JP2020037146A - Holding device and conveying device - Google Patents

Abstract

To provide a holding device holding various-state objects to be held: and to provide a conveying device.SOLUTION: A holding device includes an adsorption pad, a pipe member, a first support mechanism, and a second support mechanism. The pipe member is communicated with the inside of the adsorption pad. The first support mechanism is disposed in a first direction of the adsorption pad to support the adsorption pad. The first support mechanism can make the adsorption surface of the adsorption pad turnable around a plurality of turning shafts. The second support mechanism is disposed in a first direction of the first support mechanism to support the first support mechanism. The second support mechanism enables the first support mechanism to be movable in a flat surface intersecting with the first direction. The plurality of turning shafts intersect with one another on the adsorption surface.SELECTED DRAWING: Figure 2

Description

  Embodiments of the present invention relate to a holding device and a transport device.

  2. Description of the Related Art A transport device including a holding device for holding a load (an object to be held) is used. The holding device is required to hold holding objects in various states.

JP 2009-214277 A JP 2011-169393 A JP 2011-643 A

  The problem to be solved by the present invention is to provide a holding device and a transfer device that can hold holding objects in various states.

  The holding device of the embodiment has a suction pad, a tube member, a first support mechanism, and a second support mechanism. The tube member communicates with the inside of the suction pad. The first support mechanism is arranged in the first direction of the suction pad and supports the suction pad. The first support mechanism is capable of rotating the suction surface of the suction pad around a plurality of rotation axes. The second support mechanism is arranged in the first direction of the first support mechanism, and supports the first support mechanism. The second support mechanism can make the first support mechanism movable within a plane intersecting the first direction. The plurality of rotation axes intersect on the suction surface.

1 is a schematic configuration diagram of a transport system including a transport device according to an embodiment. The side view of the holding device of an embodiment. FIG. 4 is an explanatory diagram of a plurality of links. The 1st model figure of the holding device of an embodiment. FIG. 4 is a second model diagram of the holding device according to the embodiment. FIG. 2 is a schematic configuration diagram of a first braking mechanism. FIG. 3 is a perspective view of a slide mechanism. FIG. 5 is a first explanatory diagram of a holding operation of the holding device of the embodiment. FIG. 5 is a second explanatory diagram of the holding operation of the holding device of the embodiment. FIG. 9 is a third explanatory view of the holding operation of the holding device of the embodiment. Explanatory drawing of the holding | maintenance operation | movement of the holding device of a comparative example. FIG. 4 is an explanatory diagram of a holding operation of the holding device according to the embodiment. FIG. 2 is a block diagram of the transfer device according to the embodiment. 5 is a flowchart of a transfer method. FIG. 9 is a perspective view of a holding device according to a first modification. FIG. 9 is a model diagram of a first support mechanism of a first modified example. FIG. 10 is a model diagram of a first support mechanism of a second modification. FIG. 10 is a model diagram of a first support mechanism of a third modification. FIG. 14 is a model diagram of a first support mechanism of a fourth modification. The schematic block diagram of the 1st brake mechanism of the 5th modification. FIG. 15 is a schematic configuration diagram of a first braking mechanism according to a sixth modification. FIG. 17 is a perspective view of a slide mechanism according to a seventh modification. The schematic block diagram of the holding device of the 8th modification.

Hereinafter, a holding device and a transport device according to an embodiment will be described with reference to the drawings.
In the holding device of the embodiment, the X direction, the Y direction, and the Z direction are defined as follows. The Z direction is a vertical direction, and the + Z direction (first direction) is an upward direction. The X direction (second direction) and the Y direction (third direction) are horizontal directions and are orthogonal to each other.

FIG. 1 is a schematic configuration diagram of a transport system including the transport device of the embodiment. The transport system 100 transfers the load (object to be held) G arranged in the load storage area 120 to a conveyor 140 or the like. The luggage storage 120 is a shelf, a basket, a box, or the like. In the luggage storage 120, the luggage G may be randomly stacked.
The transport system 100 includes a recognition device 130 and a transport device 110.

The recognition device 130 recognizes the state of the baggage G. The recognition device 130 recognizes the suction state and the holding state of the baggage G by the holding device 1. The recognition device 130 includes a plurality of image sensors 131, 132, and 133, and a recognition control unit 135.
The plurality of image sensors 131 to 133 are cameras and the like. The plurality of image sensors 131-133 capture images from different directions. The plurality of image sensors 131 to 133 transmit the captured image data to the recognition control unit 135. The recognition control unit 135 analyzes the image data and recognizes a state such as the position or posture of the package G. The recognition control unit 135 transmits the baggage information relating to the state of the baggage G to the transport device 110.

The recognition control unit 135 analyzes the image data and recognizes a state of the holding device 1 where the baggage G is sucked. The recognition control unit 135 recognizes the suction state from the shape of the suction pad of the holding device 1 or the like. The recognition control unit 135 transmits the suction information on the suction state of the baggage G to the transport device 110.
The recognition control unit 135 analyzes the image data and recognizes the holding state of the baggage G by the holding device 1. The recognition control unit 135 recognizes the holding state from the posture of the load G lifted by the holding device 1 or the shape of the suction pad. The recognition control unit 135 transmits the holding information regarding the holding state of the baggage G to the transport device 110.

The transfer device 110 holds the load G and transfers it to the conveyor 140. The transfer device 110 includes a robot arm (robot, manipulator) 111, the holding device 1, the air pressure adjusting device 70, and a transfer control unit (control unit) 115.
The robot arm 111 has a plurality of arm units 112 and a plurality of joint units 113. The robot arm 111 is formed by connecting a plurality of arm units 112 in series. The plurality of arms 112 are connected in series via the plurality of joints 113. The joint unit 113 relatively rotates the adjacent arm unit 112. For example, a first end of the robot arm 111 is connected to the ground. The holding device 1 is connected to the second end of the robot arm 111.
The air pressure adjusting device 70 adjusts the pressure of the air used in the holding device 1.

The transfer control unit 115 controls operations of the robot arm 111, the holding device 1, and the air pressure adjusting device 70. The transfer control unit 115 moves the holding device 1 to an arbitrary position by controlling the operation of the robot arm 111. The transport control unit 115 holds and releases the load G by controlling the operations of the holding device 1 and the air pressure adjusting device 70. Thereby, the transport device 110 holds the package G and transports it to the conveyor 140 or the like.
The holding device 1, the air pressure adjusting device 70, and the transport control unit 115 will be described later.

  The conveyor 140 is a belt conveyor, a roller conveyor, or the like. The conveyor 140 places and moves the load G. The operation of the conveyor 140 is controlled by the conveyor control unit 145.

The configuration of the holding device 1 will be described.
FIG. 2 is a side view of the holding device 1 according to the embodiment. The holding device 1 includes a suction pad 2, a tube member 4, a first support mechanism 5, and a second support mechanism 6.
The suction pad 2 is formed of an elastic material such as rubber. The suction pad 2 is formed in a bell shape and opens in the −Z direction. The opening of the suction pad 2 functions as a suction surface (suction opening surface) F.

  The suction pad 2 has a suction sensor 2s (see FIG. 13). The suction sensor 2s outputs a suction signal corresponding to the suction state of the suction pad 2. The suction sensor 2s is a pressure sensor, a distance sensor, or the like. The pressure sensor outputs a pressure signal corresponding to the pressure inside the suction pad 2. The distance sensor outputs a distance signal corresponding to the distance from the suction pad 2 to the load G. The suction state of the baggage G by the suction pad 2 is detected based on a suction signal such as a pressure signal or a distance signal.

  The tube member 4 is formed of an elastic material such as rubber. The tube member 4 is arranged in the + Z direction of the suction pad 2 and extends along the Z direction. The end of the pipe member 4 in the -Z direction is connected to the suction pad 2 via the lower joint 4a. The pipe member 4 communicates with the inside of the suction pad 2. The end of the pipe member 4 in the + Z direction is connected to the arm 112 (see FIG. 1) of the transfer device 110 via the upper joint 4b. The pipe member 4 communicates with an air pressure adjusting device 70 described below via a pipe along the arm 112.

The first support mechanism 5 is arranged in the + Z direction of the suction pad 2. An end in the −Z direction of the first support mechanism 5 is connected to the suction pad 2. The first support mechanism 5 supports the suction pad 2. The first support mechanism 5 is capable of rotating the suction surface F of the suction pad 2 around a plurality of rotation axes r, s, and t.
The first support mechanism 5 has a plurality of links 10, 20, 30, 40. The plurality of links 10-40 are connected in series via the plurality of connectors 18, 28, and 38. The plurality of connection portions 18-38 can make the plurality of links 10-40 rotatable around the plurality of rotation axes r, s, and t. The plurality of connecting portions 18-38 are arranged in the + Z direction of the suction pad 2.

  FIG. 3 is an explanatory diagram of a plurality of links. The plurality of links 10-40 include a first link 10, a second link 20, a third link 30, and a fourth link 40. Each of the plurality of connection portions 18-38 has a first connection portion 18, a second connection portion 28, and a third connection portion 38.

  The first link 10 has a first end portion 12, an intermediate portion 13, and a second end portion. The second link 20 has a first end 22, an intermediate part 23, and a second end 24. The third link 30 has a first end portion 32, an intermediate portion 33, and a second end portion. The fourth link 40 has a first end 42 and a second end 44. Each link is formed of a metal material or the like. The first end, the second end, and the intermediate portion of each link are each formed in a plate shape. An intermediate portion of each link connects between the first end and the second end.

  Assume three axes (r-axis, s-axis, t-axis) that are orthogonal to each other. The first end 12 of the first link 10 is arranged near an intersection CP of three axes. As shown in FIG. 2, the suction pad 2 is connected to the first end 12 of the first link 10.

  As shown in FIG. 3, the intermediate portion 13 of the first link 10 is arranged along the r-axis. The second end 14 of the first link 10 is arranged orthogonal to the r-axis. The first end 22 of the second link 20 is also arranged orthogonal to the r-axis. The second end 14 of the first link 10 and the first end 22 of the second link 20 are rotatably connected at a first connection portion 18. The first connection portion 18 connects the first link 10 and the second link 20 so as to be rotatable around an r-axis (first rotation axis).

  An intermediate portion 23 of the second link 20 connects between the first end 22 and the second end 24. The second end 24 of the second link 20 is arranged orthogonal to the s-axis. The first end 32 of the third link 30 is also arranged orthogonal to the s-axis. The second end 24 of the second link 20 and the first end 32 of the third link 30 are rotatably connected at a second connection portion 28. The second connecting portion 28 connects the second link 20 and the third link 30 so as to be rotatable around the s-axis (second rotation axis).

The intermediate portion 33 of the third link 30 connects between the first end 32 and the second end 34. The second end 34 of the third link 30 is arranged orthogonal to the t-axis. The first end 42 of the fourth link 40 is also arranged orthogonal to the t-axis. The second end 34 of the third link 30 and the first end 42 of the fourth link 40 are rotatably connected at a third connection 38. The third connecting portion 38 connects the third link 30 and the fourth link 40 so as to be rotatable around a t-axis (third rotation axis).
The second end 44 of the fourth link 40 is connected to the second support mechanism 6, as shown in FIG.

  FIG. 4 is a first model diagram of the holding device of the embodiment. The geometric structure of the first support mechanism 5 is represented by a triangular pyramid M3 with its vertex directed in the −Z direction. The intersection CP of the three axes r, s, and t that are orthogonal to each other is the vertex of the triangular pyramid M3. The three axes r, s, and t are ridge lines connected to the vertices of the triangular pyramid M3. The suction surface F is arranged at the vertex, and the connecting portions 18, 28, 38 are arranged on the ridge line. Each of the links 10, 20, 30 is arranged in order along one ridge line and the bottom edge of the triangular pyramid M3.

  FIG. 5 is a second model diagram of the holding device of the embodiment, and is a side view of FIG. The plurality of rotation axes r, s, and t of the first support mechanism 5 intersect on the suction surface F of the suction pad 2 in a state where the load G is not suctioned. That is, the intersection CP of the plurality of rotation axes r, s, t is arranged on the suction surface F. In the present application, the phrase “a plurality of rotation axes intersect on the suction surface” includes not only the case where the intersection CP is disposed on the suction surface F, but also the intersection CP at a slight distance from the suction surface F. The case where a CP is arranged is also included.

  The suction pad 2 is connected to the first end 12 of the first link 10 shown in FIG. Thereby, the suction surface F of the suction pad 2 is rotatable around the plurality of rotation axes r, s, t. As described later, the suction surface F is arranged along the surface of the load G in various states. Thereby, the holding device 1 can hold the load G in various states.

  FIG. 6 is a schematic configuration diagram of the first braking mechanism. The first support mechanism 5 has a first braking mechanism 5b that stops the rotation of the suction surface F. The first braking mechanism 5b is installed at each of the connection parts 18, 28, 38. The first braking mechanism 5b operates by air pressure. The first braking mechanism 5b is a jamming effect type braking mechanism. The first braking mechanism 5b has a bag 52 and braking particles 54 as a regulating member.

  The bag body 52 is formed of an elastic sheet or the like. The bag body 52 covers each connection part 18-38 airtightly. The inside of the bag body 52 communicates with an air pressure adjusting device different from the air pressure adjusting device 70. The bag body 52 can be expanded and contracted by air pressure. The inside of the bag body 52 may communicate with the pipe member 4. In this case, the inside of the bag body 52 communicates with the air pressure adjusting device 70 similarly to the pipe member 4.

  The regulating member is arranged inside the bag body 52. The restricting member comes into close contact with each connecting portion 18-38 by the contraction of the bag body 52, and restricts the rotation of each link 10-40. For example, the regulating member is the braking particle 54. The braking particles 54 are formed into small spheres by metal or resin. A large number of braking particles 54 are enclosed inside the bag 52.

When the inside of the bag 52 is depressurized by the air pressure adjusting device, the bag 52 contracts. A large number of the braking particles 54 sealed inside the bag body 52 adhere to the periphery of each connection part 18-38. Since the relative positions of the large number of braking particles 54 are fixed, the relative positions of the links 10-40 connected by the connection portions 18-38 are also fixed. Thereby, the rotation of each link 10-40 is regulated, and the rotation of the suction surface F is stopped.
The first support mechanism 5 stops the rotation of the suction surface F while the first brake mechanism 5b is operating. The first support mechanism 5 is capable of rotating the suction surface F around a plurality of rotation axes without operating the first brake mechanism 5b.

  The first support mechanism 5 may include a first sensor 5s (see FIG. 13) at each of the connection portions 18-38. The first sensor 5s outputs an angle signal corresponding to the rotation angle of each link 10-40 around each rotation axis r, s, t. The first sensor 5s is a potentiometer, an encoder, a photo interrupter, or the like. The angle of the suction surface F is calculated based on the angle signal output from the first sensor 5s. Further, a failure of the first braking mechanism 5b is detected based on the angle signal.

  The second support mechanism 6 is disposed in the + Z direction of the first support mechanism 5, as shown in FIG. The + Z direction end of the first support mechanism 5 is connected to the second support mechanism 6. The second support mechanism 6 supports the first support mechanism 5. The second support mechanism 6 can make the first support mechanism 5 movable in an XY plane orthogonal to the + Z direction.

The second support mechanism 6 has a case 7 and a slide mechanism 60.
The case 7 is formed in a rectangular parallelepiped shape. The case 7 opens in the -Z direction. The upper joint 4b of the pipe member 4 is fixed inside the + Z plane of the case 7. The outside of the + Z plane of the case 7 is connected to the robot arm 111 of the transfer device 110.

FIG. 7 is a perspective view of the slide mechanism. The slide mechanism 60 is arranged near the opening in the −Z direction inside the case 7. The slide mechanism 60 has a pair of first rails 61, a pair of second rails 62, and a slider 63.
The pair of first rails 61 are fixed inside the + Y plane and the −Y plane of the case 7. The pair of first rails 61 extend in the X direction. The pair of first rails 61 are arranged at predetermined intervals in the Y direction.
The pair of second rails 62 are arranged inside the pair of first rails 61 in the Y direction. The pair of second rails 62 is movable in the X direction along the pair of first rails 61. The pair of second rails 62 extend in the Y direction. The pair of second rails 62 are arranged at predetermined intervals in the X direction.

  The slider 63 is arranged inside the pair of second rails 62 in the X direction. The slider 63 is movable in the Y direction along the pair of second rails 62. The slider 63 is formed in a rectangular parallelepiped shape. A through hole 64 that penetrates in the Z direction is formed at the center of the slider 63. The pipe member 4 is passed through the through hole 64. The slider 63 is connected to the second end 44 (see FIG. 2) of the fourth link 40 of the first support mechanism 5. The first support mechanism 5 is movable in an XY plane by a slide mechanism 60.

The second support mechanism 6 has a second brake mechanism 6b (see FIG. 13) for stopping the movement of the first support mechanism 5. The second braking mechanism 6b is installed at a connection portion between the pair of first rails 61 and the pair of second rails. The second braking mechanism 6b is installed at a connecting portion between the pair of second rails and the slider 63. The second braking mechanism 6b operates by air pressure. The second braking mechanism 6b communicates with an air pressure adjusting device different from the air pressure adjusting device 70. The second braking mechanism 6b may communicate with the pipe member 4. In this case, the second braking mechanism 6b communicates with the air pressure adjusting device 70 as in the case of the pipe member 4.
The second support mechanism 6 stops the movement of the first support mechanism 5 in a state where the second brake mechanism 6b is operated. The second support mechanism 6 can make the first support mechanism 5 movable within the XY plane without operating the second brake mechanism 6b.

  The second support mechanism 6 may include a second sensor 6s (see FIG. 13). The second sensor 6s outputs a first signal corresponding to a relative position of the pair of second rails 62 with respect to the pair of first rails 61. The second sensor 6s outputs a second signal corresponding to the relative position of the slider 63 with respect to the pair of second rails 62. Based on the first signal and the second signal, the positions of the first support mechanism 5 connected to the slider 63 in the X and Y directions are calculated.

The operation of the holding device 1 will be described.
FIG. 8 is a first explanatory diagram of the holding operation of the holding device of the embodiment. FIG. 9 is a second explanatory diagram. FIG. 10 is a third explanatory diagram.
As shown in FIG. 8, the holding device 1 descends toward the load G in the -Z direction. The holding device 1 approaches the load G without operating the first braking mechanism 5b and the second braking mechanism 6b. The upper surface of the load G is inclined.

  As shown in FIG. 9, the holding device 1 comes into contact with the load G. The first braking mechanism 5b and the second braking mechanism 6b of the holding device 1 are not operating. The suction surface F is rotatable around a plurality of rotation axes r, s, and t. The suction surface F is movable in the XY plane. The suction surface F rotates and moves in accordance with the inclination of the upper surface of the load G. Thus, the suction surface F is arranged along the upper surface of the load G. When the pressure inside the suction pad 2 is reduced, the suction surface F suctions the upper surface of the load G.

  As shown in FIG. 10, the holding device 1 rises in the + Z direction while adsorbing the load G. Thereby, the holding device 1 holds the baggage G. The first support mechanism 5 and the second support mechanism 6 support the weight of the load G. The tube member 4 does not support the weight of the load G. Therefore, the holding device 1 holds the load G in a stable state.

FIG. 11 is an explanatory diagram of the holding operation of the holding device of the comparative example. The holding device 91 of the comparative example has the suction pad 2, the first support mechanism 5, and the second support mechanism 6. The suction surface F of the suction pad 2 is rotatable around a plurality of rotation axes of the first support mechanism 5. In the holding device 91, the intersection CP of the plurality of rotation axes is arranged to be separated upward from the suction surface F.
When the holding device 91 is lowered, the end point Q of the suction surface F comes into contact with the upper surface of the load G. On the upper surface of the load G, the end point Q of the suction surface F does not move due to friction. The suction surface F rotates around the intersection CP while the position of the end point Q is fixed. At this time, the slider 63 of the second support mechanism 6 that supports the first support mechanism 5 moves by the movement distance D1 in the −X direction.
In the holding device 91 of the comparative example, the intersection points CP of the plurality of rotation axes are arranged to be separated upward from the suction surface F. Therefore, the moving distance D1 of the slider 63 is large.

FIG. 12 is an explanatory diagram of the holding operation of the holding device of the embodiment. In the holding device 1 of the embodiment, the intersection CP of the plurality of rotation axes is arranged on the suction surface F.
When the holding device 1 is lowered, the end point Q of the suction surface F comes into contact with the upper surface of the load G. The suction surface F rotates around the intersection CP while the position of the end point Q is fixed. At this time, the slider 63 of the second support mechanism 6 supporting the first support mechanism 5 moves by the movement distance D2 in the + X direction.
In the holding device 1 of the embodiment, intersections CP of the plurality of rotation axes are arranged on the suction surface F. Therefore, the moving distance D2 of the slider 63 is small. The moving distance D2 of the holding device 1 of the embodiment is smaller than the moving distance D1 of the holding device 91 of the comparative example.

The holding device 1 of the embodiment employs the second support mechanism 6 having a smaller size than the holding device 91 of the comparative example, and can hold the baggage G having the same upper surface inclination angle. In other words, the holding device 1 of the embodiment employs the second support mechanism 6 having the same size as the holding device 91 of the comparative example, and can hold the load G having a large upper surface inclination angle. In the luggage storage 120, the luggage G may be randomly stacked. Therefore, the upper surface of the load G exhibits various inclination angles. The holding device 1 of the embodiment can hold the load G in various states.
Since the second support mechanism 6 having a small size can be employed, the holding device 1 is downsized. Since the intersection points CP of the plurality of rotation axes are arranged on the suction surface F, the suction surface F is smoothly inclined, and is arranged following the surface of the load G.

As shown in FIG. 2, the lower joint 4 a of the pipe member 4 is fixed to an end of the first support mechanism 5 in the −Z direction. The upper joint 4b of the pipe member 4 is fixed to an end of the second support mechanism 6 in the + Z direction. As described above, the pipe member 4 is formed of an elastic material.
In the original state where the holding device 1 does not hold the baggage G, the first support mechanism 5 takes a posture in which the suction surface F is arranged parallel to the XY plane. The second support mechanism 6 takes a posture in which the slider 63 is arranged at the center of the slide mechanism 60 in the X and Y directions.

When the suction surface F rotates following the surface of the load G, the posture of the first support mechanism 5 changes. Along with this, the tube member 4 is elastically deformed. When the suction surface F separates from the surface of the load G, the first support mechanism 5 returns to the original posture by the restoring force of the pipe member 4.
When the suction surface F rotates following the surface of the load G, the first support mechanism 5 moves in the horizontal direction, and the slider 63 of the second support mechanism 6 moves in the horizontal direction. Accordingly, the pipe member 4 passed through the through hole 64 of the slider 63 is elastically deformed. When the suction surface F separates from the surface of the load G, the second support mechanism 6 returns to the original posture by the restoring force of the tube member 4.

As described above, the first support mechanism 5 and the second support mechanism 6 return to the original posture by the restoring force of the pipe member 4. Since the first support mechanism 5 and the second support mechanism 6 are returned to their original positions, an elastic member other than the tube member 4 is not required. Therefore, an increase in the number of parts is suppressed.
In order to assist the restoring force of the pipe member 4, an elastic member may be arranged at the plurality of connecting portions 18, 28, 38. The elastic member is a torsion spring or the like.

FIG. 13 is a block diagram of the transport device of the embodiment. As described above, the transfer device 110 includes the robot arm 111, the holding device 1, the air pressure adjusting device 70, and the transfer control unit 115.
The robot arm 111 has a weight sensor 114. The weight sensor 114 is disposed between the robot arm 111 and the holding device 1. The weight sensor 114 outputs a weight signal corresponding to the weight of the load G held by the holding device 1.

The air pressure adjusting device 70 includes a pressure reducing device 72, a pressurizing device 74, and a switching valve 76.
The pressure reducing device 72 reduces the pressure of the air to a pressure lower than the atmospheric pressure. The pressure reducing device 72 is a vacuum pump or the like.
The pressurizing device 74 pressurizes air to a pressure higher than the atmospheric pressure. The pressurizing device 74 is a compressor or the like.
The switching valve 76 switches the communication destination of the suction pad 2 between the pressure reducing device 72 and the pressure device 74. The switching valve 76 can also cut off the communication between the suction pad 2 and the decompression device 72 and the pressure device 74.

  The transport control unit 115 is a microcomputer including a processor such as a CPU (Central Processing Unit) 116. The transport control unit 115 is realized by a processor such as the CPU 116 executing a program stored in the memory 117 or the auxiliary storage device 118, for example. Part or all of the transport control unit 115 may be realized by hardware such as an LSI (Large Scale Integration), an ASIC (Application Specific Integrated Circuit), or an FPGA (Field-Programmable Gate Array), or may be implemented by software. And hardware may cooperate.

  The transfer control unit 115 controls operations of the robot arm 111, the holding device 1, and the air pressure adjusting device 70. The transfer control unit 115 moves the holding device 1 to an arbitrary position by controlling the operation of the robot arm 111. The transport control unit 115 holds and releases the load G by controlling the operations of the holding device 1 and the air pressure adjusting device 70. The transfer control unit 115 switches the switching valve 76 of the air pressure adjusting device 70. The transport control unit 115 reduces the pressure inside the suction pad 2 by selecting the pressure reducing device 72 as the communication destination of the suction pad 2. Thereby, the holding device 1 holds the baggage G with the suction pad 2. The transport control unit 115 presses the inside of the suction pad 2 by selecting the pressing device 74 as a communication destination of the suction pad 2. Thereby, the holding device 1 releases the load G from the suction pad 2.

  The transport control unit 115 includes a suction control unit 151, a holding control unit 152, and a heavy load control unit 153 as functional units.

  The suction control unit 151 controls the holding device 1 to appropriately suction the baggage G. The suction control unit 151 detects a suction state of the suction pad 2 based on the suction signal received from the suction sensor 2s. The suction control unit 151 may detect the suction state based on the suction information received from the recognition control unit 135. When the suction control unit 151 determines that the suction state is inappropriate, the suction operation by the holding device 1 is performed again. That is, the suction control unit 151 temporarily releases the suction of the baggage G by the suction pad 2. The suction control unit 151 moves the holding device 1 to a different place and causes the suction pad 2 to re-suck the baggage G. The suction control unit 151 determines the suction state again. The suction control unit 151 repeats the above processing until it is determined that the suction state is appropriate.

  The suction control unit 151 may determine the suction state based on the inclination angle of the upper surface of the baggage G and the angle of the suction surface F. The inclination angle of the upper surface of the baggage G to be sucked by the suction pad 2 is detected by the baggage information output from the recognition control unit 135 (see FIG. 1). The angle of the suction surface F is calculated based on angle signals output from the first sensor 5s and the second sensor 6s. When the plurality of links 10-40 of the first support mechanism 5 are in contact with the obstacle, the suction surface F is not arranged along the upper surface of the load G. In this case, the angle of the suction surface F is different from the inclination angle of the upper surface of the load G. The suction control unit 151 determines that the suction state is inappropriate when the difference between the inclination angle of the upper surface of the baggage G and the angle of the suction surface F is equal to or greater than a predetermined angle.

  When restarting the suction operation, the suction control unit 151 may move the holding device 1 according to the state of the baggage G. The state of the package G is detected based on the package information output from the recognition control unit 135 (see FIG. 1). The suction control unit 151 detects a place where there is no obstacle from the state of the baggage G, and moves the holding device 1.

The holding control unit 152 controls the holding device 1 to stably hold the baggage G. There is a case where the suction pad 2 suctions a position away from the center of gravity of the load G. When the load G is lifted in this state, a bending moment or a shearing force acts on the suction pad 2, and the load G is easily detached from the suction pad 2. In this case, the holding device 1 cannot stably hold the load G.
The holding control unit 152 detects a holding state of the holding device 1 based on the suction signal received from the suction sensor 2s. The holding control unit 152 may detect the holding state based on the holding information received from the recognition control unit 135. When the holding control unit 152 determines that the holding state is inappropriate, the holding operation by the holding device 1 is performed again. That is, the holding control unit 152 temporarily releases the suction of the baggage G by the suction pad 2. The holding control unit 152 moves the holding device 1 to a different location and causes the suction pad 2 to re-suck the baggage G. The holding control unit 152 re-determines the holding state of the holding device 1. The holding control unit 152 repeats the above processing until it is determined that the holding state is appropriate.

  When restarting the holding operation, the holding control unit 152 may move the holding device 1 according to the state of the baggage G. The state of the package G is detected based on the package information output from the recognition control unit 135 (see FIG. 1). The holding control unit 152 estimates the position of the center of gravity of the load G from the state of the load G, and moves the holding device 1.

The heavy load control unit 153 controls the holding device 1 to stably transport the heavy load. When the load G is heavy, the posture of the load G during transportation becomes unstable. When the holding device 1 lifts the load G, the weight sensor 114 outputs a weight signal of the load G. The heavy object control unit 153 detects the weight of the baggage G based on the weight signal received from the weight sensor 114. When the weight of the load G is equal to or more than a predetermined weight, the heavy load control unit 153 determines that the load G is a heavy load. At this time, the heavy object control unit 153 operates the first braking mechanism 5b and the second braking mechanism 6b. Accordingly, the posture of the load G being transported is stabilized, and the holding device 1 transports the heavy load stably.
The heavy object control unit 153 may operate the first braking mechanism 5b and the second braking mechanism 6b when the load G is a heavy object and the transport speed of the holding device 1 is equal to or higher than a predetermined speed.

A transfer method using the transfer device 110 according to the embodiment will be described.
FIG. 14 is a flowchart of the transport method.
The transfer control unit 115 controls the operation of the robot arm 111 to lower the holding device 1 (S10). As shown in FIG. 1, the transport control unit 115 lowers the holding device 1 toward the load G arranged in the load storage area 120. The lowering stop position of the holding device 1 is determined by the baggage information output from the recognition control unit 135 (see FIG. 1). The holding device 1 may detect the contact with the baggage G based on the distance signal output from the distance sensor as the suction sensor 2s, and stop descending. The holding device 1 comes into contact with the load G without operating the first braking mechanism 5b and the second braking mechanism 6b. The suction surface F rotates and moves in accordance with the inclination of the upper surface of the load G. Thus, the suction surface F is arranged along the upper surface of the load G.

  The transfer control unit 115 controls the operation of the air pressure adjusting device 70 to reduce the pressure of the suction pad 2 (S12). Thereby, the suction pad 2 suctions the upper surface of the load G. The first braking mechanism 5b and the second braking mechanism 6b may be connected to the air pressure adjusting device 70 similarly to the suction pad 2. In this case, the first brake mechanism 5b and the second brake mechanism 6b operate simultaneously with the suction pad 2 sucking the load G.

  The suction control unit 151 determines whether the state of suction of the baggage G by the holding device 1 is appropriate (S14). If the determination in S14 is No, the suction control unit 151 restarts the suction operation by the holding device 1. That is, the suction control unit 151 controls the operation of the air pressure adjusting device 70 to press the suction pad 2 (S16). Thus, the suction pad 2 once releases the load G. The suction control unit 151 controls the operation of the robot arm 111 to move the holding device 1 to a different place (S18). Further, the suction control unit 151 re-performs the suction operation performed in S10 and subsequent steps. The suction control unit 151 repeats the above processing until the determination in S14 becomes Yes. Thereby, the baggage G is properly sucked.

  If the determination in S14 is Yes, the transport control unit 115 controls the operation of the robot arm 111 and raises the holding device 1 (S20). The holding device 1 lifts the load G without operating the first braking mechanism 5b and the second braking mechanism 6b. At this time, the first support mechanism 5 and the second support mechanism 6 are automatically displaced so that the load G is most stable. However, when the suction pad 2 sucks a position away from the center of gravity of the load G, the load G is held in an unstable state.

  The holding control unit 152 determines whether the holding state of the baggage G by the holding device 1 is stable (S22). When the determination in S22 is No, the holding control unit 152 restarts the holding operation by the holding device 1. That is, the holding control unit 152 controls the operation of the robot arm 111 to lower the holding device 1 (S24). The holding control unit 152 presses the suction pad 2 to temporarily release the baggage G (S26). The holding control unit 152 moves the holding device 1 to a different place (S28). Further, the holding control unit 152 re-executes the suction operation and the holding operation performed in S10 and subsequent steps. The holding control unit 152 repeats the above processing until the determination in S22 becomes Yes. Thereby, the load G is stably held.

  If the determination in S22 is Yes, the heavy object control unit 153 determines whether the baggage G is a heavy object having a predetermined weight or more (S30). When the determination in S30 is Yes, the heavy object control unit 153 operates the first braking mechanism 5b and the second braking mechanism 6b. Thereby, the load G is stably conveyed.

The transfer control unit 115 controls the operation of the robot arm 111 to transfer the load G held by the holding device 1 (S34). As shown in FIG. 1, the transport control unit 115 transports the load G to a destination such as the conveyor 140. The transfer control unit 115 controls the operation of the air pressure adjusting device 70 to press the suction pad 2 (S36). Thereby, the suction pad 2 releases the load G on the conveyor 140.
Thus, the processing of the transport method ends.

  As described in detail above, the holding device 1 of the embodiment includes the suction pad 2, the pipe member 4, the first support mechanism 5, and the second support mechanism 6. The pipe member 4 communicates with the inside of the suction pad 2. The first support mechanism 5 is disposed in the + Z direction of the suction pad 2 and supports the suction pad 2. The first support mechanism 5 is capable of rotating the suction surface F of the suction pad 2 around a plurality of rotation axes r, s, and t. The second support mechanism 6 is arranged in the + Z direction of the first support mechanism 5, and supports the first support mechanism 5. The second support mechanism 6 can make the first support mechanism 5 movable within an XY plane intersecting the + Z direction. The plurality of rotation axes r, s, and t intersect on the suction surface F.

  The suction surface F rotates according to the inclination of the surface of the load G. At this time, the second support mechanism 6 moves in the XY directions. The rotation axes r, s, and t of the suction surface F intersect on the suction surface F. Therefore, the amount of movement of the second support mechanism 6 in the XY directions is small. The suction surface F can hold a load G having a large surface inclination angle. Therefore, the holding device 1 can hold the load G in various states.

The first support mechanism 5 has a plurality of links 10, 20, 30, 40 connected in series via a plurality of connecting portions 18, 28, 38. The suction pad 2 is connected to ends of the plurality of links 10-40 in the -Z direction. Ends of the plurality of links 10-40 in the + Z direction are connected to the second support mechanism 6. The plurality of connecting portions 18-38 are capable of rotating the plurality of links 10-40 around the plurality of rotation axes r, s, and t. The plurality of connecting portions 18-38 are arranged in the + Z direction of the suction pad 2.
The plurality of connection portions 18-38 are not arranged around the suction pad 2. The plurality of connection portions 18-38 do not prevent the suction pad 2 from sucking a large load G. Therefore, the holding device 1 can hold the load G in various states.

The plurality of rotation axes include a first rotation axis r, a second rotation axis s, and a third rotation axis t that are orthogonal to each other. The plurality of connection parts include a first connection part 18, a second connection part 28, and a third connection part 38. The plurality of links include a first link 10, a second link 20, a third link 30, and a fourth link 40. The first connecting portion 18 is capable of rotating the first link 10 and the second link 20 around the first rotation axis r. The second connecting portion 28 is capable of rotating the second link 20 and the third link 30 around the second rotation axis s. The third connecting portion 38 is capable of rotating the third link 30 and the fourth link 40 around the third rotation axis t.
The suction surface F rotates at an arbitrary angle. Therefore, the holding device 1 can hold the load G in various states. Further, the configuration of the holding device 1 is simplified.

The tube member 4 extends from the suction pad 2 in the + Z direction. The tube member 4 can be elastically deformed in accordance with a change in the posture of the first support mechanism 5 and the second support mechanism 6.
When the suction surface F rotates according to the inclination of the surface of the load G, the postures of the first support mechanism 5 and the second support mechanism 6 change, and the tube member 4 is elastically deformed. When the suction surface F separates from the load G, the first support mechanism 5 and the second support mechanism 6 return to the original posture by the restoring force of the pipe member 4.

The first support mechanism 5 has a first braking mechanism 5b that stops the rotation of the suction surface F. The second support mechanism 6 has a second braking mechanism 6b that stops the movement of the first support mechanism 5.
By operating the first braking mechanism 5b and the second braking mechanism 6b, the load G can be stably transported even when the load G is heavy.

The first braking mechanism 5b and the second braking mechanism 6b communicate with the pipe member 4 and operate by air pressure.
Thus, the first brake mechanism 5b and the second brake mechanism 6b operate simultaneously with the suction of the load G by the suction pad 2. Further, the configuration of the holding device 1 is simplified.

The first braking mechanism 5b has a bag 52 and braking particles 54 as a regulating member. The bag body 52 covers the plurality of connecting portions 18, 28, 38. The bag body 52 can be expanded and contracted by air pressure. The braking particles 54 are arranged inside the bag body 52. The braking particles 54 come into close contact with the plurality of connecting portions 18-38 by the contraction of the bag body 52, and regulate the rotation of the plurality of links 10, 20, 30, 40.
Thereby, the first braking mechanism 5b is easily formed.

The second support mechanism 6 includes a pair of first rails 61, a pair of second rails 62, and a slider 63. The pair of first rails 61 extend in the X direction and are spaced apart in the Y direction. The pair of second rails 62 are arranged inside the pair of first rails 61 in the Y direction. The pair of second rails 62 is movable in the X direction along the pair of first rails 61. The pair of second rails 62 extend in the Y direction and are spaced apart in the X direction. The slider 63 is disposed inside the pair of second rails 62 in the X direction. The slider 63 is movable in the Y direction along the pair of second rails 62. The slider 63 supports the first support mechanism 5.
A pair of second rails 62 are arranged inside the pair of first rails 61 in the Y direction. The slider 63 is arranged inside the pair of second rails 62. Thereby, the thickness of the second support mechanism 6 is reduced in the Z direction.

The transfer device 110 according to the embodiment includes the holding device 1, the air pressure adjusting device 70, the robot arm 111, and the transfer control unit 115. The air pressure adjusting device 70 is connected to the pipe member 4 and adjusts the air pressure of the suction pad 2. The robot arm 111 moves the holding device 1. The transport control unit 115 controls the holding device 1, the air pressure adjusting device 70, and the robot arm 111 to control the suction, transport, and release of the load G by the holding device 1.
The transport device 110 can hold and transport the load G in various states by the holding device 1.

The first support mechanism 5 has a first braking mechanism 5b that stops the rotation of the suction surface F. The second support mechanism 6 has a second braking mechanism 6b that stops the movement of the first support mechanism 5. The transport control unit 115 sucks the load G by bringing the suction surface F into contact with the load G without operating the first braking mechanism 5b and the second braking mechanism 6b. The transport control unit 115 lifts the load G without operating the first braking mechanism 5b and the second braking mechanism 6b. The transport control unit 115 transports the load G with the first brake mechanism 5b and the second brake mechanism 6b activated.
When the suction surface F is brought into contact with the load G by not operating the first brake mechanism 5b and the second brake mechanism 6b, the suction surface F automatically rotates according to the inclination of the surface of the load G. When the load G is lifted, the first support mechanism 5 and the second support mechanism 6 are automatically displaced so that the load G is most stable. By operating the first braking mechanism 5b and the second braking mechanism 6b, when transporting the load G, the load G is transported in a stable state.

The transport control unit 115 activates the first braking mechanism 5b and the second braking mechanism 6b when the weight of the load G is equal to or greater than a predetermined weight.
Thus, when the load G is heavy, the load G is transported in a stable state.

The first support mechanism 5 has a plurality of links 10-40 connected in series via a plurality of connecting portions 18-38. The plurality of connecting portions 18-38 are capable of rotating the plurality of links 10-40 around the plurality of rotation axes r, s, and t. The holding device 1 has a first sensor 5s that outputs an angle signal corresponding to the rotation angles of the links 10-40 around the rotation axes r, s, and t. The transport control unit 115 detects the angle of the suction surface F based on the angle signal. When the difference between the angle of the surface of the load G to be sucked by the suction pad 2 and the angle of the suction surface F is equal to or larger than the predetermined angle, the transport control unit 115 restarts the suction of the load G by the holding device 1.
When the magnitude of the angle difference is equal to or larger than the predetermined angle, the holding state of the baggage G by the holding device 1 is inappropriate. By performing the suction of the load G again, the suction state of the load G becomes appropriate.

The holding device 1 of the embodiment has a suction pad 2, a tube member 4, a first support mechanism 5, and a second support mechanism 6. The pipe member 4 communicates with the inside of the suction pad 2. The first support mechanism 5 is disposed in the + Z direction of the suction pad 2 and supports the suction pad 2. The first support mechanism 5 is capable of rotating the suction surface F of the suction pad 2 around a plurality of rotation axes r, s, and t. The second support mechanism 6 is arranged in the + Z direction of the first support mechanism 5, and supports the first support mechanism 5. The second support mechanism 6 can make the first support mechanism 5 movable in an XY plane intersecting in the + Z direction.
Since the second support mechanism 6 is disposed at the end in the first direction, a wide moving area of the first support mechanism 5 is secured. Therefore, the holding device 1 can hold the load G in various states.

A modified example of the embodiment will be described. In the description of each modification, the description of the same parts as in the embodiment is omitted.
FIG. 15 is a perspective view of the holding device of the first modified example. In the holding device 1 of the embodiment shown in FIG. 2, the suction surface F can be rotatable around three axes r, s, and t. On the other hand, in the holding device 201 of the first modification shown in FIG. 15, the suction surface F can be rotatable around four axes r, s, t, and u.

  The holding device 201 has a first support mechanism 205. The first support mechanism 205 has a plurality of links 210, 220, 230, 240, 250 connected in series via a plurality of connectors 218, 228, 238, 248. The plurality of connecting portions 218-248 can make the plurality of links 210-250 rotatable around the plurality of rotation axes r, s, t, and u.

  The plurality of rotation axes include a first rotation axis r, a second rotation axis s, a third rotation axis t, and a fourth rotation axis u. The plurality of connection parts include a first connection part 218, a second connection part 228, a third connection part 238, and a fourth connection part 248. The plurality of links include a first link 210, a second link 220, a third link 230, a fourth link 240, and a fifth link 250.

  The first connection portion 218 is capable of rotating the first link 210 and the second link 220 around the first rotation axis r. The second connecting portion 228 is capable of rotating the second link 220 and the third link 230 around the second rotation axis s. The third connection portion 238 is capable of rotating the third link 230 and the fourth link 240 around the third rotation axis t. The fourth connecting portion 248 is capable of rotating the fourth link 240 and the fifth link 250 around the fourth rotation axis u.

  FIG. 16 is a model diagram of the first support mechanism of the first modification. The geometric structure of the first support mechanism 205 is represented by a quadrangular pyramid M4 with the vertex directed in the −Z direction. The intersection CP of the four axes r, s, t, and u is the vertex of the quadrangular pyramid M4. The four axes r, s, t, and u are ridge lines connected to the vertices of the quadrangular pyramid M4. A suction surface is arranged at the vertex, and a plurality of connecting portions are arranged on the ridge line. The plurality of links are arranged in order along one ridge line and the bottom edge of the quadrangular pyramid M4.

A plurality of rotation axes r, s, t, and u of the first support mechanism 205 shown in FIG. The suction surface F is rotatable around four axes r, s, t, and u. Thereby, the holding device 1 can hold the baggage G in various states.
The first support mechanism 205 of the first modified example has a larger number of rotating shafts, connecting portions and links as compared with the embodiment. Thereby, the first support mechanism 205 of the first modified example can arrange the suction surface F along the surface of the load G while freely avoiding an obstacle. Therefore, the holding device 201 of the first modified example can hold loads G in various states.

  The plurality of rotation axes of the holding device 1 include n rotation axes. The plurality of connection units have n connection units. The plurality of links have n + 1 links. n is an integer of 3 or more. The holding device 1 of the embodiment shown in FIG. 2 is a case where n = 3. The holding device 201 of the first modification shown in FIG. 15 is a case where n = 4. The following modified example 2-4 is a case where n is 5 or more.

  FIG. 17 is a model diagram of the first support mechanism of the second modification. The first support mechanism of the second modification can make the suction surface F rotatable around five axes r, s, t, u, and v. The geometric structure of the first support mechanism is represented by a pentagonal pyramid M5 with its vertex directed in the −Z direction. The intersection CP of the five axes r, s, t, u, and v is the vertex of the pentagonal pyramid M5. The five axes r, s, t, u, and v are ridge lines connected to the vertices of the pentagonal pyramid M5. A suction surface is arranged at the vertex, and a plurality of connecting portions are arranged on the ridge line. The plurality of links are arranged in order along one edge line of the pentagonal pyramid M5 and the edge of the bottom surface. The first support mechanism of the second modified example can arrange the suction surface along the surface of the load G while freely avoiding an obstacle.

  FIG. 18 is a model diagram of the first support mechanism of the third modification. The first support mechanism of the third modified example can make the suction surface F freely rotatable around six axes r, s, t, u, v, w. The geometric structure of the first support mechanism is represented by a hexagonal pyramid M6 whose apex is directed in the −Z direction. The intersection CP of the six axes r, s, t, u, v, w is the vertex of the hexagonal pyramid M6. Six axes r, s, t, u, v, and w are ridge lines connected to the vertices of the hexagonal pyramid M6. A suction surface is arranged at the vertex, and a plurality of connecting portions are arranged on the ridge line. The plurality of links are arranged in order along one ridge line and the bottom edge of the hexagonal pyramid M6. The first support mechanism of the third modified example can arrange the suction surface along the surface of the load G while freely avoiding an obstacle.

  FIG. 19 is a model diagram of the first support mechanism of the fourth modification. The first support mechanism of the fourth modified example can make the suction surface F freely rotatable around multiple axes. The geometric structure of the first support mechanism is represented by a cone MX whose apex is directed in the −Z direction. The intersection CP of many axes is the vertex of the cone MX. Multiple axes extend from the apex of the cone MX to the periphery of the bottom surface to form an inclined surface of the cone MX. A suction surface is arranged at the vertex, and a plurality of connecting portions are arranged on the inclined surface. The plurality of links are arranged in order along the periphery of the inclined surface and the bottom surface of the cone MX. The first support mechanism of the fourth modified example can arrange the suction surface along the surface of the load G while freely avoiding an obstacle.

FIG. 20 is a schematic configuration diagram of a first braking mechanism according to a fifth modification. The first braking mechanism 5b of the embodiment shown in FIG. 6 is a jamming effect type braking mechanism. On the other hand, the first braking mechanism 305b of the fifth modified example shown in FIG. 20 is a chuck type (gripper type) braking mechanism. The first braking mechanism 305b has a bag 352 and a chuck 354 as a regulating member.
When the inside of the bag 352 is depressurized by the air pressure adjusting device, the bag 352 contracts. The chuck 354 enclosed inside the bag body 352 is in close contact with the periphery of the plurality of connecting portions 18, 28, 38. For example, a chuck 354 having a groove on the inner surface is in close contact with the pivots of the plurality of connecting portions 18-38. Since the movement of the plurality of connecting portions 18-38 is restricted, the relative positions of the plurality of links connected in series via the plurality of connecting portions 18-38 are also fixed. Thus, the rotation of the plurality of links is restricted, and the rotation of the suction surface F is stopped.

  FIG. 21 is a schematic configuration diagram of a first braking mechanism according to a sixth modification. The first braking mechanism 405b of the sixth modification example shown in FIG. 21 is a rotation stopping type braking mechanism. The first braking mechanism 405b has a bag body 452, and a rotation suppressing part 454 and an engaging part 456 that constitute an engaging mechanism. The rotation suppressing portion 454 and the engaging portion 456 are respectively connected to a pair of links in the plurality of connecting portions 18, 28, 38. In a state where the rotation suppressing portion 454 and the engaging portion 456 are separated, the pair of links can rotate with each other. The rotation suppressing portion 454 has a plurality of pins 455 that can advance and retreat with respect to the engaging portion 456. The plurality of pins 455 are urged toward the engagement portion 456.

  When the inside of the bag 452 is depressurized by the air pressure adjusting device, the bag 452 contracts. The rotation suppressing portion 454 and the engaging portion 456 sealed inside the bag 452 approach each other. The engaging portion 456 pushes the plurality of pins 455 of the rotation suppressing portion 454 to engage with the rotation suppressing portion 454 at an arbitrary position. The plurality of pins 455 arranged around the engagement portion 456 regulate the rotation of the engagement portion 456. Since the rotation of the rotation suppressing portion 454 and the engaging portion 456 is restricted, the relative positions of the pair of links connected to the rotation suppressing portion 454 and the engaging portion 456 are also fixed. Thus, the rotation of the suction surface F stops.

  FIG. 22 is a perspective view of a slide mechanism according to a seventh modification. The slide mechanism 60 of the embodiment shown in FIG. 7 is a direct-acting type. On the other hand, the slide mechanism 560 of the seventh modified example shown in FIG. 22 is a rotary type. The slide mechanism 560 has a plurality of rotating members connected in series. The slide mechanism 560 has a first rotating member 561 arranged at a first end and a second rotating member 562 arranged at a second end. The first rotating member 561 is formed in a flat plate shape. The end of the first rotating member 561 in the + X direction is connected to the robot arm (external) 111 so as to be rotatable around the Z axis.

  The second rotating member 562 is formed in a flat plate shape. An end in the + X direction of the second rotating member 562 and an end in the -X direction of the first rotating member 561 are connected to be rotatable around a pin 563 extending in the Z direction. That is, the adjacent first rotation member 561 and second rotation member 562 are connected to be rotatable around the Z direction. A through-hole 564 that penetrates in the Z direction is formed at an end of the second rotating member 562 in the −X direction. The pipe member 4 is passed through the through hole 564. A second end 44 (see FIG. 2) of the fourth link 40 of the first support mechanism 5 is connected to an end of the second rotating member 562 in the −X direction. The first support mechanism 5 is movable in an XY plane by a slide mechanism 560.

FIG. 23 is a schematic configuration diagram of a transport device according to an eighth modification. The transfer device 701 according to the eighth modification includes a plurality of holding devices 1. The transfer device 701 includes a plurality of holding devices 1, a plurality of linear motion mechanisms 709, a base member 708, a robot arm (robot) 111, an air pressure adjusting device 70 (see FIG. 13), and a transfer control unit 115 (control Section, see FIG. 13).
The plurality of holding devices 1 are configured by arranging the holding devices 1 of the embodiment in an XY plane.
The plurality of translation mechanisms 709 are arranged in the + Z direction of the plurality of holding devices 1. The plurality of linear motion mechanisms 709 support the plurality of holding devices 1 movably in the + Z direction and the −Z direction.
The base member 708 is formed in a flat plate shape. The base member 708 is disposed in the + Z direction of the plurality of translation mechanisms 709, and supports the plurality of translation mechanisms 709.
The robot arm 111 is connected to the base member 708.

The air pressure adjusting device 70 has a plurality of switching valves 76. The plurality of switching valves 76 communicate with the pipe members 4 of the plurality of holding devices 1 respectively. The air pressure adjusting device 70 can individually adjust the air pressure of the suction pads 2 of the plurality of holding devices 1. Accordingly, the plurality of holding devices 1 are individually controlled to perform and stop the suction operation.
The transfer control unit 115 controls the plurality of holding devices 1, the air pressure adjusting device 70, and the robot arm 111. Accordingly, the transport control unit 115 controls the suction, transport, and release of the load G by the plurality of holding devices 1.

When the base member 708 approaches the load G, the plurality of linear motion mechanisms 709 expand and contract in the Z direction according to the unevenness of the surface of the load G. Thereby, the plurality of holding devices 1 move in the Z direction. Further, the suction surfaces F of the plurality of holding devices 1 rotate along the inclination of the surface of the load G. Thus, the transport device 701 can hold the load G having large irregularities on the surface.
Execution and stop of the suction operation of the plurality of holding devices 1 are individually controlled. Thereby, the transport device 701 can hold loads G of various sizes.

In the holding device of the embodiment, the first braking mechanism 5b and the second braking mechanism 6b operate by air pressure. On the other hand, the first braking mechanism and the second braking mechanism may be electric mechanisms.
In the holding device of the embodiment, the suction sensor 2s is disposed on the suction pad 2. On the other hand, a pressure sensor as the suction sensor 2s may be arranged in the air pressure adjusting device 70.
In the holding device of the embodiment, the pipe member 4 is arranged along the Z direction. On the other hand, the pipe members may be arranged along a plurality of links. Further, a cavity may be provided inside the plurality of links, and the pipe member may be arranged in the cavity.
In the holding device of the embodiment, an intermediate portion of the plurality of links 10, 20, 30, 40 is formed in a flat plate shape. On the other hand, the intermediate portion may be formed in a bent plate shape or a curved plate shape. Further, the intermediate portion may be formed in a straight rod shape, a bent rod shape, a curved rod shape, or the like.

  According to at least one embodiment described above, the rotation axes r, s, and t of the suction surface F intersect on the suction surface F. Thereby, the baggage G in various states can be held.

  Although several embodiments of the present invention have been described, these embodiments are provided by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in other various forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and equivalents thereof.

  F: suction surface, G: luggage (object to be held), r: first rotation axis, s: second rotation axis, t: third rotation axis, 1 ... holding device, 2 ... suction pad, 4 ... Pipe member, 5: first support mechanism, 5b: first brake mechanism, 5s: first sensor, 6: second support mechanism, 6b: second brake mechanism, 10: first link, 18: first connection portion, Reference numeral 20: second link, 28: second connecting portion, 30: third link, 38: third connecting portion, 40: fourth link, 52: bag body, 54: braking particles (restriction member), 61: first Rail 62, second rail 63, slider 70, air pressure adjusting device 110, transport device 111, robot arm (robot), 115 transport controller (control unit), 352 bag, 354 chuck Regulating member), 452: bag body, 454: rotation suppressing portion (engaging mechanism), 456: engaging portion (engaging mechanism), 56 ... first rotating member, 562 ... second rotating member, 701 ... transporting apparatus, 708 ... base member, 709 ... linear motion mechanism.

Claims (17)

Suction pads,
A pipe member communicating with the inside of the suction pad,
A first support mechanism that is arranged in a first direction of the suction pad, supports the suction pad, and is capable of rotating a suction surface of the suction pad around a plurality of rotation axes;
A second support disposed in the first direction of the first support mechanism, supporting the first support mechanism, and enabling the first support mechanism to be movable in a plane intersecting the first direction; And a mechanism,
The plurality of rotation axes intersect on the suction surface;
Holding device. The first support mechanism has a plurality of links connected in series via a plurality of connecting portions, a first end to which the suction pad is connected, and a second end connected to the second support mechanism. And
The plurality of connecting portions can make the plurality of links freely rotatable around the plurality of rotation axes,
The plurality of connection portions are arranged in the first direction of the suction pad.
The holding device according to claim 1. The plurality of rotation axes include a first rotation axis, a second rotation axis, and a third rotation axis that are orthogonal to each other,
The plurality of connection units include a first connection unit, a second connection unit, and a third connection unit,
The plurality of links include a first link, a second link, a third link, and a fourth link,
The first connection portion is capable of rotating the first link and the second link around the first rotation axis,
The second connecting portion is capable of rotating the second link and the third link around the second rotation axis,
The third connection portion is capable of rotating the third link and the fourth link around the third rotation axis.
The holding device according to claim 2. The plurality of rotation axes include n rotation axes,
The plurality of connection units have n connection units,
The plurality of links has n + 1 links;
n is an integer of 4 or more;
The holding device according to claim 2. The tube member extends from the suction pad in the first direction, and is elastically deformable with a change in posture of the first support mechanism and the second support mechanism.
The holding device according to claim 1. The first support mechanism has a first braking mechanism that stops rotation of the suction surface,
The second support mechanism includes a second brake mechanism that stops movement of the first support mechanism.
The holding device according to claim 1. A first braking mechanism and a second braking mechanism communicate with the pipe member and are operated by air pressure;
The holding device according to claim 6. The first braking mechanism includes:
A bag body that covers the plurality of connection portions and that can be expanded and contracted by air pressure,
A regulating member that is disposed inside the bag body and is in close contact with the plurality of connecting portions by contraction of the bag body, and regulates rotation of the plurality of links.
The holding device according to claim 6. The first braking mechanism includes:
A bag body that covers the plurality of connection portions and that can be expanded and contracted by air pressure,
An engagement mechanism arranged inside the bag body, connected to the plurality of links, engaged at an arbitrary position by contraction of the bag body, and restricting rotation of the plurality of links,
The holding device according to claim 6. The second support mechanism includes:
A pair of first rails extending in a second direction intersecting the first direction and spaced apart in a third direction intersecting the first direction and the second direction;
It is arranged inside the pair of first rails in the third direction, is movable in the second direction along the pair of first rails, extends in the third direction, and is separated in the second direction. A pair of second rails arranged
A slider that is disposed inside the pair of second rails in the second direction, is movable in the third direction along the pair of second rails, and supports the first support mechanism.
The holding device according to claim 1. The second support mechanism has a plurality of rotating members connected in series,
A pair of rotating members adjacent to each other in the plurality of rotating members are connected to be rotatable around the first direction,
The plurality of rotating members include a first rotating member disposed at a first end and connected to the outside, and a second rotating member disposed at a second end and supporting the first support mechanism. Have,
The holding device according to claim 1. A holding device according to any one of claims 1 to 11,
An air pressure adjusting device connected to the pipe member and adjusting the air pressure of the suction pad,
A robot for moving the holding device,
By controlling the holding device, the pneumatic pressure adjusting device and the robot, the control unit controls the suction, transfer and release of the holding object by the holding device,
Transport device. The first support mechanism has a first braking mechanism that stops rotation of the suction surface,
The second support mechanism has a second braking mechanism that stops the movement of the first support mechanism,
The control unit includes:
In a state where the first braking mechanism and the second braking mechanism are not operated, the suction surface is brought into contact with the holding object to suck the holding object,
Lifting the holding object in a state where the first braking mechanism and the second braking mechanism are not operated,
Transporting the holding object in a state where the first braking mechanism and the second braking mechanism are operated;
The transfer device according to claim 12. The control unit activates the first braking mechanism and the second braking mechanism when the weight of the holding target object is equal to or greater than a predetermined weight.
The transport device according to claim 13. The first support mechanism has a plurality of links connected in series via a plurality of connection portions,
The plurality of connecting portions can make the plurality of links freely rotatable around the plurality of rotation axes,
The holding device has a first sensor that outputs an angle signal corresponding to a rotation angle of the plurality of links around the plurality of rotation axes,
The control unit includes:
Detecting the angle of the suction surface based on the angle signal,
When the difference between the angle of the surface of the object to be held by the suction pad and the angle of the suction surface is equal to or greater than a predetermined angle, the suction operation of the object to be held by the holding device is performed again.
The transfer device according to claim 12. A plurality of holding devices configured by arranging the holding device according to any one of claims 1 to 11 in a plane intersecting the first direction,
A plurality of linear motion mechanisms arranged in the first direction of the plurality of holding devices, and supporting the plurality of holding devices movably in the first direction and the direction opposite to the first direction;
A base member that is arranged in the first direction of the plurality of translation mechanisms and supports the plurality of translation mechanisms;
A robot for moving the base member,
An air pressure adjusting device connected to the pipe member of the plurality of holding devices and capable of individually adjusting the air pressure of the suction pads of the plurality of holding devices,
By controlling the plurality of holding devices, the pneumatic pressure adjusting device and the robot, the control unit controls the suction, transfer and release of the holding object by the plurality of holding devices,
Transport device. Suction pads,
A pipe member communicating with the inside of the suction pad,
A first support mechanism that is arranged in a first direction of the suction pad, supports the suction pad, and is capable of rotating a suction surface of the suction pad around a plurality of rotation axes;
A second support disposed in the first direction of the first support mechanism, supporting the first support mechanism, and enabling the first support mechanism to be movable in a plane intersecting the first direction; And a mechanism,
Holding device.

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