to be slightly smaller than the hole diameter of the first pin insertion hole 21. And, when each connecting pin 30 is inserted into each first pin inserting hole 21 and each second pin inserting hole 22, the first inlay portion 35a of each connecting pin 30 corresponds to each first pin inserting hole The first holes 21a, the second pin insertion holes 22, and the second holes 21b of the first pin insertion holes 21 are inserted while being guided. Further, the second inlay portions 35 b of the respective connection pins 30 are inserted into the first holes 21 a of the respective first pin insertion holes 21.

  The outer diameters of the first inlay portion 35a and the second inlay portion 35b are smaller than the hole diameter of the first pin insertion hole 21, so the first inlay portion 35a and the second inlay portion 35b are first pins. The insertion of the connection pin 30 into the insertion hole 21 is facilitated, and the inclination of the connection pin 30 when the pair of press-fit portions 32 are press-fit into the inner peripheral surface of the first pin insertion hole 21 is suppressed.

  As shown in FIG. 2, the twin rod cylinder 10 is provided with a retaining member 36 for preventing the first pin insertion holes 21 and the second pin insertion holes 22 of the connection pins 30 from coming off. The retaining member 36 is a screw member. In the tip end surface of the small diameter portion 12a of each rod 12, a female screw hole 12h in which the retaining member 36 is screwed is formed. The female screw hole 12 h extends in the axial direction of the rod 12. In a state where the fixing portion 31 is press-fitted to the inner peripheral surface of the second pin insertion hole 22, the female screw hole 12 h and the groove 31 a overlap in the axial direction of the rod 12. When the retaining member 36 is screwed into the female screw hole 12h, the tip end of the retaining member 36 is engaged with the groove 31a. The connection pin 30 is prevented from dropping out of the first pin insertion hole 21 and the second pin insertion hole 22 by the locking of the tip end portion of the retaining member 36 with the groove 31 a.

  Each connecting pin 30 is fixed to the end plate 20 because the pair of press-fit portions 32 is press-fitted to the inner peripheral surface of each first pin insertion hole 21. Further, each connecting pin 30 is fixed to the small diameter portion 12 a of each rod 12 because the fixing portion 31 is fixed by being pressed into the second pin insertion holes 22. Thereby, each rod 12 and the end plate 20 are connected by the pair of connection pins 30, respectively.

Next, the operation of the first embodiment will be described.
When the material of the end plate 20 and the material of the guide block 11 are different from each other and the linear expansion coefficients of the end plate 20 and the guide block 11 differ, the degree of expansion and contraction of the end plate 20 and the guide block 11 changes with the temperature change. At this time, the pair of press-fit portions 32 is deformed at the press-fit portion with the inner circumferential surface of the first pin insertion hole 21, and the relative movement of the pair of rods 12 in the arranging direction with respect to the first pin insertion hole 21 in the connection pin 30 Is permitted by the allowable space 34, so that the occurrence of the prying in the pair of rods 12 is suppressed.

  In the twin rod cylinder 10 of the present embodiment, the inner peripheral surface of each rod hole 11 a functions as a bearing surface 11 b for supporting each rod 12, so the inner peripheral surface of each rod hole 11 a and each rod 12 There is almost no gap between them, and the design is such that the radial play of each rod 12 is small. Therefore, the design is such that the positional accuracy in the radial direction of each rod 12 in the end plate 20 is improved.

  Since the shapes of the press-fit portions of the inner circumferential surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are symmetrical, the inner circumferential surface of the first pin insertion hole 21 and the pair of press-fit portions 32 Between them, a centripetal force is generated toward the central axis L1 of the virtual cylinder through which the inner peripheral surface of the first pin insertion hole 21 and the press-fit portion of the pair of press-fit portions 32 pass. The degree of expansion and contraction of the end plate 20 and the guide block 11 due to a change in ambient temperature is different, and the pair of press-fit portions 32 is deformed at the press-fit portion with the inner peripheral surface of the first pin insertion hole 21. The relative movement of the pair of rods 12 in the juxtaposed direction with respect to the first pin insertion hole 21 is permitted by the allowance space 34. Thereby, the positional relationship between the guide block 11 and the pair of rods 12 is displaced due to the deformation of the pair of press-fit portions 32, but at this time, the centripetal force acts and the deformation amount and centripetal force of the pair of press-fit portions 32 are It will be in equilibrium.

  In detail, in each connecting pin 30, the press-fit portions of the inner circumferential surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are in a shape symmetrically arranged with respect to the first virtual surface S1. Therefore, in the operation of relieving the deformation of the pair of press-fit portions 32, the fluctuation of the rod 12 in the end plate 20 in the projecting and retracting direction is restrained.

  Further, the pair of connection pins 30 are arranged so that the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are arranged symmetrically with respect to the second virtual surface S2. . For this reason, the rigidity of the connection pin 30 in the direction in which the pair of rods 12 are juxtaposed is equal in the relaxation operation of the deformation of the pair of press-fit portions 32, and the presence of the pair of connection pins 30 The rigidity in the direction of As a result, the variation in the juxtaposed direction of the juxtaposed centers of the pair of rods 12 in the end plate 20 is restrained.

  Therefore, the movement of the pair of rods 12 due to the deformation of the pair of press-fit portions 32 is a symmetrical amount with respect to the center between the pair of rods 12 in the end plate 20, and the pair of rods 12 move in opposite directions. The positional relationship between the center between the pair of rods 12 in the end plate 20 and the center between the pair of rods 12 in the guide block 11 is maintained.

  The fixing portion 31 is fixed to the second pin insertion hole 22, and the pair of press-fit portions 32 is press-fitted to a portion where the rod 12 projects in the withdrawal direction with respect to the inner peripheral surface of the first pin insertion hole 21. It is done. Thereby, each connecting pin 30 connects each rod 12 and the end plate 20 in a state in which rattling between the pair of rods 12 and the end plate 20 in the projecting and retracting direction of the pair of rods 12 is eliminated. Therefore, for example, the position of the end plate 20 when the pair of rods 12 reach the stroke end is prevented from being shifted with respect to the desired position.

  When a large load is applied to the end plate 20 in the projecting and retracting direction of the rod 12, a load is applied to each connecting pin 30, and each connecting pin 30 may be deformed. In this case, when the end plate 20 moves toward the stepped portions 12c with the deformation of the connection pins 30, the end plate 20 abuts on the stepped portions 12c. And since the load added to end plate 20 is received by each level difference part 12c, load applied to each connection pin 30 decreases.

  Furthermore, when the end plate 20 moves in the direction in which the pair of rods 12 are arranged in parallel with the deformation of each connecting pin 30, the inner peripheral surface of the insertion hole 20a of the end plate 20 abuts on the outer peripheral surface of the small diameter portion 12a. It has become. And since the load added to end plate 20 is received by small diameter part 12a, the load applied to each connecting pin 30 decreases.

The following effects can be obtained in the first embodiment.
(1) The connection pins 30 are fixed by being press-fitted into the second pin insertion holes 22 and fixed in pairs with the inner peripheral surface of the first pin insertion holes 21 in the direction in which the rods 12 protrude and retract And a pair of press-fit portions 32 which are press-fit into the following portions. According to this, each rod 12 and the end plate 20 are connected in a state in which the play between the pair of rods 12 and the end plate 20 in the projecting and retracting direction of the pair of rods 12 is eliminated by each connecting pin 30. Can. Furthermore, with the pair of press-fit portions 32 press-fit into the inner peripheral surface of the first pin insertion hole 21 inside the first pin insertion hole 21, the pair of rods for the first pin insertion hole 21 in the connection pin 30 An allowance space 34 is provided to allow relative movement in the parallel arrangement direction of twelve. According to this, relative movement in the parallel arrangement direction of the pair of rods 12 with respect to the first pin insertion hole 21 in the connection pin 30 is permitted by the allowable space 34, and the pair of rods 12 suffers from pricking due to temperature change. Can be suppressed. As described above, even if there is a change in the operating temperature, high positioning accuracy can be ensured without the sliding resistance of the pair of rods 12 increasing.

  (2) In each connection pin 30, the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are arranged symmetrically with respect to the first virtual surface S1. According to this, in the operation of relieving the deformation of the pair of press-fit portions 32, the fluctuation in the direction in which the rod 12 in the end plate 20 appears is restrained. Further, the pair of connection pins 30 are arranged so that the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are arranged symmetrically with respect to the second virtual surface S2. . According to this, when the deformation of the pair of press-fit portions 32 is relieved, the rigidity of the connection pins 30 in the juxtaposed direction of the pair of rods 12 is equal, and the presence of the pair of connection pins 30 makes the pair of connection pins 30 The rigidity in the opposite direction of the same. As a result, in the state in which the relative position between the end plate 20 and the rod 12 is adjusted due to the temperature change, the fluctuation in the direction in which the pair of rods 12 in the end plate 20 is aligned is restricted. Therefore, the movement of the pair of rods 12 due to the deformation of the pair of press-fit portions 32 is a symmetrical amount with respect to the center between the pair of rods 12 in the end plate 20, and the pair of rods 12 move in opposite directions. The positional relationship between the center between the pair of rods 12 in the end plate 20 and the center between the pair of rods 12 in the guide block 11 can be maintained.

  (3) The both ends of each connection pin 30 are the 1st inlay part 35a and the 2nd inlay part 35b. According to this, it becomes easy to insert the connecting pin 30 into the first pin insertion hole 21 and the assembling operation of each connecting pin 30 becomes easy.

  (4) The inner circumferential surface of each rod hole 11 a functions as a bearing surface 11 b for supporting each rod 12. According to this, there is almost no gap between the inner peripheral surface of each rod hole 11 a and each rod 12, and it is possible to reduce the play in the radial direction of each rod 12. The positional accuracy in the radial direction can be improved.

  (5) The end plate 20 can be in contact with the stepped portion 12c. According to this, a large load is applied to the end plate 20, a load is applied to each connecting pin 30, and each connecting pin 30 is deformed, so that the end plate 20 has a stepped portion 12c with the deformation of each connecting pin 30. When moving toward the end, the end plate 20 abuts on each step 12c. Therefore, since the load applied to the end plate 20 is received by the step portions 12 c, the load applied to each connecting pin 30 can be reduced, and the durability of each connecting pin 30 can be improved.

  (6) The outer peripheral surface of the small diameter portion 12a and the inner peripheral surface of the insertion hole 20a can be in contact with each other. According to this, a large load is applied to the end plate 20, a load is applied to each connecting pin 30, and each connecting pin 30 is deformed, and the end plate 20 becomes a pair of rods 12 with the deformation of each connecting pin 30. The inner peripheral surface of the insertion hole 20a of the end plate 20 abuts on the outer peripheral surface of the small diameter portion 12a. Therefore, since the load applied to the end plate 20 is received by the small diameter portion 12a, the load applied to each connecting pin 30 can be reduced, and the durability of each connecting pin 30 can be improved.

  (7) The twin rod cylinder 10 is provided with the retaining member 36. According to this, the retaining member 36 can prevent the connection pin 30 from coming off the first pin insertion hole 21 and the second pin insertion hole 22.

  (8) The twin rod cylinder 10 in which the end plate 20 is attached to the pair of rods 12 does not need a separate mechanism for preventing the rotation of each rod 12. Furthermore, the twin rod cylinder 10 having the pair of rods 12 can obtain a larger thrust than a cylinder with one rod.

Second Embodiment
Hereinafter, a second embodiment in which the actuator is embodied in a twin rod cylinder will be described according to FIGS. In the embodiment described below, the same components as those of the first embodiment already described are denoted by the same reference numerals, and the overlapping description will be omitted or simplified.

  As shown in FIGS. 5 and 6, each connecting pin 30 is fixed by being press-fitted into the first hole 21a of the first pin insertion hole 21 as a first fixing portion 31A as a fixing portion, and the first pin A second fixing portion 31B as a fixing portion fixed by being pressed into the second hole 21b of the insertion hole 21 is provided. The first fixing portion 31A is provided at one end of the connection pin 30, and the second fixing portion 31B is provided at the other end of the connection pin 30. The first fixing portion 31A is press-fitted over the entire inner peripheral surface of the first hole 21a, and the second fixing portion 31B is press-fitted over the entire inner peripheral surface of the second hole 21b. Thus, each connecting pin 30 is fixed to the end plate 20. Further, an annular groove 31a is formed in the second fixing portion 31B.

  As shown in FIG. 7, each connecting pin 30 is present at a portion forming a pair in the projecting and retracting direction of the rod 12 on the outer peripheral surface of the connecting pin 30 and against the inner peripheral surface of the second pin insertion hole 22. It has a pair of press-fit parts 32A which are press-fit to the part which becomes a pair in the direction of emergence and retraction. The outer surfaces of the pair of press-fit portions 32A are curved in an arc along the inner peripheral surface of the second pin insertion hole 22 and have a symmetrical shape. Therefore, the shapes of the press-fit portions of the inner peripheral surface of the second pin insertion hole 22 and the pair of press-fit portions 32A are symmetrical.

  Also in the second embodiment, the symmetry regarding the press-fit portion between the inner circumferential surface of the second pin insertion hole 22 and the pair of press-fit portions 32A is the inside of the first pin insertion hole 21 described in the first embodiment. Similar to the symmetry of the circumferential surface and the press-fit portion of the pair of press-fit portions 32, the first virtual surface S1 and the second virtual surface S2 are maintained. Due to this symmetry, the variation in the juxtaposed direction of the juxtaposed centers of the pair of rods 12 in the end plate 20 is restrained.

  The pair of press-fit portions 32 </ b> A is disposed at the axial center of the connection pin 30. The outer surfaces of the pair of press-fit portions 32A are continuous with the outer peripheral surfaces of the first fixing portion 31A and the second fixing portion 31B in the axial direction of the connection pin 30. The outer surfaces of the pair of press-fit portions 32A extend on the same plane as the outer peripheral surfaces of the first fixing portion 31A and the second fixing portion 31B.

  Each connection pin 30 is continuous with the pair of press-fit portions 32A in the circumferential direction of the connection pin 30, and has a pair of relief portions 33A connecting the pair of press-fit portions 32A. The pair of relief portions 33A have a mountain shape, and the outer surface of the relief portions 33A extends in a straight line. The pair of relief portions 33 </ b> A is present in the connecting pin 30 at a portion where the pair of rods 12 are arranged in parallel.

  The outer surfaces of the pair of relief portions 33A are positioned radially inward of the connecting pin 30 than the virtual cylinder through which the outer peripheral surface of the first fixed portion 31A, the outer peripheral surface of the second fixed portion 31B, and the outer surfaces of the pair of press-fit portions 32A pass. doing. Therefore, the outer surfaces of the pair of relief portions 33A are in non-contact with the inner peripheral surface of the second pin insertion hole 22. Then, in a state in which the pair of press-fit portions 32A are press-fitted into the inner peripheral surface of the second pin insertion hole 22 inside the second pin insertion hole 22, the pair of rods for the second pin insertion hole 22 in the connection pin 30 An allowance space 34A for allowing relative movement of the twelve in the parallel arrangement direction is provided.

  As shown in FIGS. 5 and 6, the end plate 20 is formed with a female screw hole 20h in which the retaining member 36 is screwed. The female screw hole 20 h extends in the axial direction of the rod 12. In a state where the second fixing portion 31B is press-fitted to the inner peripheral surface of the second hole 21b, the female screw hole 20h and the groove 31a overlap in the axial direction of the rod 12. When the retaining member 36 is screwed into the female screw hole 20h, the tip end of the retaining member 36 is locked in the groove 31a. The connection pin 30 is prevented from dropping out of the first pin insertion hole 21 and the second pin insertion hole 22 by the locking of the tip end portion of the retaining member 36 with the groove 31 a.

  Each connecting pin 30 is fixed to the small diameter portion 12 a of each rod 12 because the pair of press-fit portions 32 A is press-fitted to the inner peripheral surface of each second pin insertion hole 22. Further, each connecting pin 30 is fixed by pressing the first fixing portion 31A into the first hole 21a, and is fixed by pressing the second fixing portion 31B into the second hole 21b. Therefore, it is fixed to the end plate 20. Thereby, each rod 12 and the end plate 20 are connected by the pair of connection pins 30, respectively.

Next, the operation of the second embodiment will be described.
When the material of the end plate 20 and the material of the guide block 11 are different from each other and the linear expansion coefficients of the end plate 20 and the guide block 11 differ, the degree of expansion and contraction of the end plate 20 and the guide block 11 changes with the temperature change. At this time, since relative movement in the parallel arrangement direction of the pair of rods 12 with respect to the second pin insertion hole 22 in the connecting pin 30 is permitted by the admissible space 34A, the generation of the pricking in the pair of rods 12 is suppressed It is done.

  The first fixing portion 31A is fixed to the first hole 21a, the second fixing portion 31B is fixed to the second hole 21b, and the pair of press-fit portions 32A with respect to the inner peripheral surface of the second pin insertion hole 22. The rod 12 is press-fit into a pair of parts in the projecting and retracting direction. Thereby, each connecting pin 30 connects each rod 12 and the end plate 20 in a state in which rattling between the pair of rods 12 and the end plate 20 in the projecting and retracting direction of the pair of rods 12 is eliminated. Therefore, for example, the position of the end plate 20 when the pair of rods 12 reach the stroke end is prevented from being shifted with respect to the desired position. Therefore, according to the second embodiment, the same effects as the effects (1) to (8) of the first embodiment can be obtained.

The above embodiments may be modified as follows.
As shown in FIG. 8, the pair of relief portions 33 may not be provided on the connection pin 30, and the pair of relief portions 21 </ b> A may be formed on the inner peripheral surface of the first pin insertion hole 21. . The pair of relief portions 21 </ b> A is a concave portion present on the inner circumferential surface of the first pin insertion hole 21 at a portion that becomes a pair in the direction in which the pair of rods 12 are arranged in parallel. And the site | part which becomes a pair in the parallel arrangement direction of a pair of rod 12 in the connection pin 30 is opposingly arranged by a pair of clearance part 21A. Therefore, portions of the connecting pin 30 which are paired in the direction in which the pair of rods 12 are juxtaposed are not in contact with the inner peripheral surface of the first pin insertion hole 21. Then, in a state in which the pair of press-fit portions 32 are press-fitted into the inner peripheral surface of the first pin insertion hole 21 inside the first pin insertion hole 21, the pair of rods for the first pin insertion hole 21 in the connection pin 30 An allowance space 34 is provided to allow relative movement in the parallel arrangement direction of twelve.

  As shown in FIG. 9, for example, portions of the connecting pin 30 in the projecting and retracting direction of the rod 12 form a pair of flat surfaces 30f, and both corners of each flat surface 30f correspond to the inner periphery of the first pin insertion hole 21. It may be configured to be pressed into the surface. Accordingly, the corner portions of the two flat surfaces 30 f which are paired in the protrusion and retraction direction of the rod 12 function as the pair of press-fit portions 32. Thus, the connecting pin 30 is present in the outer peripheral surface of the connecting pin 30 in the part where it is paired in the projecting and retracting direction of the rod 12, and the connecting pin 30 is paired in the projecting and recessed direction of the rod 12 The structure which has two pairs of a pair of press-fit part 32 press-fit in the site | part which becomes these may be sufficient. The shapes of the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the two pairs of press-fit portions 32 are symmetrical.

  Also in the embodiment shown in FIG. 9, the symmetry regarding the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the pair of press-fit portions 32 is the first pin insertion described in the first embodiment. Similar to the symmetry of the inner circumferential surface of the hole 21 and the press-fit portion of the pair of press-fit portions 32, the first virtual surface S1 and the second virtual surface S2 are maintained. Due to this symmetry, the variation in the juxtaposed direction of the juxtaposed centers of the pair of rods 12 in the end plate 20 is restrained.

  Between the inner circumferential surface of the first pin insertion hole 21 and the two pairs of press-fit portions 32, the press-fit portions of the inner circumferential surface of the first pin insertion hole 21 and the two pairs of press-fit portions 32 pass A centripetal force is generated toward the central axis L1 of the virtual cylinder. The degree of expansion and contraction of the end plate 20 and the guide block 11 due to a change in ambient temperature is different, and two pairs of press-fit portions 32 are deformed at the press-fit portion with the inner circumferential surface of the first pin insertion hole 21 The relative movement of the pair of rods 12 in the juxtaposed direction with respect to the first pin insertion hole 21 in the pin 30 is permitted by the allowance space 34. Thereby, the positional relationship between the guide block 11 and the pair of rods 12 is displaced due to the deformation of the pair of press-fit portions 32, but at this time, the centripetal force acts and the deformation amount and centripetal force of the pair of press-fit portions 32 are It will be in equilibrium.

  Specifically, in each connecting pin 30, the press-fit portions of the inner circumferential surface of the first pin insertion hole 21 and the two pairs of press-fit portions 32 are arranged symmetrically with respect to the first virtual surface S1. Because of this, during the relaxation operation of the deformation of the pair of press-fit portions 32 of the two sets, the fluctuation of the rod 12 in the end plate 20 in the projecting and retracting direction is restrained.

  Further, the pair of connection pins 30 are arranged mutually such that the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the two pairs of press-fit portions 32 are arranged symmetrically with respect to the second virtual surface S2. It is done. For this reason, the rigidity of the connection pin 30 in the parallel arrangement direction of the pair of rods 12 is equal during the relaxation operation of the deformation of the two pairs of press-fit portions 32, and the pair of connection pins 30 causes the pair of connection pins The stiffness in the 30 opposite directions coincide. As a result, the fluctuation in the direction in which the pair of rods 12 in the end plate 20 are arranged in parallel is restrained.

  Furthermore, in each connection pin 30, the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the two pairs of press-fit portions 32 are respectively arranged symmetrically with respect to each third virtual surface S3. ing. Also in this case, during the relaxation operation of the deformation of the two pairs of press-fit portions 32, the fluctuation in the direction in which the pair of rods 12 in the end plate 20 is arranged in parallel is restrained.

  Therefore, the movement of the pair of rods 12 accompanying the deformation of the two pairs of press-fit portions 32 is a symmetrical amount with respect to the center between the pair of rods 12 in the end plate 20. Then, the pair of rods 12 move in opposite directions, but the positional relationship between the center between the pair of rods 12 in the end plate 20 and the center between the pair of rods 12 in the guide block 11 is maintained. .

  As shown in FIG. 10, in each connection pin 30, the press-fit portions of the inner circumferential surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are arranged asymmetrically with respect to each third virtual surface S3. It may be in the shape of Each connection pin 30 is continuous with the pair of press-fit portions 32 in the circumferential direction of the connection pin 30, and has a mountain-shaped relief portion 33 connecting the pair of press-fit portions 32 with each other. Each connecting pin 30 is continuous with the pair of press-fit portions 32 in the circumferential direction of the connection pin 30, and has a flat surface-like relief portion 33B connecting the pair of press-fit portions 32 with each other. The relief portions 33, 33B are present at portions forming a pair in the arranging direction of the pair of rods 12 in the connecting pin 30. The relief portions 33 </ b> B of the connection pins 30 are disposed at positions facing each other in the direction in which the pair of rods 12 are juxtaposed.

  And in each connecting pin 30, the press-fit sites of the inner circumferential surface of the first pin insertion hole 21 and the pair of press-fit sections 32 are located at positions closer to the relief section 33B than the respective third virtual surfaces S3 The circumferential length of the connecting pin 30 is longer than the portion located closer to the relief portion 33 than the virtual plane S3. Therefore, in each connection pin 30, the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are arranged asymmetrically with respect to the respective third virtual surfaces S3. .

  In this case, in each connection pin 30, the press-fit portions of the inner circumferential surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are symmetrically arranged with respect to the first virtual surface S1. The pair of connection pins 30 are mutually arranged such that the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the pair of press-fit portions 32 are arranged symmetrically with respect to the second virtual surface S2.

  Also in the embodiment shown in FIG. 10, the symmetry regarding the press-fit portions of the inner peripheral surface of the first pin insertion hole 21 and the pair of press-fit portions 32 is the same as that of the first pin insertion hole 21 described in the first embodiment. Similar to the symmetry of the inner circumferential surface and the press-fit portion of the pair of press-fit portions 32, the first virtual surface S1 and the second virtual surface S2 are maintained. Due to this symmetry, the variation in the juxtaposed direction of the juxtaposed centers of the pair of rods 12 in the end plate 20 is restrained.

In the first embodiment, the shapes of the press-fit portions of the inner circumferential surface of the first pin insertion hole 21 and the pair of press-fit portions 32 may be asymmetric.
In the second embodiment, the shapes of the press-fit portions of the inner peripheral surface of the second pin insertion hole 22 and the pair of press-fit portions 32A may be asymmetric.

  In each of the above embodiments, the material of the end plate 20 and the material of the guide block 11 may be the same material. Even in this case, for example, when the material of the jig attached to the end plate 20 is different from the material of the end plate 20 and the guide block 11, the expansion and contraction of the end plate 20 to which the jig is attached is also performed. Will follow expansion and contraction. Similarly, for example, when the material of the attachment target to which the guide block 11 is attached is different, the guide block 11 attached to the attachment target also performs expansion and contraction following the expansion and contraction of the attachment target. In such a case, as a result, the degree of expansion and contraction of the end plate 20 and the guide block 11 due to a change in ambient temperature will be different. However, according to the configuration of each of the above-described embodiments, occurrence of prying in the pair of rods 12 is suppressed.

  In each of the above embodiments, without making the inner circumferential surface of each rod hole 11a function as a bearing surface 11b for supporting each rod 12, a bearing member for supporting each rod 12 is separately provided inside each rod hole 11a. You may provide.

  In each of the above embodiments, even if the end plate 20 moves toward the step 12c with the deformation of each connecting pin 30, the end plate 20 may not be in contact with the step 12c.

  In each of the above embodiments, even if the end plate 20 moves in the direction in which the pair of rods 12 is juxtaposed along with the deformation of each connecting pin 30, the inner circumferential surface of the insertion hole 20a of the end plate 20 is the small diameter portion 12a. It may not be in contact with the outer peripheral surface.

In each of the above embodiments, the twin rod cylinder 10 may not have the retaining member 36.
In the first embodiment, either the first hole 21a or the second hole 21b may be eliminated. That is, the first pin insertion hole 21 may not be configured by the first hole 21a and the second hole 21b, and may be only one of the first hole 21a and the second hole 21b.

In the first embodiment, the fixing portion 31 may be fixed by being adhered to the second pin insertion hole 22 by, for example, an adhesive.
In the second embodiment, the first fixing portion 31A may be fixed by being adhered to the first hole 21a of the first pin insertion hole 21 by an adhesive, for example, or the second fixing portion 31B May be fixed by being adhered to the second hole 21 b of the first pin insertion hole 21 by an adhesive, for example.

In the first embodiment, the first and second inlay portions 35a and 35b may not be provided, and both ends of the connection pin 30 may not function as the inlay portions.
In each of the above embodiments, the pistons 13 may not be attached to the respective rods 12, and the pair of cylinder tubes 14 may not be provided. Then, a cylinder chamber is separately formed in the guide block 11, and a piston movable in the advancing and retracting direction of the pair of rods 12 is accommodated in the cylinder chamber by supplying and discharging the fluid to the cylinder chamber, and following the movement of the piston The pair of rods 12 may be moved.

  In each of the above embodiments, the pair of rods 12 may be moved by driving the motor.

  C1, C2: Clearance, 10: Twin rod cylinder (actuator), 11: Guide block, 11a: Rod hole, 11b: Bearing surface, 12: Rod, 12a: Small diameter portion, 12b: Large diameter portion, 12c: Stepped portion, DESCRIPTION OF SYMBOLS 20 ... End plate, 20a ... Insertion hole, 21 ... 1st pin insertion hole, 22 ... 2nd pin insertion hole, 30 ... Connection pin, 31 ... Fixed part, 31A ... 1st fixed part as a fixed part, 31B ... fixed Second fixed part as a part 32, 32A: Press-fit part, 34, 34A: Allowed space, 35a: First inlay part as in-row part 35b: Second inlay part as in-row part, 36: Detachment preventing member.

Claims (8)

A guide block having a pair of rod holes;
A pair of rods inserted in the respective rod holes so as to be able to project and retract respectively;
An end plate attached to the projecting end of the pair of rods;
A pair of connecting pins for connecting each of the rods and the end plate;
The end plate extends in a direction orthogonal to the pair of insertion holes into which the projecting end portions of the rods are respectively inserted and the direction in which the rods extend and retracts, A pair of first pin insertion holes respectively communicating with the insertion holes and into which the connection pins are respectively inserted;
The projecting end portions of the rods extend in a direction perpendicular to the direction in which the rods protrude and retract and perpendicular to the direction in which the rods are juxtaposed, and communicate with the first pin insertion holes, respectively. It has a second pin insertion hole into which the pins are respectively inserted
Each connecting pin is
A fixing portion fixed to one of the first pin insertion hole and the second pin insertion hole;
It exists in the part which becomes a pair in the up-and-down direction of the above-mentioned rod in the peripheral face of the above-mentioned connection pin, and is paired in the other side of the inner peripheral surface of the 1st pin insertion hole and the 2nd pin insertion hole And a pair of press-fit parts pressed into the part
A state in which the pair of press-fit parts are press-fit into the other inner peripheral surface of the first pin insertion hole and the second pin insertion hole inside the other of the first pin insertion hole and the second pin insertion hole An actuator characterized in that an allowance space is provided for allowing relative movement of the pair of rods in the arranging direction with respect to the other of the first pin insertion hole and the second pin insertion hole in the connection pin. . There is a pair of center axes of virtual cylinders through which press-fit portions of the other inner peripheral surfaces of the first pin insertion hole and the second pin insertion hole and the pair of press-fit portions pass,
Assuming that a virtual surface passing through the pair of central axes is a first virtual surface, the other inner peripheral surfaces of the first pin insertion hole and the second pin insertion hole and the pair of press-fit portions in each connection pin The press-fit portion of the is arranged symmetrically with respect to the first virtual surface,
The first pin insertion hole and the first pin insertion hole, wherein a virtual surface passing through the center between the pair of central axes in the direction in which the pair of rods are arranged and orthogonal to the first virtual surface is a second virtual surface. The press-fit portions of the other inner peripheral surface of the second pin insertion hole and the pair of press-fit portions are shaped so as to be arranged symmetrically with respect to the second virtual surface. Actuator.   The actuator according to claim 1 or 2, wherein both end portions of each of the connection pins are inlay portions with respect to the first pin insertion holes.   The actuator according to any one of claims 1 to 3, wherein an inner circumferential surface of each of the rod holes functions as a bearing surface for supporting the respective rods. Each rod has a small diameter portion which is a projecting end portion inserted into the insertion hole, a large diameter portion whose outer diameter is larger than the small diameter portion, an outer peripheral surface of the small diameter portion and an outer peripheral surface of the large diameter portion And a step to connect the
The stepped portion is disposed to face the end plate with a gap therebetween,
The actuator according to any one of claims 1 to 4, wherein the end plate is capable of coming into contact with the stepped portion. There is a gap between the outer peripheral surface of the projecting end and the inner peripheral surface of the insertion hole,
The actuator according to any one of claims 1 to 5, wherein an outer peripheral surface of the projecting end portion and an inner peripheral surface of the insertion hole can be in contact with each other.   The actuator according to any one of claims 1 to 6, further comprising a retaining member for preventing removal of the connection pin from the first pin insertion hole and the second pin insertion hole. .   The actuator according to any one of claims 1 to 7, wherein the actuator is a twin rod cylinder that moves the pair of rods by fluid pressure.

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