JP2017222010A - Robot, robot retainer, object retainer, and machine work method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent misalignment of an object from being caused by a processing force of a tool when machine work is performed to the object by the tool in a state where a robot holds the object.SOLUTION: A robot 30 is used to hold an object 1 when machine work is performed to the object 1. The robot 30 includes: a holding device 5; an operation mechanism 7; and a robot side attachment/detachment mechanism 9. The holding device 5 holds the object 1. The holding device 5 is fixed to the operation mechanism 7. The operation mechanism 7 operates to move the holding device 5. The robot side attachment/detachment mechanism 9 is fixed to the holding device 5 or the operation mechanism 7. The robot side attachment/detachment mechanism 9 may be attached to a structure side attachment/detachment mechanism 17 provided at a structure 15 in a setting position.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a technique for machining an object while the object is gripped by a robot.

  When machining an object (for example, a workpiece) with a machine tool, a robot may be used for attaching the object to the machine tool (for example, Patent Document 1 below). In this case, first, the robot grasps an object placed at the standby place and moves the object to the machine tool. Thereafter, the object is gripped and fixed by the chuck mechanism on the machine tool side, and the robot releases the object. Next, the object is machined with the tool of the machine tool.

Japanese Patent Laid-Open No. 58-160076

  In this way, the object is gripped by the chuck mechanism after being gripped by the robot. Thereby, the installation position of the target object on the machine tool may deviate from an accurate position, or it may take time to install the target object on the machine tool.

  In order to avoid this, it is conceivable that the object is machined with a tool while the robot is holding the object. In this case, when the processing force by the tool acts on a low-rigidity movable part (for example, a joint part of the robot arm) in the robot, the robot may move and the position of the object may be shifted.

  Accordingly, an object of the present invention is to suppress positional displacement of an object due to the processing force of the tool when the object is machined by a tool while the robot is holding the object.

To achieve the above object, according to the present invention, a robot for gripping an object when machining the object,
A gripping device for gripping the object;
An operating mechanism for moving the gripping device when the gripping device is fixed and operating;
A robot side attaching / detaching mechanism fixed to the gripping device or the operation mechanism,
The robot side attaching / detaching mechanism is provided with a robot that can be attached to the structure side attaching / detaching mechanism provided in the structure at the set position.

In order to achieve the above object, according to the present invention, there is provided a robot fixing device for fixing a robot that grips an object when machining the object,
A robot side attaching / detaching mechanism is fixed to the robot,
The robot fixing device includes a structure-side attachment / detachment mechanism that is provided in a structure at a set position, and the robot-side attachment / detachment mechanism is attachable / detachable.
The structure side attaching / detaching mechanism is provided with a robot fixing device to which the robot side attaching / detaching mechanism can be attached.

  Furthermore, according to this invention, the target object fixing apparatus provided with the above-mentioned robot and the above-mentioned robot fixing apparatus is provided.

Further, in order to achieve the above object, according to the present invention, there is provided a method of machining the object in a state where the object is gripped by a robot,
Prepare the robot with the robot side attachment / detachment mechanism fixed,
A structure side attaching / detaching mechanism to which the robot side attaching / detaching mechanism can be attached / detached is provided in the structure at the set position,
(A) gripping the object by the robot;
(B) By the operation of the robot, the robot side attaching / detaching mechanism is moved to the structure side attaching / detaching mechanism, and the robot side attaching / detaching mechanism is attached to the structure side attaching / detaching mechanism,
(C) In this state, there is provided a method for machining an object, in which the object gripped by the robot is machined with a tool.

  According to the present invention, an object can be gripped by a robot, and the robot side attaching / detaching mechanism can be attached to the structure side attaching / detaching mechanism provided in the structure. Therefore, the processing force acting on the object from the tool during processing can be supported by the structure via the robot side attaching / detaching mechanism and the structure side attaching / detaching mechanism. That is, the processing force can be supported by the structure without using the low-rigidity movable part in the operation mechanism. Therefore, the position shift of the target object due to the processing force can be prevented.

1 shows an object fixing device according to a first embodiment of the present invention. 1 shows a configuration example 1 of a robot side attaching / detaching mechanism and a structure side attaching / detaching mechanism. The structural example 2 of the robot side attachment / detachment mechanism and the structure side attachment / detachment mechanism is shown. 3 shows a configuration example 3 of the robot side attaching / detaching mechanism and the structure side attaching / detaching mechanism. The object fixing device in the case of the structural example 3 is shown. 4 shows a configuration example 4 of a robot side attaching / detaching mechanism and a structure side attaching / detaching mechanism. The structural example 5 of the robot side attachment / detachment mechanism and the structure side attachment / detachment mechanism is shown. It is a flowchart which shows the machining method of the target object by 1st Embodiment. 6 shows an object fixing device according to another embodiment.

  A preferred embodiment of the present invention will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected to the common part in each figure, and the overlapping description is abbreviate | omitted.

[First Embodiment]
FIG. 1A shows an object fixing device 10 according to a first embodiment of the present invention. The object fixing device 10 holds and fixes the object 1 when the object 1 is machined by the machine tool 20. The object fixing device 10 includes a robot 30 and a robot fixing device 40.

  The machine tool 20 has a tool 3, and the object 1 is machined by the tool 3. This machining may be cutting, grinding, shearing, or deburring, but may be other machining performed on the fixed object 1. The machine tool 20 may be an NC (Numerical Control) machine tool, but is not limited thereto.

  The robot 30 holds the object 1 when machining the object 1. The robot 30 grips the target object 1 placed at the standby position and moves the target object 1 to a position where the tool 3 of the machine tool 20 can machine.

  The robot 30 includes a gripping device 5, an operation mechanism 7, a robot side attaching / detaching mechanism 9, and a control device 11.

  The gripping device 5 grips the object 1. In the first embodiment, the gripping device 5 includes a plurality of gripping members 5a and 5b that are driven to open and close. The plurality of gripping members 5a and 5b are driven to close and thereby approach each other and sandwich the object 1 therebetween. Thereby, the holding device 5 holds the object 1 firmly. When the plurality of gripping members 5a and 5b are driven to open from this state, they are separated from each other and release the object 1 that has been gripped. The gripping device 5 may have another configuration that can firmly grip the object 1.

  A gripping device 5 is fixed to the operating mechanism 7. The operation mechanism 7 moves the gripping device 5 by operating. That is, by the operation of the operation mechanism 7, the gripping device 5 can move from a position where the object 1 placed at the standby position can be gripped to a position where the object 1 is machined by the machine tool 20. In the present embodiment, the operation mechanism 7 includes a plurality of constituent members 7a to 7f. The plurality of constituent members 7a to 7f are operably connected to each other.

  In this embodiment, the operation mechanism 7 is a robot arm, and the plurality of constituent members 7a to 7f are arm constituent members. Adjacent arm components are connected to each other so as to be movable (rotating or translating).

  The robot arm 7 is, for example, an articulated 6-degree-of-freedom arm. In the example of FIG. 1A, the arm constituent member 7a can rotate about its own central axis C1. The arm constituent member 7b is rotatable around the axis C2 with respect to the arm constituent member 7a. The arm constituent member 7c is rotatable around the axis C3 with respect to the arm constituent member 7b. The arm constituent member 7d can rotate around the axis C4 with respect to the arm constituent member 7c. The arm constituent member 7e is rotatable around the axis C5 with respect to the arm constituent member 7d. The arm constituent member 7f is rotatable with respect to the arm constituent member 7e around its own central axis C6. The form of the robot arm 7 may be any form such as an orthogonal coordinate type or a scalar type.

  In the first embodiment, the gripping device 5 is fixed to the most advanced arm constituent member 7f.

  The robot side attaching / detaching mechanism 9 is fixed to the gripping device 5 or the operating mechanism 7 (the operating mechanism 7 in FIG. 1A). In the first embodiment, the robot side attaching / detaching mechanism 9 is fixed to the most advanced arm constituent member 7f.

  The robot side attaching / detaching mechanism 9 can be attached to and detached from the structure side attaching / detaching mechanism 17 provided in the structure 15 at the set position. FIG. 1B shows a state where the robot side attaching / detaching mechanism 9 is attached to and coupled to the structure side attaching / detaching mechanism 17. In the first embodiment, when the robot side attaching / detaching mechanism 9 is attached to the structure side attaching / detaching mechanism 17, the position and the posture thereof are fixed with respect to the structure side attaching / detaching mechanism 17.

  The robot fixing device 40 fixes the robot 30 that holds the object 1 when the object 1 is machined. The robot fixing device 40 includes a structure-side attachment / detachment mechanism 17 provided on the structure 15 at the set position. In the first embodiment, the structure 15 is an inoperable stationary body. Preferably, the set position is a position on the machine tool 20 as shown in FIG. For example, the structure 15 may be a fixed structure portion of the machine tool 20. The set position may be a position outside the machine tool 20 (for example, near the machine tool 20).

  The control device 11 controls the gripping device 5 and the operation mechanism 7.

  The control device 11 controls the operation of the gripping device 5 by controlling a drive device (not shown) of the gripping device 5. In the first embodiment, the control device 11 controls the opening / closing operations of the plurality of gripping members 5a and 5b.

The control device 11 can move the operating mechanism 7 to any of the following positions (1) and (2) by controlling a driving device (not shown) that drives the constituent members 7a to 7f.
(1) A position where the gripping device 5 can grip the object 1 placed at the standby position.
(2) A position where the robot side attaching / detaching mechanism 9 can be fixed to the structure side attaching / detaching mechanism 17.
For example, the control device 11 moves the operation mechanism 7 based on one or both of the following (a) and (b).
(A) A preset trajectory of the gripping device 5 set in advance.
(B) The position of the structure side attaching / detaching mechanism 17 recognized using the operation mechanism 7 or a sensor (for example, a camera or a laser distance meter) provided at another position.

  In the first embodiment, as the configuration of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17, for example, any one of the following configuration examples 1 to 5 may be adopted.

(Configuration example 1)
FIG. 2A is a partially enlarged view of FIG. 1B, and shows a configuration example 1 of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17. FIG. 2B shows a state where the robot side attaching / detaching mechanism 9 is separated from the structure side attaching / detaching mechanism 17.

One of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17 has a fitting portion 18, and the other of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17 is a fitted portion 19 into which the fitting portion 18 can be fitted. Have Hereinafter, as shown in FIG. 2, the case where the robot side attaching / detaching mechanism 9 has the fitting portion 18 and the structure side attaching / detaching mechanism 17 has the fitted portion 19 will be described.
However, the robot side attaching / detaching mechanism 9 may have the fitted portion 19 and the structure side attaching / detaching mechanism 17 may have the fitting portion 18.

  The fitting portion 18 can be fitted into the fitted portion 19 by being inserted into a fitting hole 19 a formed in the fitted portion 19. The fitting hole 19a is cylindrical in the example of FIG. The portion of the fitting portion 18 that fits with the fitted portion 19 matches the shape and size of the portion of the fitted portion 19 that fits the fitting portion 18. As a result, when the fitting portion 18 is fitted to the fitted portion 19, the position does not shift with respect to the fitted portion 19 in directions other than the fitting direction of both. Hereinafter, a state in which the fitting portion 18 is fitted to the fitted portion 19 is simply referred to as a fitted state.

In order to maintain this fitting state, the object fixing device 10 includes a fitting maintenance device 21. The fitting maintaining device 21 can be switched between a blocking state in which the fitting portion 18 fitted to the fitting portion 19 is prevented from coming off from the fitting portion 19 and a released state in which the blocking state is released. It is.
This switching is preferably performed by the control device 11. The control device 11 controls the operation mechanism 7 to fit the fitting portion 18 to the fitting portion 19. Next, the control device 11 controls the fitting maintaining device 21 to bring the fitting maintaining device 21 into the above-described blocking state.

  The fitting maintenance device 21 includes a plurality of spheres 23, a gas supply device 25, and on-off valves 26 and 27.

  The plurality of spheres 23 are provided in the fitting portion 18. The plurality of spheres 23 are, for example, steel balls. The plurality of spheres 23 are arranged at intervals in the circumferential direction of the outer peripheral surface 18 a of the fitting portion 18. Inside the fitting portion 18, a passage 18b in which each sphere 23 can move is formed. By this passage 18b, each spherical body 23 is movable between a protruding position protruding from the outer peripheral surface 18a of the fitting portion 18 and an inner position retracted inward from the outer peripheral surface 18a. In addition, a stopper structure 29 is provided in the fitting portion 18 so as to prevent each sphere 23 from moving outward from the protruding position. For example, the stopper structure 29 includes a locked portion 29a provided in the sphere 23 and a step portion 29b provided in the passage 18b. The stepped portion 29b locks the locked portion 29a of the sphere 23 at the protruding position and prevents the locked portion 29a from moving further outward.

  Corresponding to the plurality of spheres 23, a plurality of depressions 19b are formed on the inner peripheral surface of the fitting hole 19a. These recesses 19b are arranged at intervals in the circumferential direction of the inner peripheral surface of the fitting hole 19a. The sphere 23 of the fitting portion 18 inserted into the fitting hole 19a can be inserted into each recess 19b.

  The gas supply device 25 supplies pressurized gas (pressurized air) to the passage 18b, whereby the plurality of spheres 23 are moved to the protruding position and held at the protruding position. The gas supply device 25 includes a pressurized supply source 25a, a gas supply path 25b for supplying pressurized gas from the pressurized supply source 25a to the path 18b, and an exhaust path 25c branched from the gas supply path 25b. Have.

  The on-off valve 26 is provided in the gas supply path 25b, and the on-off valve 27 is provided in the exhaust path 25c. The tip of the exhaust path 25c (for example, a tube) is open to the atmosphere. If the on-off valve 26 is opened and the on-off valve 27 is closed in the above-described fitting state, the gas supply device 25 is in the above-described blocking state. That is, pressurized gas is supplied from the pressurized supply source 25a through the gas supply path 25b to the passage 18b, and the locked portion 29a is pressed against the stepped portion 29b by this pressurized gas, and the sphere 23 is inserted into the recess 19b. Maintained in the protruding position. Thereby, the spherical body 23 engages with the fitted portion 19 in the fitting direction described above. When the on-off valve 26 is closed and the on-off valve 27 is opened from such a blocking state, the gas supply device 25 enters the above-described release state.

  The control device 11 switches the gas supply device 25 between a blocking state and a releasing state by controlling opening and closing of the on-off valves 26 and 27.

  In the configuration example 1, the robot-side attaching / detaching mechanism 9 can be quickly fixed to the structure-side attaching / detaching mechanism 17 by fitting the fitting portion 18 to the fitted portion 19 and putting the fitting maintaining device 21 into the blocking state.

  Instead of the plurality of spheres 23, a moving member having another shape may be provided. In this case, the sphere 23 is replaced with the moving member 23 in the above description.

(Configuration example 2)
FIG. 3A corresponds to a partially enlarged view of FIG. 1B, but shows a configuration example 2 of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17. FIG. 3B shows a state where the robot side attaching / detaching mechanism 9 is separated from the structure side attaching / detaching mechanism 17.

One of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17 has a fitting part 31, and the other of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17 is a fitted part 32 to which the fitting part 31 can be fitted. Have Hereinafter, the case where the robot side attaching / detaching mechanism 9 has the fitting portion 31 and the structure side attaching / detaching mechanism 17 has the fitted portion 32 as shown in FIG. 3 will be described.
However, the robot side attaching / detaching mechanism 9 may have the fitted portion 32 and the structure side attaching / detaching mechanism 17 may have the fitting portion 31.

  The fitting portion 31 can be fitted into the fitted portion 32 by being inserted into a fitting hole 32 a formed in the fitted portion 32. In the example of FIG. 3, a plurality of fitting holes 32a are provided, each fitting hole 32a has a conical shape, and the apex of the conical shape is located at the lower end of the fitting hole 32a. The portion of the fitting portion 31 that fits with the fitted portion 32 is matched in shape and size with the portion of the fitted portion 32 that fits the fitting portion 31. Accordingly, when the fitting portion 31 is fitted to the fitted portion 32, the position is not shifted with respect to the fitted portion 32 in a direction other than the fitting direction.

In order to maintain the above-described fitting state, the object fixing device 10 includes a fitting maintaining device 41. The fitting maintaining device 41 can be switched between a blocking state in which the fitting portion 31 fitted to the fitting portion 32 is prevented from being detached from the fitting portion 32 and a released state in which the blocking state is released. It is.
This switching is preferably performed by the control device 11. The control device 11 controls the operation mechanism 7 to fit the fitting portion 31 to the fitted portion 32. Next, the control device 11 controls the fitting maintaining device 41 to bring the fitting maintaining device 41 into the above-described blocking state.

  The fitting maintenance device 41 includes an electromagnet 43, a current supply device 45, and a switch 47.

The electromagnet 43 is fixed to one of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17. In the example of FIG. 3, one of these is the robot side attaching / detaching mechanism 9, and the electromagnet 43 is incorporated in the fitting portion 31. The other of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17 has a portion formed of a material (for example, a ferromagnetic material) attracted to the electromagnet 43 by the magnetic force generated by the electromagnet 43. This portion is the fitted portion 32 in the example of FIG.
The current supply device 45 includes a power source 45a and an electric wire 45b. The electric wire 45 b connects the power source 45 a and the electromagnet 43, and allows current from the power source 45 a to flow to the electromagnet 43.
The switch 47 is provided on the electric wire 45b. When the switch 47 is closed in a state where the fitting portion 31 is fitted to the fitted portion 32, a current flows from the power source 45a to the electromagnet 43 and the magnetic force of the electromagnet 43 causes the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17 ( In the example of FIG. 3, the electromagnet 43 and the fitted part 32) are attracted to each other. As a result, the current supply device 45 enters the above-described blocking state. When the switch 47 is opened from this state, the current supply device 45 is in the release state described above.

  The control device 11 switches the current supply device 45 between the blocked state and the released state by controlling the opening and closing of the switch 47.

  In the configuration example 2, the robot-side attaching / detaching mechanism 9 can be quickly fixed to the structure-side attaching / detaching mechanism 17 by fitting the fitting portion 31 to the fitted portion 32 and setting the fitting maintaining device 41 in the blocking state.

(Configuration example 3)
FIG. 4A corresponds to a partially enlarged view of FIG. 1B, but shows a configuration example 3 of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17. FIG. 4B shows a state where the robot side attaching / detaching mechanism 9 is separated from the structure side attaching / detaching mechanism 17.

One of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17 has a clamp device 51, and the other of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17 has a clamped portion 52 fixed to the clamp device 51. Hereinafter, as shown in FIG. 4, a case where the structure side attaching / detaching mechanism 17 includes the clamp device 51 and the robot side attaching / detaching mechanism 9 includes the clamped portion 52 will be described.
However, the robot side attaching / detaching mechanism 9 may include the clamping device 51 and the structure side attaching / detaching mechanism 17 may include the clamped portion 52.

  The clamp device 51 has a pair of clamp parts 51a and 51b that sandwich and fix the clamped part 52 therebetween.

  In the example of FIG. 4, the clamped portion 52 includes at least a part of a spherical shape, each clamp portion 51 a, 51 b has a clamp surface 53, and each clamp surface 53 includes a clamped portion 52. A recess 54 into which a part of the recess is inserted is formed. Preferably, by inserting a part of the clamped part 52 (part of the above part) into the recess 54, the clamped part 52 is positioned in at least one direction orthogonal to the insertion direction. More preferably, the recess 54 has a shape and a size according to the clamped portion 52. Thereby, by inserting a part of the clamped portion 52 into the recess 54, the clamped portion 52 is positioned in all directions orthogonal to the insertion direction. For example, the recess 54 may have a shape that forms a part of a sphere, may have a conical shape with a vertex at the bottom, or may have a V-shaped cross section. The shape of the clamped portion 52 is not limited to the above, and the pair of clamp portions 51a and 51b only need to be able to sandwich and clamp the clamped portion 52.

  Preferably, the operation of the clamp portions 51a and 51b is controlled by the control device 11. In this case, the clamp device 51 includes a drive device 55 that opens and closes the pair of clamp portions 51a and 51b. In the example of FIG. 4, the driving device 55 includes a motor 55 a, a screw shaft 55 b that is rotationally driven by the motor 55 a, a slide 55 c that is screwed to the screw shaft 55 b, and rotation of the slide 55 c to prevent the slide 55 c from moving back and forth. (That is, a guide 55d for guiding in the left-right direction in FIG. 4). The guide 55d is fixed to the structure 15. One clamp part 51 a is coupled to the slide 55 c, and the other clamp part 51 b is fixed to the structure 15. By rotating the screw shaft 55b by the motor 55a, the one clamp part 51a is moved back and forth together with the slide 55c, thereby opening and closing the pair of clamp parts 51a and 51b.

  The driving device 55 is not limited to the above as long as it has a configuration for opening and closing the pair of clamp portions 51a and 51b, or a configuration using an air cylinder or a hydraulic cylinder, or another configuration. You may have.

  The control device 11 controls the operation mechanism 7 to position the clamped portion 52 between the pair of clamp portions 51a and 51b, and then controls the driving device 55 (the motor 55a in the example of FIG. 4). A pair of clamp parts 51a and 51b are brought close to each other. Thereby, the clamped portion 52 is sandwiched and fixed between the pair of clamp portions 51a and 51b. Thereafter, the control device 11 drives the drive device so as to continuously drive one or both of the clamp portions 51a and 51b (the clamp portion 51a in the example of FIG. 4) in a direction in which the pair of clamp portions 51a and 51b are brought close to each other. 55 may be controlled. As a result, the state in which the clamped portion 52 is fixed by the pair of clamp portions 51a and 51b is maintained.

  In the configuration example 3, the clamped portion 52 is positioned between the pair of clamp portions 51a and 51b, and the clamped portion 52 is sandwiched between the clamp portions 51a and 51b. In addition, it can be fixed more firmly.

  FIG. 5 shows the entire object fixing device 10 in a state in which the clamped portion 52 is fixed to the pair of clamp portions 51a and 51b. In the configuration example 3, when the clamped portion 52 includes at least a part of a spherical shape, the clamped portion 52 is paired with a pair of clamp portions 51a, 51b can be firmly sandwiched and fixed. At this time, since the clamped portion 52 includes at least a part of a spherical shape, the clamped portion 52 is placed in a pair with the orientation of the object 1 gripped by the gripping device 5 being a desired orientation. It can be fixed to the clamp portions 51a and 51b. For example, as shown in FIG. 5, the clamped portion 52 can be fixed to the pair of clamp portions 51a and 51b in a state in which the object 1 is oriented obliquely with respect to the horizontal.

(Configuration example 4)
FIG. 6A corresponds to a partially enlarged view of FIG. 1B, but shows a configuration example 4 of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17. FIG. 6B is a view taken in the direction of arrows BB in FIG. FIG. 6C shows a state where the robot side attaching / detaching mechanism 9 is separated from the structure side attaching / detaching mechanism 17. FIG. 6D is a DD arrow view of FIG.

  In the configuration example 4, a below-described fastener 57 is provided in place of the driving device 55, and the force to sandwich the object 1 by the clamp portions 51a and 51b is maintained by the fastener 57. The configuration example 4 is the same as the configuration example 3 in that it is not described below.

  One clamp part 51a can be brought close to and separated from the other clamp part 51b so that the pair of clamp parts 51a and 51b can be opened and closed, and the other clamp part 51b is fixed to the structure 15.

  The clamp device 51 includes a fastening tool 57 that fastens the pair of clamp portions 51a and 51b to each other. In the example of FIG. 6, the fastener 57 has a bolt 57a and a nut 57b. One end of the bolt 57a is coupled to the clamp part 51b, the intermediate part passes through the through hole of the other clamp part 51a, and the other end is screwed into the nut 57b. The nut 57b is rotated manually or by an actuator (not shown) and fastened to the bolt 57a. Accordingly, the clamped portion 52 is firmly sandwiched between the pair of clamp portions 51 a and 51 b, and this state is maintained by the fastener 57.

  When the nut 57b is rotated by the actuator, the control device 11 controls the operation mechanism 7 so that the clamped portion 52 is positioned between the pair of clamp portions 51a and 51b, and then the actuator is moved. By controlling, the nut 57b is fastened to the bolt 57a.

  The fastening tool 57 may have another configuration as long as the clamp parts 51a and 51b are fastened to each other and the object 1 is firmly sandwiched between the clamp parts 51a and 51b. In this case, the clamp portions 51a and 51b are fastened to each other by a fastener 57 by manual operation or by an actuator. When the actuator is used, the control device 11 controls the operation mechanism 7 so that the clamped portion 52 is positioned between the pair of clamp portions 51a and 51b, and then tightens by controlling the actuator. The tool 57 is driven and the clamp portions 51a and 51b are fastened to each other by the fastening tool 57.

  In the configuration example 4, the clamp parts 51a and 51b are fastened to each other by the fastening tool 57 in a state where the clamped part 52 is positioned between the pair of clamp parts 51a and 51b. Thereby, the robot side attaching / detaching mechanism 9 can be more firmly fixed to the structure side attaching / detaching mechanism 17.

(Configuration example 5)
FIG. 7A corresponds to the partially enlarged view of FIG. 1B, but shows a configuration example 5 of the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17. FIG. 7B is a BB arrow view of FIG. FIG. 7C shows a state where the robot side attaching / detaching mechanism 9 is separated from the structure side attaching / detaching mechanism 17. FIG. 7D is a DD arrow view of FIG.

  In the configuration example 5, the clamped portion 52 includes a portion that forms at least a part of a cylindrical shape. The configuration example 5 is the same as the configuration example 4 in the points not described below.

  Each clamp part 51a, 51b has a clamp surface 53, and a groove 56 into which a part of the clamped part 52 (a part of the above part) is inserted is formed in each clamp surface 53. Preferably, by inserting a part of the clamped portion 52 into the groove 56, the clamped portion 52 is positioned in all directions orthogonal to the insertion direction. The groove 56 has a shape and a size according to the clamped portion 52. For example, the groove 56 may have a shape that forms a part of a cylinder, or may have a V-shaped cross section. When the clamped portion 52 is sandwiched and fixed by the pair of clamp portions 51a and 51b, a part of the clamped portion 52 is inserted into each groove 56 as shown in FIGS.

  In the configuration example 5, as in the configuration example 3, the operations of the clamp parts 51a and 51b may be controlled by the control device 11. In this case, the control device 11 may open and close the clamp portions 51a and 51b by controlling a driving device (not shown) that opens and closes the pair of clamp portions 51a and 51b. Further, in this case, when the control device 11 sandwiches and fixes the clamped portion 52 by the pair of clamp portions 51a and 51b, one of the clamp portions 51a and 51b is moved in a direction in which the pair of clamp portions 51a and 51b are brought close to each other. Or you may control the said drive device so that both may be driven continuously.

  In the configuration example 5, the clamped portion 52 can be firmly sandwiched and fixed by the pair of clamp portions 51a and 51b in a state where the clamped portion 52 is inserted in the groove 56 described above. At this time, since the clamped portion 52 includes at least a part of a cylindrical shape, the clamped portion 52 is adjusted in a state in which the orientation of the object 1 gripped by the gripping device 5 is adjusted around the axis of the clamped portion 52. Can be fixed to the pair of clamp portions 51a and 51b.

  FIG. 8 is a flowchart showing a method of machining the object 1 using the object fixing device 10 described above.

  In step S <b> 1, the object 1 is gripped by the gripping device 5. That is, the control device 11 moves the operation mechanism 7 to a position where the gripping device 5 can grip the target object 1 and then causes the gripping device 5 to grip the target object 1.

In step S <b> 2, the control device 11 moves the operation mechanism 7 to a position where the robot side attaching / detaching mechanism 9 is attached to the structure side attaching / detaching mechanism 17. Next, in step S2, the robot side attaching / detaching mechanism 9 is attached to and coupled to the structure side attaching / detaching mechanism 17.
In the case of the configuration examples 1 and 2, the control device 11 causes the fitting portions 18 and 31 to be fitted to the fitted portions 19 and 32, and this fitting state is maintained by the fitting maintaining devices 21 and 41.
In the case of the configuration examples 3 to 5, the control device 11 positions the clamped portion 52 between the pair of clamp portions 51a and 51b, and the pair of clamp portions 51a and 51a are manually operated by the control device 11 or manually. The clamped portion 52 is sandwiched and fixed by 51b.

  In step S <b> 3, the object 1 gripped by the gripping device 5 is machined with the tool 3 in a state where the robot-side attaching / detaching mechanism 9 and the structure-side attaching / detaching mechanism 17 are fixed to each other. That is, in the machine tool 20, the tool 3 moves to the position of the target object 1 to machine the target object 1. At this time, the object 1 is firmly supported by the structure 15 via the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17, so that even if a large machining force is applied to the object 1 from the tool 3 The position of object 1 is not off.

In step S4, the robot side attaching / detaching mechanism 9 is released from being fixed to the structure side attaching / detaching mechanism 17.
In the case of the configuration examples 1 and 2, the control device 11 puts the fitting maintaining devices 21 and 41 into the released state.
In the case of the configuration examples 3 to 5, the pair of clamp parts 51a and 51b are separated from each other by the control device 11 or manually, and the clamped part 52 is released from the clamp parts 51a and 51b.

  In step S5, the control device 11 operates the operating mechanism 7 to convey the machined object 1 to a designated position. Next, in step S5, the control device 11 controls the gripping device 5 to release the object 1 from the gripping device 5 and place it at a designated position.

  Then, it returns to step S1 and performs above-mentioned step S1-S5 about the new target object 1. FIG.

  According to the first embodiment described above, the object 1 can be held by the grasping device 5, and the robot side attaching / detaching mechanism 9 can be attached and coupled to the structure side attaching / detaching mechanism 17 provided in the structure 15. In this state, since the position and posture of the robot side attaching / detaching mechanism 9 are fixed with respect to the structure side attaching / detaching mechanism 17, the rigidity of the coupling portion between the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17 is set to the operating mechanism 7. Higher than the movable part (for example, the joint part of the robot arm 7). The machining force acting on the object 1 from the tool 3 at the time of machining can be supported by the structure 15 through such a highly rigid joint between the robot side attachment / detachment mechanism 9 and the structure side attachment / detachment mechanism 17. That is, the processing force can be supported by the structure 15 without using the low-rigidity movable part in the operation mechanism 7. Therefore, the position shift of the object 1 due to the processing force can be suppressed.

  Preferably, the robot side attaching / detaching mechanism 9 is fixed to the most advanced arm constituent member 7f. As a result, the machining force acting on the object 1 from the tool 3 during machining is not via any connecting portion between the arm constituent members, but via the coupling portion between the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17. Supported by the structure 15. Since the joint between the robot side attaching / detaching mechanism 9 and the structure side attaching / detaching mechanism 17 has high rigidity, it is possible to prevent displacement of the object 1 due to the processing force.

[Second Embodiment]
FIG. 9A shows an object fixing device 10 according to a second embodiment of the present invention. In the second embodiment, the points not described below are the same as in the first embodiment.

  In the second embodiment, the structure 15 is provided in the fixed structure 59 so as to be movable with respect to the fixed structure 59 (for example, the fixed structure of the machine tool 20). The direction of this movement is the horizontal direction in the example of FIG. 9A, but it may be a vertical direction or an oblique direction with respect to the horizontal direction.

The robot fixing device 40 includes a driving device 61 that moves the structure 15 with respect to the fixed structure portion 59.
The operation mechanism 7 operates so as to follow the movement of the structure 15 by the driving device 61. That is, the operation mechanism 7 operates with the driving force of the driving device 61. At this time, in one example, the control device 11 performs force control on the operation mechanism 7. In this force control, a driving force is generated in the operation mechanism 7 in the setting direction. The driving device 61 moves the structure 15 against the driving force generated in the operating mechanism 7 by the above-described force control, and operates the operating mechanism 7 so as to follow this movement.

  In the second embodiment, the driving device 61 can move the structure 15 in a state where the gripping device 5 grips the object 1 and the robot-side attaching / detaching mechanism 9 is coupled to the structure-side attaching / detaching mechanism 17. Thereby, the relative position of the tool 3 and the target object 1 can be adjusted. For example, the structure 15 may be moved by the driving device 61 while the tool 3 is machining the object 1. Thereby, the processing position of the target object 1 with the tool 3 can be changed.

[Third Embodiment]
FIG. 9B shows an object fixing device 10 according to the third embodiment of the present invention. In the third embodiment, the points not described below are the same as those in the first embodiment.

  As described above, the state-of-the-art arm constituent member 7f can rotate around its own central axis C6. In the third embodiment, the robot-side attaching / detaching mechanism 9 is fixed to another arm constituent member 7e that is incapable of relative movement other than rotation around the central axis C6 with respect to the most advanced arm constituent member 7f. That is, in FIG. 9B, the robot side attaching / detaching mechanism 9 is fixed to the arm constituent member 7e adjacent to the most advanced arm constituent member 7f.

  The gripping device 5 is fixed to the most advanced arm constituent member 7f.

  In a state where the gripping device 5 grips the object 1 and the robot side attaching / detaching mechanism 9 is coupled to the structure side attaching / detaching mechanism 17, the control device 11 causes the most advanced arm constituent member 7f to move around its own central axis C6. Can be rotated. Thereby, for example, the object 1 can be positioned around the central axis C6, and the object 1 can be machined by the tool 3 in this state. Thus, the most advanced arm component 7f can be used as an index table of the machine tool 20.

  As described above, the arm constituent member 7f is connected to the arm constituent member 7e so as to be rotatable around its own central axis C6. Therefore, the relative position between the arm constituent members 7e and 7f is less likely to change even when a processing force by the tool 3 acts on the connection portion between the arm constituent members 7e and 7f. Misalignment is unlikely to occur.

In an example of such a configuration, the root portion of the arm component member 7f is a cylindrical shape or a column shape having the central axis C6 as an axis, and this root portion is connected to a cylindrical connection portion fixed to the arm component member 7e. Has been inserted. As a result, the arm constituent member 7f is inoperable with respect to the arm constituent member 7e other than the rotation around the central axis C6.
In another configuration example, the base portion of the arm constituent member 7f has a cylindrical shape with the central axis C6 as an axis, and a columnar or cylindrical connecting portion fixed to the arm constituent member 7e is inserted into the base portion. ing. As a result, the arm constituent member 7f is inoperable with respect to the arm constituent member 7e other than the rotation around the central axis C6.

  The present invention is not limited to the above-described embodiments, and various changes can be made within the scope of the technical idea of the present invention. For example, any of the following modification examples 1 to 3 may be employed, or modification example 1 or modification example 2 and modification example 3 may be employed in combination. In this case, the points not described below are the same as described above.

(Modification 1)
The fitting maintaining devices 21 and 41 may be omitted in the configuration examples 1 and 2 described above. In this case, the control device 11 controls the operation mechanism 7 so that the fitting portions 18 and 31 are fitted to the fitted portions 19 and 32 (that is, the robot side attaching / detaching mechanism 9 is used as the structure side attaching / detaching mechanism 17. Attach). In this state, the object 1 gripped by the gripping device 5 is machined with the tool 3. Preferably, at this time, the operation mechanism 7 is controlled so as to maintain the state where the fitting portions 18 and 31 are pressed against the fitted portions 19 and 32.

(Modification 2)
In the above configuration examples 1 and 2, the fitting maintaining devices 21 and 41 may be manually switched between the blocking state and the releasing state. For example, the on-off valves 26 and 27 may be manually opened and closed, and the switch 47 may be manually opened and closed.

(Modification 3)
In the above-described configuration examples 3 and 4, the recess 54 may be formed only in one of the pair of clamp parts 51a and 51b. In the above-described configuration example 5, the groove 56 may be formed only in one of the pair of clamp portions 51a and 51b.

DESCRIPTION OF SYMBOLS 1 Object, 3 Tool, 5 Gripping device, 5a, 5b Gripping member, 7 Operation mechanism (robot arm), 7a-7f Structural member (arm structural member), 9 Robot side attaching / detaching mechanism, 10 Object fixing device, 11 Control Device, 15 structure, 17 structure side attaching / detaching mechanism, 18 fitting portion, 18a outer peripheral surface, 18b passage, 19 fitted portion, 19a fitting hole, 19b depression, 20 machine tool, 21 fitting maintaining device, 23 sphere , 25 Gas supply device, 25a Pressure supply source, 25b Gas supply path, 25c Exhaust path, 26, 27 On-off valve, 29 Stopper structure, 29a Locked part, 29b Stepped part, 30 Robot, 31 Fitting part, 32 Part to be fitted, 32a fitting hole, 40 robot fixing device, 41 fitting maintaining device, 43 electromagnet, 45 current supply device, 45a power supply, 45b electric wire, 47 Switch, 51 Clamping device, 51a, 51b Clamping part, 52 Clamped part, 53 Clamping surface, 54 Recess, 55 Drive device, 55a Motor, 55b Screw shaft, 55c Slide, 55d Guide, 56 Groove, 57 Fastener, 57a Bolt, 57b Nut, 59 Fixing structure, 61 Drive device

Claims (10)

A robot for gripping an object when machining the object,
A gripping device for gripping the object;
An operating mechanism for moving the gripping device when the gripping device is fixed and operating;
A robot side attaching / detaching mechanism fixed to the gripping device or the operation mechanism,
The robot-side attachment / detachment mechanism can be attached to a structure-side attachment / detachment mechanism provided in a structure at a set position. The movement mechanism is a robot arm, and the robot arm has a plurality of arm components that can move relative to each other.
The gripping device is fixed to the most advanced arm component,
The robot according to claim 1, wherein the robot side attaching / detaching mechanism is fixed to the most advanced arm constituent member or the gripping device. The movement mechanism is a robot arm, and the robot arm has a plurality of arm components that can move relative to each other.
The state-of-the-art arm component is rotatable about its own central axis,
The robot according to claim 1, wherein the robot side attaching / detaching mechanism is fixed to the arm constituent member adjacent to the most advanced arm constituent member. A robot fixing device for fixing a robot that grips an object when machining the object,
A robot side attaching / detaching mechanism is fixed to the robot,
The robot fixing device includes a structure-side attachment / detachment mechanism that is provided in a structure at a set position, and the robot-side attachment / detachment mechanism is attachable / detachable.
The robot fixing device, wherein the robot side attaching / detaching mechanism can be attached to the structure side attaching / detaching mechanism. The structure is provided in the fixed structure part so as to be movable with respect to the fixed structure part,
The robot fixing device according to claim 4, wherein the robot fixing device includes a drive device that moves the structure relative to the fixed structure portion.   An object fixing device comprising the robot according to claim 1, 2 or 3 and the robot fixing device according to claim 4 or 5. One of the robot side attaching / detaching mechanism and the structure side attaching / detaching mechanism includes a fitting portion that can be fitted to the other of the robot side attaching / detaching mechanism and the structure side attaching / detaching mechanism,
The other includes a fitted portion into which the fitting portion can be fitted,
The object fixing device is switched between a blocking state in which the fitting portion fitted to the fitting portion is prevented from coming off from the fitting portion and a release state in which the blocking state is released. The object fixing device according to claim 6, comprising a fitting maintenance device. One of the robot side attaching / detaching mechanism and the structure side attaching / detaching mechanism includes a pair of clamp portions that can be fixed by sandwiching the other of the robot side attaching / detaching mechanism and the structure side attaching / detaching mechanism,
The object fixing device according to claim 6, wherein the other includes a clamped portion sandwiched between the pair of clamp portions. The clamped portion includes at least a part of a spherical shape or at least a part of a cylindrical shape,
The object according to claim 8, wherein a recess into which a part of the clamped part is inserted is formed in the clamp part, or a groove into which a part of the clamped part is inserted is formed. Fixing device. A method of machining the object in a state where the object is gripped by a robot,
Prepare the robot with the robot side attachment / detachment mechanism fixed,
A structure side attaching / detaching mechanism to which the robot side attaching / detaching mechanism can be attached / detached is provided in the structure at the set position,
(A) gripping the object by the robot;
(B) By the operation of the robot, the robot side attaching / detaching mechanism is moved to the structure side attaching / detaching mechanism, and the robot side attaching / detaching mechanism is attached to the structure side attaching / detaching mechanism,
(C) In this state, the object machining method of machining the object gripped by the robot with a tool.

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