JP2019119018A - Gripping device and industrial robot - Google Patents

Abstract

To provide a gripping device which can grip various work-pieces by simple control, and an industrial robot.SOLUTION: A gripping device comprising: a bag-like gripping body 32 having a palm part 33, and a first finger part 34 which is so provided around the palm part 33 as to project, and falls toward the palm part 33 by deforming the palm part 33 in a thickness direction by vacuum suction; an elastic part 53 which is provided in the first finger part 34; and a shape holding part 47 which prevents contraction of an outer periphery of the palm part 33. The gripping body 32 further has a second finger part 35 which is so provided as to be opposite to the first finger part 34 with the palm part 33 interposed therebetween. A gas circulation part 36, in which a gas can be circulated between an interior and an exterior of the gripping part 32, is formed on the second finger part 35.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a gripping device and an industrial robot.

  A two-finger type gripper (for example, Patent Document 1) is used as a gripping device intended to grip a work. The two-fingered gripper is used as an industrial robot because its operation is relatively simple.

  In order to improve the followability to the shape of a work, a five-finger type gripping device having a mechanism close to the shape of a human hand has been studied (for example, Patent Document 2). The five-finger type gripping device realizes complex motion close to human hands by using a finger having a plurality of joints.

JP, 2009-125851, A JP 2012-192496 A

  However, the gripping device of Patent Document 1 may not be able to grip workpieces having different shapes in a versatile manner. In the gripping device of Patent Document 2, the operation mechanism and the control mechanism are very complicated, and the complexity thereof makes the introduction difficult. Specifically, in the gripping device disclosed in Patent Document 2, adjustment of the gripping force for workpieces of different sizes is difficult, and calibration is necessary to perform gripping operations according to individual workpieces, and a hand system Is not practical because it is complicated.

  An object of the present invention is to provide a gripping device and an industrial robot that can grip various workpieces with simple control.

  A gripping device according to the present invention includes a palm portion, and a first finger portion which is provided protruding around the palm portion and which falls toward the palm portion by deforming the palm portion in the thickness direction by vacuum suction. And an elastic portion provided in the first finger portion, and a shape holding portion for preventing contraction of the outer periphery of the palm portion, the grip body sandwiching the palm portion. And a second finger portion provided opposite to the first finger portion, wherein the second finger portion is provided with a gas circulation portion through which gas can flow between the inside and the outside of the grip body. It is characterized by being.

  An industrial robot according to the present invention is characterized in that the holding device is provided.

  According to the present invention, when the gas circulation unit communicating with the inside of the grip body is closed by vacuum suction, the inside of the grip body is decompressed, and the palm portion is deformed in the thickness direction to start the gripping operation. Various workpieces can be gripped by simple control.

It is a schematic diagram which shows the example of the industrial robot to which the holding | gripping apparatus which concerns on 1st Embodiment is applied. It is a perspective view showing a grasping device concerning a 1st embodiment. It is a partial end elevation showing a grasping device concerning a 1st embodiment. It is a partial end elevation showing a state where gas in the inner space is sucked. It is a partial end elevation showing the state where the air intake was blocked by the work. It is a partial end elevation showing a state where a work is gripped. It is a partial end elevation showing a grasping device concerning a 2nd embodiment. It is a fragmentary end elevation showing the state where suction of the gas of interior space of a grasping device concerning a 2nd embodiment is carried out. It is a partial end elevation showing movement to a grasping position of a grasping device concerning a 2nd embodiment. It is a partial end elevation showing the state where the gas circulation part of the grasping device concerning a 2nd embodiment was closed. It is a fragmentary end elevation showing the state where a work was grasped by a grasping device concerning a 2nd embodiment. It is a partial end elevation showing movement of a work by a grasping device concerning a 2nd embodiment. It is a partial end elevation showing a grasping device concerning a 3rd embodiment. It is a partial end elevation showing a grasping device concerning a 4th embodiment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1. First embodiment (whole configuration)
FIG. 1 shows the configuration of an industrial robot 12 to which the gripping device 10 according to the first embodiment is applied. The industrial robot 12 is an orthogonal robot, and includes a rail 14, a moving body 16 moving along the rail 14, and an air cylinder 18 fixed to the moving body 16. The moving body 16 is provided so as to be movable in the XY axis direction in the drawing.

  The air cylinder 18 has a cylinder tube 19 and a piston rod 20 provided so as to be movable back and forth relative to the cylinder tube 19. Air cylinder pipes 21 and 22 are provided in the cylinder tube 19. The piston rod 20 can be advanced and retracted with respect to the cylinder tube 19 by supplying and discharging gas through the air cylinder pipes 21 and 22.

  A gripping device 10 is attached to the end of the piston rod 20 via a rotation mechanism 23. The rotation mechanism 23 shown in FIG. 1 is an example of a mechanism for rotating the gripping device 10, and may be designed as appropriate.

  The rotation mechanism 23 has a rotation shaft 23a. The axial direction of the rotating shaft 23a is the Y-axis direction in the drawing in the present embodiment. The rotating shaft 23 a is connected to the gripping device 10 via the connecting rod 24. Although not shown, the rotation shaft 23a has, for example, an adjustment screw, and is adjusted by the adjustment screw after adjusting the rotation angle θ. The rotation angle θ is the angle between the piston rod 20 and the connecting rod 24. In the present embodiment, the rotation angle θ is in the range of 90 ° to 270 °. In the case of this figure, the rotation angle θ is 100 °.

  The industrial robot 12 can hold the work W placed on the belt surface 25 a of the belt conveyor 25 and conveyed by the holding device 10 and can move in the X-axis, Y-axis, and Z-axis directions. The belt conveyor 25 is a transport path of the work W. It is preferable that the workpiece | work W is a thing in which the clearance gap G is formed between the surface on the downstream side of the belt conveyor 25 among lower surfaces, and the belt surface 25a. In the drawing, the work W shows a bag containing a powder or a granular material.

  The gripping device 10 includes a case 30 connected to the connecting rod 24 and a gripping body 32 fixed to the case 30. In the gripping device 10, the case 30 side is the upper side, and the gripping body 32 side is the lower side. The grip body 32 has a palm portion 33, a first finger portion 34 and a second finger portion 35, which are integrally formed. The details of the gripping device 10 will be described later using another drawing.

  One end of a pipe 26 communicating with the inside of the grip main body 32 is connected to the case 30. The other end of the pipe 26 is connected to the pressure pump and the three-way valve, not shown, for example, via a switching valve. The three-way valve has a vacuum port, an air supply / exhaust port, an air release port (all not shown), the vacuum port is connected to the vacuum pump, the air supply / discharge port is connected to the pipe 26, and the air release port is connected to the outside. Although not shown, the pressure pump, the vacuum pump, the three-way valve, and the switching valve are electrically connected to, for example, a controller, and are controlled by the controller.

  The grip body 32 is provided below the case 30. The grip body 32 is formed of a material having air tightness and elasticity. The gripping body 32 is preferably formed of a material having a restoring force. As a material of the grip body 32, for example, an elastic resin or rubber is used. The hardness of the grip body 32 may be appropriately designed according to the application. The hardness of the grip body 32 is measured by a type A durometer in accordance with Japanese Industrial Standard JIS K6253. The hardness of the grip body 32 is preferably about 60 to 90, and is 60 in the present embodiment.

  As shown in FIG. 2, the grip body 32 has a palm portion 33 and a first finger portion 34 provided to protrude around the palm portion 33. The palm portion 33 is formed in a disk shape, and the inner surface and the outer surface of the central portion are flat surfaces. The first finger 34 has a columnar shape in the present embodiment. The external shape of the first finger portion 34 can be appropriately selected, and may be, for example, a cylinder, a triangular prism, a quadrangular prism, a cone, a triangular pyramid, a quadrangular pyramid, a truncated cone, a quadrangular pyramid, a plate, or the like. Although only one first finger portion 34 is provided in the present embodiment, two or more first finger portions 34 may be provided. When two or more first fingers 34 are provided, the outer diameter shape of each first finger 34 may be all the same, or some or all may be different.

  The grip body 32 further includes a second finger 35 provided opposite to the first finger 34 across the palm portion 33. The second finger portion 35 is formed in a thin plate shape, and in the present embodiment, is in the form of a spatula. The second finger portion 35 has a distal end side wider than the proximal end side. The thickness of the distal end side of the second finger portion 35 is smaller than the thickness of the proximal end side. In the present embodiment, the width of the second finger portion 35 gradually increases and the thickness gradually decreases toward the distal end side. The tip of the second finger 35 is preferably sharp.

  The second finger portion 35 is formed with a gas flow portion 36 through which gas can flow between the inside and the outside of the grip body 32. The gas flow portion 36 has an air inlet 36 a formed on the surface of the second finger 35. In the case of the present embodiment, the intake port 36 a is formed on the inner surface facing the palm portion 33 of the second finger portion 35. The intake port 36 a is formed on the tip end side of the second finger 35 and at the center in the width direction of the second finger 35. The shape of the intake port 36a is a quadrangle in FIG. 2, but a circular shape, an elliptical shape, a polygonal shape, or the like can be appropriately selected. The size and the number of the inlets 36 a may be appropriately designed in accordance with the size of the work W or the like.

  The gripping device 10 will be specifically described with reference to FIG. The grip body 32 is in the form of a bag whose upper side is open, and the opening is closed by the case 30. A space surrounded by the case 30 and the inner surface of the grip body 32 is an internal space 44. Although the thickness of the grip body 32 is 1 mm in this embodiment, it may be designed as appropriate. In the present embodiment, the length of the first finger 34 is shorter than the length of the second finger 35.

  Elastic portions 53 and 54 are provided in the first finger portion 34 and the second finger portion 35, respectively. The elastic parts 53 and 54 are integrally formed with each of the first finger part 34 and the second finger part 35 in the present embodiment. The proximal end portion 53 a of the elastic portion 53 is curved, for example, so as to be smoothly connected to the inner surface of the palm portion 33. The proximal end 54 a of the elastic portion 54 has, for example, the same shape as the proximal end 53 a, and is curved so as to be smoothly connected to the inner surface of the palm portion 33.

  The gas flow portion 36 has a flow path 36b provided between the intake port 36a and the base end 54a. The intake port 36 a communicates with the internal space 44 via the elastic portion 54 by the flow path 36 b. Although the shape of the flow path 36b is a quadrangle matched to the intake port 36a in the present embodiment, it may be appropriately selected from a circular shape, an elliptical shape, a polygonal shape, and the like. Although the size of the flow path 36b is a size matched to the intake port 36a in the present embodiment, it may be designed as appropriate.

  The case 30 is connected to the connecting rod 24. The case 30 shown in FIG. 3 is an example, and may be designed as appropriate.

  The case 30 has a case body 38 and a support 39. The case body 38 is disk-shaped and has a joint portion 42 to which the pipe 26 is connected. The joint portion 42 is provided in a through hole (not shown) formed in the case main body 38.

  The support 39 includes a support 39a for supporting the grip body 32, a flange 39b provided on the upper end of the support 39a, and a disk 39c provided on the lower end of the support 39a. In the present embodiment, the support 39 is formed integrally with the support portion 39a, the flange portion 39b, and the disk portion 39c. The support 39 may be formed by bonding the support portion 39a, the flange portion 39b, and the disk portion 39c which are separately formed using an adhesive or the like. The support 39 is formed of a rigid material which is not deformed by reduced pressure. As a material of the support 39, for example, hard resin, metal or the like is used.

  The support portion 39 a is accommodated in the grip body 32 and supports the grip body 32 on the outer peripheral surface. As a method of attaching the grip body 32 to the support portion 39a, for example, a method of applying an adhesive to the entire circumferential direction of the outer peripheral surface of the support portion 39a and adhering the grip body 32 to the support portion 39a via the adhesive Is used. Thereby, the drop-off | omission from the support part 39a of the holding body 32 and the distribution | circulation of gas between the outer peripheral surface of the support part 39a and the inner surface of the holding body 32 are prevented. The outer diameter of the support portion 39a may be slightly larger than the opening diameter of the grip body 32, and the outer peripheral surface of the support portion 39a may be attached in close contact with the inner surface of the grip body 32 using the elasticity of the grip body 32. . The shape of the support portion 39a is cylindrical in the present embodiment, but is not limited to this and may be appropriately designed. In the case of using the attachment method utilizing the elasticity of the grip main body 32, it is preferable that the support portion 39a be formed in a cylindrical shape.

  The flange portion 39b protrudes outward in the radial direction of the support portion 39a, and is fixed to the lower surface of the case main body 38 via a packing (not shown) using fastening means (not shown), for example, a screw.

  An opening 41 is formed at the center of the disc 39c. The opening 41 is for circulating a gas between the support 39 a and the grip body 32. The position where the opening 41 is formed is not limited to the center of the disc 39 c and may be appropriately designed.

  Below the case 30, a shape holding portion 47 for holding the shape of the outer peripheral surface 46 of the palm portion 33 and a finger holding portion 51 for holding the second finger portion 35 in an extended state are provided. The shape holding portion 47 is fixed to, for example, the disk portion 39c with an adhesive or the like. The shape holding portion 47 and the disk portion 39c may be an integral molded product. The shape holding portion 47 is formed of a hard material that does not deform due to pressure reduction. As a material of the shape holding part 47, hard resin, a metal, etc. are used, for example. The material of the shape holding portion 47 is not necessarily a kind of material, and may be a composite material in which different kinds of materials are combined.

  The shape holding portion 47 is a frame-shaped member having a circular guide hole 48 for receiving the palm portion 33 deformed upward, and a curved portion 50 outside the finger side end of the guide hole 48 in the axial direction. In the case of the present embodiment, the shape holding portion 47 is a cylindrical member further having a holding surface 49 for holding the outer peripheral surface 46 of the palm portion 33. The guide hole 48 is provided at the center of the shape holding portion 47 corresponding to the palm portion 33. The guide hole 48 permits deformation of the palm portion 33 in the thickness direction (vertical direction in FIG. 3). The size of the guide hole 48 may be appropriately designed, but is preferably approximately the same size as the palm portion 33. The holding surface 49 is an outer circumferential surface of the shape holding portion 47. The holding surface 49 is formed in a size capable of holding the outer peripheral surface 46. Since the deformation of the palm portion 33 in the direction orthogonal to the thickness direction is restricted by the holding surface 49, the contraction of the outer periphery of the palm portion 33 is prevented. The lower end of the holding surface 49 is connected to the upper end of the bending portion 50. The curved portion 50 is convex toward the outside. The curved portion 50 is provided between the proximal end portions 53a and 54a with a gap. A curved surface may be formed, for example, by chamfering at the tip of the curved portion 50, that is, at the tip of the shape holding portion 47 where the curved portion 50 and the guide hole 48 intersect at a surface. The chamfering process can be performed by shaving the tip of the shape holding portion 47 on the finger portion side to form an angular surface or a round surface. By chamfering the shape holding portion 47, breakage such as a chip at the tip can be prevented.

  The finger holding portion 51 is disposed in the guide hole 48 and has a contact surface 52 for suppressing deformation of a part of the palm portion 33 corresponding to the second finger portion 35. The finger holding portion 51 is provided with a gap between the contact surface 52 and the inner surface of the palm portion 33. In the present embodiment, the finger holding portion 51 is fixed to the disk portion 39c with an adhesive or the like. The finger holding portion 51 has substantially the same height as the shape holding portion 47, and the contact surface 52 and the curved portion 50 are smoothly connected. The contact surface 52 is formed in a size that can hold the second finger 35 in an extended state. The finger holding portion 51 is formed of a hard material that does not deform due to pressure reduction. As a material of the finger holding portion 51, for example, hard resin or metal is used. The material of the finger holding portion 51 is not necessarily a kind of material, and may be a composite material in which different kinds of materials are combined.

(Operation and effect)
The operation and effects of the industrial robot 12 provided with the gripping device 10 configured as described above will be described. In the industrial robot 12, the piston rod 20 is retracted into the cylinder tube 19, and the air cylinder 18 is contracted, and the surface on which the palm portion 33 of the grip body 32 is formed is vertically downward, that is, the rotation angle θ The state in which the angle is 180 degrees is taken as the initial state. In the initial state, the switching valve is in a state where the pipe 26 and the three-way valve are connected. In the gripping device 10, the pipe 26 is connected to the atmosphere release port via a three-way valve, and the pressure in the internal space 44 is atmospheric pressure.

  The industrial robot 12 positions the gripping device 10 above the transport path of the workpiece W by moving the movable body 16 along the rail 14. By setting the rotation angle θ to, for example, 100 °, the industrial robot 12 directs the surface on which the palm portion 33 of the grip body 32 is formed to the upstream side of the transport path. The second finger 35 is located below the first finger 34. Next, the industrial robot 12 extends the air cylinder 18 to a position where the tip of the second finger 35 can be inserted into the gap G by advancing the piston rod 20 from the cylinder tube 19.

  The three-way valve is then switched to the state where the air release port is shut off and the pipe 26 is in communication with the vacuum port. As shown in FIG. 4, the gas in the internal space 44 is sucked through the pipe 26. Along with this, the gas in the vicinity of the intake port 36 a flows into the internal space 44 through the gas circulation portion 36 and is exhausted through the pipe 26. The industrial robot 12 stands by in a state where the gas in the internal space 44 is continuously sucked. In the standby state, in the gripping device 10, the pressure in the internal space 44 is maintained at atmospheric pressure.

  The workpiece W transported from the upstream to the downstream of the transport path comes in contact with the tip of the second finger 35 of the holding device 10 waiting on the downstream side. At this time, the tip of the second finger 35 enters the gap G.

  As shown in FIG. 5, the work W rides on the second finger portion 35 and is adsorbed to the air inlet 36a. Thereby, the gas flow part 36 is closed by the work W. The work W is prevented from falling from above the second finger 35 by the suction force. The internal space 44 is sealed except for the through hole in which the joint portion 42 is provided by closing the gas flow portion 36 with the work W. Therefore, the internal space 44 is vacuum-sucked through the pipe 26 and depressurized.

  The shape of the outer peripheral surface of the palm portion 33 is held by the shape holding portion 47 of the grip body 32. Therefore, the palm portion 33 is deformed in the thickness direction so as to be sucked into the guide hole 48 by vacuum suction of the internal space 44. A part of palm part 33 corresponding to the 2nd finger part 35 contacts contact surface 52, and modification is held down. As a result, the second finger portion 35 is held in the extended state without falling toward the palm portion 33.

  As shown in FIG. 6, as vacuum suction of the internal space 44 is continued, a part of the palm portion 33 corresponding to the first finger portion 34 is further deformed in the thickness direction. The first finger portion 34 is pulled to the center of the palm portion 33 and deformed so as to fall toward the palm portion 33 starting from the contact portion between the holding surface 49 and the connecting portion of the bending portion 50. When the first finger 34 falls, the bending portion 50 and the proximal end portion 53a come in contact with each other. After the first finger portion 34 contacts the curved portion 50 and the base end portion 53a, the first finger portion 34 is further inclined toward the palm portion 33 starting from the contact portion between the tip end of the shape holding portion 47 and the base end portion 53a. It can be deformed. Although the curved portion 50 and the base end portion 54a are not in contact in this figure, the second finger portion 35 is pulled to the center of the palm portion 33 by the deformation of the palm portion 33, and the curved portion 50 and the base end portion 54a And may contact with each other.

  When the first finger 34 falls, the first finger 34 and the surface of the workpiece W come in contact with each other. In the case of the present embodiment, the gripping device 10 grips the workpiece W in such a manner that the first finger portion 34 contacts the upper surface of the workpiece W and the second finger portion 35 contacts the lower surface of the workpiece W.

  Next, the industrial robot 12 retracts the piston rod 20 into the cylinder tube 19 to contract the air cylinder 18, and the work W is moved to a predetermined movement destination by the movement of the movable body 16 and the movement of the rail 14.

  For example, the industrial robot 12 positions the gripping device 10 above a base (not shown) as a movement destination. The industrial robot 12 extends the air cylinder 18 until, for example, the second finger 35 contacts the base by the piston rod 20 advancing from the cylinder tube 19. Then, the switching valve is switched to the state in which the pipe 26 is in communication with the pressure pump. The compressed gas flows into the internal space 44 through the pipe 26 and the internal space 44 is pressurized. The palm portion 33 is pushed out of the guide hole 48 and returns to the original state. As a result, the palm portion 33 and the contact surface 52 do not contact with each other, compressed gas flows from the internal space 44 into the gas circulation portion 36, and the suction of the work W at the air inlet 36a is released. As the palm portion 33 returns to the original state, the first finger portion 34 rises, and the first finger portion 34 and the work W do not contact with each other. As a result, the work W slides down on the second finger 35 to the base. The compressed gas that has flowed into the internal space 44 is exhausted from the air inlet 36a, so that the grip body 32 is prevented from being ruptured.

  As described above, the industrial robot 12 can hold the workpiece W conveyed from the upstream side of the conveyance path by the holding device 10 waiting on the downstream side and move it to a desired position.

  As described above, in the holding apparatus 10, since the internal space 44 to be vacuum-sucked and the gas circulation unit 36 communicate, when the gas circulation unit 36 is closed, the internal space 44 is decompressed and the holding operation starts Be done. Therefore, since the gripping device 10 does not need control to start suction in response to the start of the gripping operation, it is possible to grip various workpieces by simple control only by vacuum suction of the internal space 44.

  The gripping device 10 can perform an adsorption operation for adsorbing the workpiece W to the intake port 36a only by exhausting through the pipe 26. The gripping operation is performed triggered by the adsorption. Therefore, the gripping device 10 does not need to separately provide a control system for performing the suction operation and the gripping operation, and there is no need to separately provide a sensor for detecting the workpiece W, so the configuration can be simplified. In addition, since the gripping device 10 does not need to perform control to switch the control system, and furthermore, it is not necessary to set teaching for the sensor and setting for teaching regarding the gripping operation, the control can be simplified.

  The gripping device 10 can more easily put the work W on the second finger 35 because the second finger 35 has a spatula shape.

  The gripping device 10 is held by the finger holding portion 51 in a state in which the second finger portion 35 is extended, so that the workpiece W can be placed on the second finger portion 35 more reliably. The second finger 35 is held in a stretched state by the deformation of a part of the palm 33 corresponding to the second finger 35 being suppressed by the contact surface 52.

  The gripping device 10 is compact because the finger holding portion 51 is disposed in the guide hole 48 and the internal space 44 is effectively used. In particular, the gripping device 10 does not have to be provided with an joint mechanism as in the conventional gripping device in order to move a part of the finger, and the moving finger itself is compact, so it is suitable for miniaturization.

  Since the length of the first finger 34 is shorter than the length of the second finger 35, the gripping device 10 can receive the work W more smoothly between the first finger 34 and the second finger 35. it can.

  The gripping device 10 suctions the work W more reliably by the intake port 36 a being formed on the tip end side of the second finger 35 and at the center in the width direction of the second finger 35. Can.

  In the gripping device 10, the elastic portions 53, 54 are integrated with the first finger portion 34 and the second finger portion 35, so that the movement of the elastic portions 53, 54 in the first finger portion 34 and the second finger portion 35 is Since this is prevented, the workpiece W can be gripped more reliably. Further, since the positional deviation between the intake port 36a and the flow path 36b is prevented, the workpiece W can be adsorbed more reliably.

  In the gripping device 10, the curved portion 50 is formed in the shape holding portion 47, so that the palm portion 33 deforms in the thickness direction while contacting the curved portion 50, so that the first finger portion 34 is continuous and Gently deform. Therefore, the gripping device 10 can grip the workpiece W softly. Incidentally, in the gripping device in which the curved portion is not formed in the shape holding portion, the finger portion is deformed so as to be buckled.

2. Second Embodiment A gripping device according to a second embodiment will be described. In the case of the second embodiment, the position of the intake port is different from that of the gripping device 10 according to the first embodiment. About the structure similar to the said 1st Embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  As shown in FIG. 7, the gripping device 60 according to the second embodiment has a second finger 62. A gas flow portion 63 is formed in the second finger portion 62. In this example, the intake port 63 a of the gas flow portion 63 is formed on the outer surface of the second finger portion 62 opposite to the inner surface facing the palm portion 33. In the case of this figure, the air intake port 63 a is formed substantially at the center of the second finger 62.

  In the second finger portion 62, an elastic portion 64 is provided. In the present embodiment, the elastic portion 64 is integrally formed with the second finger portion 62. The proximal end 64 a of the elastic portion 64 is curved, for example, so as to be smoothly connected to the inner surface of the palm portion 33.

  The gas circulation unit 63 has a flow passage 63b provided between the intake port 63a and the base end 64a. The intake port 63 a communicates with the internal space 44 via the elastic portion 64 by the flow path 63 b.

  The finger holding portion 51 is provided at a position corresponding to the second finger portion 62 in the guide hole 48, and the deformation of the palm portion 33 corresponding to the second finger portion 62 is suppressed by the contact surface 52.

  The gripping device 60 can be applied to the industrial robot 12 instead of the gripping device 10 of the first embodiment, and is moved by the rail 14, the movable body 16 and the air cylinder 18. An example of the gripping operation of the gripping device 60 will be described with reference to FIGS. 8 to 12.

  As shown in FIG. 8, the gripping device 60 is disposed above the mounting table 70 with the second finger 62 positioned lower than the first finger 34. The mounting table 70 is for mounting the work W, and is formed of, for example, an iron plate or the like. A slight gap is provided between the tip of the second finger 62 and the mounting table 70. The gripping device 60 is maintained in a state where suction of the gas in the internal space 44 is continued via the pipe 26. The gas in the vicinity of the intake port 63 a flows into the internal space 44 through the gas circulation portion 63 and is exhausted through the pipe 26. As a result, in the gripping device 60, the pressure in the internal space 44 becomes atmospheric pressure.

  As shown in FIG. 9, the gripping device 60 moves above the workpiece W and is positioned at a gripping position for gripping the workpiece W. The gripping position is set based on, for example, a detected signal obtained by detecting the position of the workpiece W by a sensor (not shown). In the case of this figure, the tip of the second finger portion 62 enters below the workpiece W, and the workpiece W is inclined relative to the mounting table 70.

  As shown in FIG. 10, the gripping device 60 moves downward so as to press the second finger 62 against the mounting table 70. The second finger portion 62 is bent toward the palm portion 33 by being pressed against the mounting table 70, and is deformed so as to fall from a contact portion between the holding surface 49 and the connecting portion of the bending portion 50. The deformation of the second finger portion 62 blocks the gas flow portion 63. In this example, the base end portion 64 a side of the elastic portion 64 in the gas flow portion 63 is closed. By closing the gas flow part 63, the internal space 44 is sealed. The enclosed internal space 44 is depressurized by vacuum suction. The palm portion 33 is deformed in the thickness direction so as to be sucked into the guide hole 48. A part of the palm portion 33 corresponding to the second finger portion 62 contacts the contact surface 52, and the deformation is suppressed.

  As shown in FIG. 11, as vacuum suction of the internal space 44 is continued, a part of the palm 33 corresponding to the first finger 34 is further deformed in the thickness direction. The first finger portion 34 is pulled to the center of the palm portion 33 and deformed so as to fall down, and contacts the upper surface of the workpiece W. Thereby, the gripping device 60 grips the work W between the first finger 34 and the second finger 62 so as to be held therebetween.

  As shown in FIG. 12, the gripping device 60 moves upward while gripping the workpiece W. The second finger 62 returns from the bent state to the extended state by releasing the pressing on the mounting table 70. At this time, the palm portion 33 is further deformed so as to be sucked into the guide hole 48 by the vacuum suction of the internal space 44, and the first finger portion 34 is further deformed toward the palm portion 33 while holding the work W. For this reason, the gripping device 60 can maintain the state in which the workpiece W is gripped between the first finger portion 34 and the second finger portion 62.

  As described above, the gripping device 60 starts the gripping operation when the vacuum-suctioned internal space 44 communicates with the gas circulating unit 63 and the gas circulating unit 63 is blocked by the deformation of the second finger unit 62. Therefore, it is not necessary to control to start suction in response to the start of the gripping operation.

  Since the suction device 63 is provided on the outer surface of the second finger 62, the holding device 60 can hold the workpiece W without suction. Therefore, the gripping device 60 can grip a wide variety of workpieces, such as workpieces smaller than the air inlet 63a, workpieces that are fragile and easily broken, and workpieces having asperities, so that the gripping device 60 is excellent in versatility.

  The gripping device 60 can grip the work W by operating to press the tip of the second finger 62 against the mounting table 70 as described above, and the proximal end of the outer surface of the second finger 62 The workpiece W can also be gripped by operating to press the portion corresponding to the portion 64 a onto the mounting table 70. The gripping device 60 can also grip the workpiece W by operating so as to close the suction port 63 a with the mounting table 70.

  The gripping device 60 can start the gripping operation even when the gas flow portion 63 is blocked by the weight of the workpiece W. In this case, as a material of the second finger portion 62 and the elastic portion 64, it is preferable to select a material that is deformed by the weight of the workpiece W and is hard enough to grip the workpiece W.

3. Third Embodiment A gripping device according to a third embodiment will be described. In the case of the third embodiment, the intake port is formed on the outer surface of the second finger portion in the same manner as the second embodiment, but the shape of the second finger portion is different.

  As shown in FIG. 13, the gripping device 80 according to the third embodiment has a second finger portion 82 formed in a columnar shape. A gas circulation portion 83 is formed in the second finger portion 82. In this example, the intake port 83 a of the gas flow portion 83 is formed on the outer surface of the second finger 82 opposite to the inner surface facing the palm portion 33. In the case of this figure, the air intake port 83a is formed substantially at the center of the second finger 82. The external shape of the second finger 82 can be selected as appropriate, and may be, for example, a cylinder, a triangular prism, a quadrangular prism, a cone, a triangular pyramid, a quadrangular pyramid, a truncated cone, a quadrangular pyramid, a plate, or the like.

  An elastic portion 84 is provided in the second finger portion 82. In the present embodiment, the elastic portion 84 is integrally formed with the second finger portion 82. The proximal end 84 a of the elastic portion 84 is curved, for example, so as to be smoothly connected to the inner surface of the palm portion 33.

  The gas flow portion 83 has a flow path 83b provided between the intake port 83a and the base end 84a. The intake port 83 a communicates with the internal space 44 via the elastic portion 84 by the flow path 83 b.

  Moreover, the holding | gripping apparatus 80 which concerns on 3rd Embodiment has the 1st finger part 92 formed in thin plate shape. In this example, the first finger portion 92 is formed in a spatula shape, and the thickness on the distal end side is smaller than the thickness on the proximal end side. The length of the first finger 92 is longer than the length of the second finger 82.

  An elastic portion 94 is provided in the first finger portion 92. In the present embodiment, the elastic portion 94 is integrally formed with the first finger portion 92. The proximal end 94 a of the elastic portion 94 is curved, for example, so as to be smoothly connected to the inner surface of the palm portion 33.

  The finger holding portion 51 is provided at a position corresponding to the second finger portion 82 in the guide hole 48, and the deformation of the palm portion 33 corresponding to the second finger portion 82 is suppressed by the contact surface 52.

  An example of the gripping operation of the gripping device 80 will be described. In this example, the gripping device 80 operates in the same manner as the gripping device 60 of the second embodiment. That is, the gripping device 80 is disposed above a mounting table (not shown) on which a work (not shown) is placed with the second finger 82 positioned lower than the first finger 92. The gripping device 80 is maintained in a state where suction of the gas in the internal space 44 is continued via the pipe 26. Next, after moving the gripping device 80 to the upper side of the workpiece, the gripping device 80 moves downward so as to press the second finger 82 on the mounting table. The second finger portion 82 is bent toward the palm portion 33 by being pressed against the mounting table, and is deformed so as to fall from a contact portion between the holding surface 49 and the connecting portion of the bending portion 50. The gas flow portion 83 is closed by the deformation of the second finger portion 82. The internal space 44 is sealed and decompressed by vacuum suction. The palm portion 33 is deformed in the thickness direction so as to be sucked into the guide hole 48. A part of the palm portion 33 corresponding to the second finger portion 82 contacts the contact surface 52, and the deformation is suppressed.

  By continuing the vacuum suction of the internal space 44, a part of the palm 33 corresponding to the first finger 92 is further deformed in the thickness direction. The first finger portion 92 is deformed so as to fall toward the palm portion 33 and contacts the upper surface of the workpiece. Thus, the gripping device 80 grips the work between the first finger portion 92 and the second finger portion 82 so as to be held therebetween.

  As described above, the gripping device 80 starts the gripping operation when the vacuum-suctioned internal space 44 communicates with the gas circulating unit 83 and the gas circulating unit 83 is blocked by the deformation of the second finger 82. Therefore, it is not necessary to control to start suction in response to the start of the gripping operation. Further, since the suction device 83 is provided with the suction port 83a on the outer surface of the second finger portion 82 and does not suction the workpiece, it can hold a wide variety of workpieces. Furthermore, since the first finger 92 is longer than the second finger 82 in the gripping device 80, the workpiece can be drawn toward the palm portion 33 by the gripping operation, and the workpiece can be gripped more reliably.

4. Fourth Embodiment A gripping device according to a fourth embodiment will be described. In the case of the fourth embodiment, the position of the air inlet of the second finger portion is different from that of the gripping device 80 according to the third embodiment.

  As shown in FIG. 14, the gripping device 100 according to the fourth embodiment has a second finger portion 102. A gas flow portion 103 is formed in the second finger portion 102. In this example, the intake port 103 a of the gas flow portion 103 is formed on the inner surface facing the palm portion 33 of the second finger portion 102. In the case of this figure, the intake port 103 a is formed on the tip end side of the second finger portion 102. The second finger portion 102 is shorter than the first finger portion 92. In other words, the length of the first finger 92 is longer than the length of the second finger 102.

  An elastic portion 104 is provided in the second finger portion 102. In the present embodiment, the elastic portion 104 is integrally formed with the second finger portion 102. The proximal end portion 104 a of the elastic portion 104 is curved, for example, to be smoothly connected to the inner surface of the palm portion 33.

  The gas flow portion 103 has a flow path 103b provided between the intake port 103a and the base end portion 104a. The intake port 103 a communicates with the internal space 44 via the elastic portion 104 by the flow path 103 b.

  An example of the gripping operation of the gripping device 100 will be described. In this example, the gripping device 100 operates in the same manner as the gripping device 10 of the first embodiment. That is, in a state where the gas in the internal space 44 is suctioned, the gripping device 100 stands by at the downstream side of the transport path (not shown) for transporting the work (not shown). In this state, the second finger portion 102 is located below the first finger portion 92.

  The workpiece conveyed from the upstream side to the downstream side of the conveyance path contacts the tip of the second finger portion 102, rides on the second finger portion 102, and is adsorbed to the air inlet 103a. As a result, the gas circulation unit 103 is blocked by the work. The internal space 44 is sealed and decompressed by vacuum suction. The palm portion 33 is deformed in the thickness direction so as to be sucked into the guide hole 48. A part of the palm portion 33 corresponding to the second finger portion 102 contacts the contact surface 52, and the deformation is suppressed.

  By continuing the vacuum suction of the internal space 44, a part of the palm 33 corresponding to the first finger 92 is further deformed in the thickness direction. The first finger portion 92 is deformed so as to fall toward the palm portion 33 and contacts the upper surface of the workpiece. Thereby, the gripping device 100 grips the work between the first finger 92 and the second finger 102 so as to be held therebetween.

  As described above, in the gripping device 100, the internal space 44 to be vacuum-suctioned is in communication with the gas circulating portion 103, and the suction port 103a is formed on the inner surface of the second finger portion 102. The same effect as that of the gripping device 10 can be obtained. In addition, since the first finger 92 is longer than the second finger 102 in the gripping device 100, the workpiece can be drawn toward the palm 33 by the gripping operation.

(Modification)
The present invention is not limited to the above embodiments, and can be appropriately modified within the scope of the present invention.

  The positions of the intake ports 36a, 63a, 83a, 103a can be changed as appropriate. For example, the air inlets 36a, 63a, 83a, 103a may be formed on the base end side of the second finger portions 35, 62, 82, 102, or formed on one side or the other side in the width direction. It is also good.

  The size of the palm portion 33, the shape, number and length of the first fingers 34 and 92, and the shape and number and length of the second fingers 35, 62, 82 and 102 may be changed according to the application. Good. For example, in the gripping device 10 according to the first embodiment, a plurality of first finger portions 34 may be provided around the palm portion 33 so as to grip the work W in a wrapping manner.

  The elastic parts 53, 54, 64, 84, 94, 104 are not limited to the case where they are integrally formed with the first finger parts 34, 92 or the second finger parts 35, 62, 82, 102, and the first finger parts 34, You may form separately from 92 or the 2nd finger part 35,62,82,102. In this case, the shape of the elastic parts 53, 54, 64, 84, 94, 104 has a fixed shape when inserted into the first finger 34, 92 or the second finger 35, 62, 82, 102. It may be any shape that can be held. The elastic parts 53, 54, 64, 84, 94, 104 are arranged so that there is no gap between the first finger 34, 92 or the inner surface of the second finger 35, 62, 82, 102. Is preferred. As a material of elastic parts 53, 54, 64, 84, 94, and 104, resin, rubber, etc. with elasticity are used, for example. The material of the elastic parts 53, 54, 64, 84, 94, 104 is not necessarily uniform, and may be a composite material in which different materials are combined. The elastic parts 53, 54, 64, 84, 94, 104 may contain additives such as a filler.

  The grip body 32 is not limited to the case where the palm portion 33, the first finger portion 34, 92, and the second finger portion 35, 62, 82, 102 are integrally formed, and may be formed separately. The material of the palm 33, the first finger 34, 92 and the second finger 35, 62, 82, 102 is not limited to the same material, but may be different. When the first finger 34, 92 and the second finger 35, 62, 82, 102 are made of a material that is hard enough to grip the workpiece W, the elastic portions 53, 54, 84, 84, 94 , 104 may be omitted.

  You may provide a nail | claw part in the front-end | tip of 2nd finger part 35,62,82,102. By providing the second finger 35, 62, 82, 102 with the claws, the work W can be more reliably placed on the second finger 35, 62, 82, 102. In addition to or instead of providing the claws on the second fingers 35, 62, 82, 102, the tips of the first fingers 34, 92 may be provided with claws. By providing the claws on the first fingers 34 and 92, the workpiece W can be gripped more reliably.

  The case 30 may be provided with a camera for photographing the workpiece W, a weight scale for measuring the weight of the workpiece W, a proximity sensor for measuring the distance between the workpiece W and the grip body 32, or the like.

  The shape holding portion 47 may be formed of a plurality of ring bodies arranged concentrically. Among the plurality of ring bodies, the hole of the innermost ring body is the guide hole 48. It is preferable that a curved surface be formed at the tip of the innermost ring body, and it is more preferable that a curved surface be formed at the tips of other ring bodies. The shape holding portion 47 can change the size of the guide hole 48 and the size of the outer shape by appropriately combining a plurality of ring bodies. Therefore, the size of the outer periphery of the grip main body 32 and the size of the palm portion 33 can be adjusted to a desired size by appropriately selecting the ring body. The shape holding portion 47 is not limited to a cylindrical member, and may be, for example, a frame-shaped member such as an oval, a polygon, or an oval in a plan view. The outer shape of the shape holding portion 47 can be appropriately changed to an oval, an oval, a polygon, or the like, and may be matched to the shape of the grip main body 32. The guide hole 48 is not limited to a circular shape, but may be a polygonal shape. Although the shape holding part 47 demonstrated the case where it had the holding surface 49 in this embodiment, this invention is not limited to this, You may abbreviate | omit the holding surface 49. FIG. When the holding surface 49 is omitted, it is preferable to separately use a holding member holding the outer peripheral surface 46 of the palm portion 33 instead of the holding surface 49.

  Although the example which pressurizes the internal space 44 in order to cancel adsorption | suction of the workpiece | work W was shown in said each embodiment, this invention is not limited to this, The state which switched the three-way valve and connected the piping 26 and the air release port As a result, the gas may be introduced into the internal space 44 through the pipe 26 and the internal space 44 may be returned to the atmospheric pressure.

  The work W is not limited to a bag but may be a food such as a hamburger, a sandwich, or a rice ball. The industrial robot 12 is not limited to the case of gripping the workpiece W conveyed by the belt conveyor 25 and the workpiece W placed on the mounting table 70, for example, the workpiece W sliding down from a table having an inclined surface, a thin transport container The workpiece W or the like accommodated in the housing may be gripped. The movement destination for moving the work W by the industrial robot 12 is not limited to the case of the base, and may be a paper bag, a packing machine, a thin-type conveyance container, or the like.

  Although the example of the orthogonal robot was shown as the industrial robot 12 in each said embodiment, this invention is not restricted to this, It is applicable to a SCARA robot, a vertical articulated robot, etc. FIG. That is, the gripping device 10 can grip the workpiece W and maintain the gripping state even when the industrial robot rotates around the X axis, the Y axis, and the Z axis.

10, 60, 80, 100 Gripping device 12 Industrial robot 26 Piping 32 Gripping body 33 Palm portion 34, 92 First finger portion 35, 62, 82, 102 Second finger portion 36, 63, 83, 103 Gas circulating portion 36a , 63a, 83a, 103a Intake port 44 Internal space 47 Shape holding part 48 Guide hole 51 Finger holding part 52 Contact surface 53, 54, 64, 84, 94, 104 Elastic part W Work

Claims (12)

Palm part,
A first finger which is provided so as to protrude around the palm portion, and is caused to fall toward the palm portion by deforming the palm portion in the thickness direction by vacuum suction;
A bag-like gripping body having
An elastic part provided in the first finger;
A shape holding portion for preventing contraction of the outer periphery of the palm portion;
Equipped with
The grip body further includes a second finger portion provided opposite to the first finger portion across the palm portion,
A gripping device characterized in that a gas flow portion through which gas can flow is formed between the inside and the outside of the holding body in the second finger portion.   The holding device according to claim 1, wherein the gas circulation portion has an air inlet on a surface of the second finger portion.   The holding device according to claim 2, wherein the air intake port is formed on an inner surface facing the palm portion of the second finger portion.   The holding apparatus according to claim 2, wherein the air inlet is formed on an outer surface of the second finger opposite to an inner surface facing the palm.   The said inlet is formed in the center part of the width direction of a said 2nd finger part, The holding | grip apparatus of any one of the Claims 2-4 characterized by the above-mentioned.   The holding device according to any one of claims 1 to 5, wherein the second finger has a spatula shape.   The holding apparatus according to any one of claims 1 to 6, further comprising a finger holding unit configured to hold the second finger unit in an extended state.   8. The holding device according to claim 7, wherein the finger holding portion has a contact surface for suppressing deformation of a part of the palm portion corresponding to the second finger portion. The shape holding portion has a guide hole for receiving the deformed palm portion,
The holding device according to claim 8, wherein the finger holding portion is disposed in the guide hole.   The holding device according to any one of claims 1 to 9, wherein a length of the first finger portion is shorter than a length of the second finger portion.   The said elastic part is integral with a said 1st finger part, The holding | grip apparatus of any one of the Claims 1-10 characterized by the above-mentioned.   An industrial robot provided with the gripping device according to any one of claims 1 to 11.

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