JP7155664B2 - Simulation equipment, controllers and robots - Google Patents

Description

The present invention relates to a simulation device, control device and robot.

A robot is known which includes a base and a robot arm having a plurality of arms (links). One of the two adjacent arms of the robot arm is rotatably connected to the other arm via a joint, and the most proximal (most upstream) arm is connected via the joint. and is rotatably connected to the base. The joint is driven by a motor, and the arm is rotated by driving the joint. Also, for example, a hand is detachably attached as an end effector to the arm closest to the distal end (most downstream). Then, the robot, for example, grips an object with a hand, moves the object to a predetermined place, and performs predetermined work such as assembly. In such a robot, it is necessary to teach the robot before actually performing the work.

Patent Literature 1 discloses a robot simulator for simulating a robot.

In the robot simulator described in Patent Document 1, when a work is gripped by a hand and the work is moved, it is determined whether or not the needle (coordinate axis) set on the hand side intersects with the three-dimensional coordinates set on the work side. Whether or not the hand has grasped the workpiece is determined according to whether the hand has grasped the workpiece successfully or not. Using this robot simulator, it is possible to teach the robot offline (offline teaching).

JP 2010-214571 A

In the robot simulator described in Patent Document 1, in order for the hand to be able to grip a workpiece in the simulation, it is necessary to set a virtual needle, which is not present in the actual machine, on the hand side. and time consuming.

The present invention has been made to solve at least part of the problems described above, and can be realized by the following.

A simulation device of the present invention is a simulation device that performs a simulation using a virtual robot that is a virtualized robot,
a reception unit that receives input of information regarding whether or not to operate the virtual robot and the virtual object in conjunction with each other, and input of information regarding a mounting portion for mounting the virtual object on the virtual robot;
displaying on a display unit the virtual robot and the virtual object attached to the mounting portion accepted by the accepting unit, and receiving an input to operate the virtual robot and the virtual object in conjunction with each other; and a control unit that moves the virtual object in conjunction with the motion of the virtual robot when receiving the motion.

According to such a simulation apparatus, by inputting information regarding whether or not to operate the virtual robot and the virtual object in conjunction with each other and inputting information regarding the attachment portion for attaching the virtual object to the virtual robot, , the virtual object can be easily attached to the attachment portion, and the virtual object can be moved in conjunction with the motion of the virtual robot. As a result, it is possible to easily perform a simulation suitable for the actual machine.

In the simulation device of the present invention, it is preferable that the position of the virtual object attached to the attachment portion can be changed from the attachment portion.
Thereby, the virtual object can be arranged at a position spaced apart from the mounting portion.

In the simulation device of the present invention, it is preferable that the attachment portion includes virtual joints of the virtual robot.
Thereby, the virtual object can be attached to the virtual joints of the virtual robot.

In the simulation device of the present invention, the receiving unit can receive selection of one coordinate system from a plurality of coordinate systems possessed by the virtual robot,
When the receiving unit receives an input to operate the virtual robot and the virtual object in conjunction with each other, the control unit controls the origin of the selected coordinate system and the origin of the coordinate system of the virtual object. It is preferable to display on the display section in a state in which .
As a result, the virtual object can be easily arranged at an appropriate position.

In the simulation apparatus according to the aspect of the invention, when the reception unit receives an input to cause the virtual robot and the virtual object to operate in conjunction with each other, the control unit causes the virtual object different from the attachment portion to move to the virtual object. When the object interferes with the object, it is preferable that the display unit displays that the virtual object different from the attachment portion and the virtual object interfere with each other.

As a result, it is possible to easily grasp that the virtual object different from the attachment portion interferes with the virtual object. This makes it possible to easily verify the arrangement of peripheral devices, verify the operation paths, etc., before creating an actual machine.

In the simulation device of the present invention, it is preferable that the virtual object includes a virtual force sensor.
Thereby, the virtual force sensor can be attached to the attachment portion.

In the simulation device of the present invention, the virtual object includes a virtual end effector,
When the virtual force sensor is attached to the virtual robot while the virtual end effector is attached to the virtual robot, the control unit changes the position of the virtual end effector and attaches the virtual force sensor to the virtual robot. It is preferable that the display is displayed in a state of being attached between the virtual robot and the virtual end effector.

As a result, the virtual force sensor and the virtual end effector can be easily arranged at the same positions as the actual machine.

In the simulation device of the present invention, it is preferable that the control unit causes the display unit to display a force sensor coordinate system of the virtual force sensor.

This makes it possible to grasp the force sensor coordinate system. Each axis of this force sensor coordinate system is a force detection axis detected by the virtual force sensor.

In the simulation device of the present invention, the virtual object includes a virtual end effector,
Preferably, the control unit causes the display unit to display a force coordinate system whose origin is an action point of the virtual end effector or the virtual object held by the virtual end effector acting on another virtual object.

As a result, the point of action of the virtual end effector or the virtual object held by the virtual end effector and the force coordinate system can be grasped. This force coordinate system is a coordinate system for executing a function using the force detected by the virtual force sensor, and each axis of the force coordinate system points in the direction of each force component applied to the point of action. ing.

In the simulation device of the present invention, it is preferable that the control section causes the display section to display the magnitude of the force acting on the point of action.

Thereby, it is possible to grasp the force applied to the point of action of the virtual end effector or the virtual object held by the virtual end effector.

In the simulation device of the present invention, it is preferable that the size of the force is represented by the size of the arrow.

This makes it possible to easily grasp the force applied to the point of action of the virtual end effector or the virtual object held by the virtual end effector.

The control device of the present invention is characterized by controlling the robot based on the simulation result by the simulation device of the present invention.

According to such a control device, it is possible to cause the robot to perform an appropriate motion using the motion program created by the simulation device.

The robot of the present invention has an attachment portion to which an object can be attached,
It is characterized by being controlled by the control device of the present invention.

According to such a robot, it is possible to perform appropriate actions under the control of the control device.

A simulation device of the present invention is a simulation device that performs a simulation using a virtual robot that is a virtualized robot,
equipped with a processor
The processor receives an input of information regarding whether or not to interlock the virtual robot and the virtual object and an input of information regarding a mounting portion for mounting the virtual object on the virtual robot, and When the virtual robot and the virtual object attached to the received attachment portion are displayed on the display unit, and an input to operate the virtual robot and the virtual object in conjunction with each other is received, the virtual robot The virtual object is moved in conjunction with the motion.

According to such a simulation apparatus, by inputting information regarding whether or not to operate the virtual robot and the virtual object in conjunction with each other and inputting information regarding the attachment portion for attaching the virtual object to the virtual robot, , the virtual object can be easily attached to the attachment portion, and the virtual object can be moved in conjunction with the motion of the virtual robot. As a result, it is possible to easily perform a simulation suitable for the actual machine.

1 is a diagram showing a robot system according to a first embodiment; FIG. 2 is a block diagram of the robot system shown in FIG. 1; FIG. It is a figure which shows an example of the screen displayed on a display apparatus. It is a figure which shows an example of the screen displayed on a display apparatus. It is a figure which shows an example of the screen displayed on a display apparatus. It is a figure which shows an example of the screen displayed on a display apparatus. It is a figure which shows an example of the screen displayed on a display apparatus. It is a figure which shows an example of the screen displayed on a display apparatus. It is a figure which shows an example of the screen displayed on a display apparatus. It is a figure which shows an example of the screen displayed on a display apparatus. It is a figure which shows an example of the screen displayed on a display apparatus. 2 is a diagram showing an example of a simulation performed by the robot system simulation device shown in FIG. 1; FIG. 2 is a diagram showing an example of a simulation performed by the robot system simulation device shown in FIG. 1; FIG. 2 is a diagram showing an example of a simulation performed by the robot system simulation device shown in FIG. 1; FIG. 2 is a diagram showing an example of a simulation performed by the robot system simulation device shown in FIG. 1; FIG. 2 is a diagram showing an example of a simulation performed by the robot system simulation device shown in FIG. 1; FIG. FIG. 11 is a diagram showing an example of a screen displayed on the display device of the robot system according to the second embodiment; FIG. It is a figure which shows an example of the simulation which the simulation apparatus of the robot system based on 2nd Embodiment performs. It is a figure which shows an example of the simulation which the simulation apparatus of the robot system based on 2nd Embodiment performs. It is a figure which shows an example of the simulation which the simulation apparatus of the robot system based on 2nd Embodiment performs. It is a figure which shows an example of the simulation which the simulation apparatus of the robot system based on 2nd Embodiment performs. It is a figure which shows an example of the simulation which the simulation apparatus of the robot system based on 2nd Embodiment performs. It is a figure which shows an example of the simulation which the simulation apparatus of the robot system based on 2nd Embodiment performs. It is a figure which shows an example of the simulation which the simulation apparatus of the robot system based on 3rd Embodiment performs. It is a figure which shows an example of the simulation which the simulation apparatus of the robot system based on 3rd Embodiment performs. It is a figure which shows an example of the simulation which the simulation apparatus of the robot system based on 4th Embodiment performs. It is a figure which shows an example of the simulation which the simulation apparatus of the robot system based on 4th Embodiment performs. FIG. 11 is a diagram showing an example of a simulation performed by a robot system simulation apparatus according to a fifth embodiment; FIG. 11 is a diagram showing an example of a simulation performed by a robot system simulation apparatus according to a fifth embodiment; FIG. 11 is a diagram showing an example of a simulation performed by a robot system simulation apparatus according to a fifth embodiment; FIG. 11 is a diagram showing an example of a simulation performed by a robot system simulation apparatus according to a fifth embodiment; FIG. 11 is a diagram showing an example of a simulation performed by a robot system simulation apparatus according to a fifth embodiment; FIG. 11 is a diagram showing an example of a simulation performed by a robot system simulation apparatus according to a fifth embodiment; FIG. 11 is a diagram showing an example of a simulation performed by a robot system simulation apparatus according to a fifth embodiment; FIG. 14 is a diagram showing an example of a simulation performed by a robot system simulation device according to a sixth embodiment; FIG. 14 is a diagram showing an example of a simulation performed by a robot system simulation device according to a sixth embodiment; FIG. 11 is a diagram (block diagram) showing another configuration example of the robot system; FIG. 11 is a diagram (block diagram) showing another configuration example of the robot system;

DETAILED DESCRIPTION OF THE INVENTION A simulation device, a control device, and a robot according to the present invention will be described in detail below based on embodiments shown in the accompanying drawings.

<First Embodiment>
<<Robot System>> FIG. 1 is a diagram showing a robot system according to an embodiment. FIG. 2 is a block diagram of the robot system shown in FIG. 3 to 11 are diagrams showing examples of screens displayed on the display device. 12 to 16 are diagrams showing examples of simulations performed by the robot system simulation apparatus shown in FIG.

In addition, in FIG. 1, xr-axis, yr-axis and zr-axis are illustrated as three axes orthogonal to each other. (negative)”. Also, the zr-axis direction in FIG. 1 is defined as the “vertical direction”, and the direction along the xr-yr plane is defined as the “horizontal direction”. Also, the +zr axis side is defined as "upper" and the -zr axis side is defined as "lower".

Further, hereinafter, for convenience of explanation, the upper side in FIGS. 1 and 3 is called "upper" or "upper", and the lower side is called "lower" or "lower". In addition, the base side in FIGS. 1 and 3 is called the "proximal end" or "upstream", and the opposite side is called the "distal end" or "downstream". Moreover, the vertical direction in FIGS. 1 and 3 is the vertical direction.

Moreover, in this specification, the term “horizontal” includes not only a completely horizontal case but also a case of being inclined within ±5° with respect to the horizontal. Similarly, in this specification, "vertical" includes not only completely vertical but also inclined within ±5° with respect to the vertical. In this specification, the term “parallel” includes not only the case where two lines (including axes) or planes are completely parallel to each other, but also the case where they are inclined within ±5°. In this specification, the term "perpendicular" includes not only the case where two lines (including axes) or planes are completely perpendicular to each other, but also the case where they are inclined within ±5°.

A robot system 100 shown in FIG. 1 includes a robot 1 , a robot control device 2 (control device) that controls the operation (driving) of the robot 1 , and a simulation device 5 that can communicate with the robot control device 2 .

Each part of the robot system 100 will be described in order below.
<Robot> The robot 1 is a so-called 6-axis vertical articulated robot, and is used, for example, in manufacturing processes for manufacturing precision equipment and the like, and is used to hold objects (not shown) such as precision equipment and parts. Carry out work such as transportation. The robot 1 has a base 110 and a robot arm 10 (movable part) connected to the base 110 . Note that the object to be held is not particularly limited as long as it is used in the work performed by the robot 1 .

The base 110 is a part for attaching the robot 1 to an arbitrary installation location 70 such as a floor. The robot arm 10 includes an arm 11 (first arm), an arm 12 (second arm), an arm 13 (third arm), an arm 14 (fourth arm), an arm 15 (fifth arm) and an arm 16 (sixth arm). arm). Also, the arm 15 and the arm 16 constitute a wrist. Further, the arm 16 has a disc shape, and an end effector 17 (holding portion) can be detachably provided (attached) to the tip of the arm 16 . These arms 11 to 16 are connected in this order from the base 110 side toward the end effector 17 side. Also, each arm 11 to 16 is rotatable with respect to the adjacent arm or base 110 . That is, the base 110 and the arm 11 are connected via a joint 171 (joint). Also, the arm 11 and the arm 12 are connected via a joint 172 (joint). Also, the arm 12 and the arm 13 are connected via a joint 173 (joint). Also, the arm 13 and the arm 14 are connected via a joint 174 (joint). Also, the arm 14 and the arm 15 are connected via a joint 175 (joint). Also, the arm 15 and the arm 16 are connected via a joint 176 (joint).

The end effector 17 is not particularly limited as long as it can hold and release (cancel holding) the object to be held. A suction head (suction device) capable of (holding) and releasing is used. Another configuration example of the end effector 17 is, for example, a hand capable of gripping (holding) and releasing an object to be held. Further, to hold a holding object means to hold the holding object so as to be able to move the holding object or change the posture of the holding object. Placement, etc. are included.
Also, the tip center of the end effector 17 is called a tool center point P.

Further, as shown in FIG. 2, the robot 1 has a driving section 130 including a motor, a speed reducer, etc. for rotating one arm with respect to the other arm (or the base 110). As the motor, for example, a servomotor such as an AC servomotor or a DC servomotor can be used. As the speed reducer, for example, a planetary gear type speed reducer, a wave gear device, or the like can be used. The robot 1 also has an angle sensor 140 that detects the rotation angle of the rotation shaft of the motor or speed reducer. As the angle sensor 140, for example, a rotary encoder or the like can be used. Driving units 130 and angle sensors 140 are provided corresponding to the respective arms 11 to 16, and the robot 1 has six driving units 130 and six angle sensors 140 in this embodiment.

Further, although not shown, each drive unit 130 is electrically connected (hereinafter also simply referred to as "connection") to a motor driver built in the base 110 shown in FIG. 1, for example. Each drive unit 130 is controlled by the robot controller 2 via a corresponding motor driver. Also, each angle sensor 140 is electrically connected to the robot controller 2 . A drive unit (not shown) that drives the end effector 17 is controlled by the robot controller 2 .

The configuration of the robot 1 has been briefly described above. Such a robot 1 is controlled by a robot control device 2, which will be described later. Thereby, the robot 1 can perform appropriate actions.

Although not shown, the robot 1 may include a force detection device (force detection unit) configured by a 6-axis force sensor or the like for detecting the force (including moment) applied to the end effector 17. . The force detection device is arranged, for example, between the arm 16 and the end effector 17 and electrically connected to the robot controller 2 . By providing the force detection device, for example, force control such as impedance control can be performed.

<Robot Control Device> The robot control device 2 controls the motion of the robot 1 . The robot control device 2 is composed of a robot controller that controls the functions of each part of the robot 1, and is connected to the robot 1 and the simulation device 5 so as to be able to communicate with each other.

The robot control device 2 and the robot 1 may be communicably connected in a wired manner using a cable or the like, or may be communicably connected in a wireless manner. Further, the robot control device 2 may be separate from the robot 1, or part or all of it may be built in the robot 1 (for example, the base 110 or the like).

Further, the robot control device 2 and the simulation device 5 may be communicably connected in a wired manner using a cable or the like, or may be communicably connected in a wireless manner.

As shown in FIG. 2, the robot control device 2 includes a control unit 21 having a processor, a storage unit 22 having a memory or the like connected to the control unit 21 in a communicable manner, and an external interface (I/F). and an input/output unit 23 (accepting unit). The external input/output unit 23 is an example of a receiving unit of the robot control device 2 . Each component of the robot controller 2 is interconnected via various buses so as to be able to communicate with each other.

The control unit 21 executes various programs and the like stored in the storage unit 22 . As a result, it is possible to control the motion of the robot 1 and to perform processing such as various calculations and judgments.

Various programs executable by the control unit 21 are saved (stored) in the storage unit 22 . Various data received by the external input/output unit 23 can be stored in the storage unit 22 . The storage unit 22 includes, for example, a volatile memory such as a RAM (Random Access Memory) and a non-volatile memory such as a ROM (Read Only Memory). Note that the storage unit 22 is not limited to a non-detachable type, and may be configured to have a detachable external storage device (not shown).

Examples of various programs include an operation program output from the simulation device 5, a program for correcting or changing the operation program, and the like. The various data include, for example, data relating to the position and orientation of the tool center point P, rotation angles of the arms 11 to 16, and the like.

The external input/output unit 23 has an external interface (I/F) and is used for each connection between the robot 1 and the simulation device 5 .

Such a robot control device 2 controls the robot 1 based on (using) a simulation result (operation program) by a simulation device 5, which will be described later. As a result, the robot 1 can be made to perform an appropriate motion using the motion program created by the simulation device 5 . In addition, since the robot 1 can be operated using the operation program created by the simulation device 5, teaching work on the actual machine can be omitted. Therefore, the teaching time can be greatly shortened compared to teaching by an operator (user) actually operating the robot 1 .

It should be noted that the robot control device 2 may have other configurations added in addition to the configuration described above. Further, the robot control device 2 may be connected to a display device having a display or the like, or an input device such as a mouse or a keyboard. Various programs and data stored in the storage unit 22 may be stored in advance in the storage unit 22, or may be stored in a recording medium (not shown) such as a CD-ROM. It may be provided from this recording medium or may be provided via a network or the like.

<Simulation Apparatus> The simulation apparatus 5 operates a virtual robot 1A, which is a virtualization of the real robot 1, in a virtual space to simulate the motion of the real robot 1 (see FIG. 3, etc.).

The virtual robot 1A corresponds to the actual robot 1 described above (see FIGS. 1 and 3). Specifically, the virtual robot 1A has a virtual base 110A and a virtual robot arm 10A (virtual movable part) connected to the virtual base 110A. The virtual robot arm 10A includes a virtual arm 11A (virtual first arm), a virtual arm 12A (virtual second arm), a virtual arm 13A (virtual third arm), a virtual arm 14A (virtual fourth arm), and a virtual arm. 15A (virtual fifth arm) and virtual arm 16A (virtual sixth arm).
Further, each virtual arm 11A to 16A is rotatable with respect to the adjacent virtual arm or virtual base 110A. That is, the virtual base 110A and the virtual arm 11A are connected via a virtual joint 171A (virtual joint). Also, the virtual arm 11A and the virtual arm 12A are connected via a virtual joint 172A (virtual joint). Also, the virtual arm 12A and the virtual arm 13A are connected via a virtual joint 173A (virtual joint). Also, the virtual arm 13A and the virtual arm 14A are connected via a virtual joint 174A (virtual joint). Also, the virtual arm 14A and the virtual arm 15A are connected via a virtual joint 175A (virtual joint). Also, the virtual arm 15A and the virtual arm 16A are connected via a virtual joint 176A (virtual joint). A virtual end effector 17A (virtual holder) can be detachably attached to the tip of the virtual arm 16A.

In this way, the reference numerals of the respective parts are indicated by adding "A" to the end of the reference numerals in the simulation device 5 (simulation), and are indicated without adding "A" to the reference numerals in the actual device. Further, the name of each part is indicated by adding "virtual" to the beginning of the name in the simulation device 5, and not adding "virtual" to the name in the real machine. For example, except for the virtual robot 1A (robot 1), the holding object in the real machine is assumed to be the virtual holding object 80A in the simulation device 5. FIG. Therefore, what has been described for either the simulation device 5 or the actual machine will not be described for the other. It should be noted that the description of "A" and "virtual" in the simulation device 5 is omitted for some of the tool center point P, the mounting portion, each coordinate system, and the like.

The simulation device 5 shown in FIG. 2 is composed of various computers such as a PC (Personal Computer), and is connected to the robot control device 2 in a communicable manner.

The simulation device 5 includes a control unit 51 including a processor, a storage unit 52 including a memory connected to the control unit 51 so as to be communicable, and an external input/output unit 53 (accepting unit) including an external I/F (interface). and including. The external input/output unit 53 is an example of a receiving unit of the simulation device 5 . Each component of the simulation device 5 is interconnected via various buses so as to be able to communicate with each other.

The control unit 51 executes various programs and the like stored in the storage unit 52 . As a result, it is possible to realize control of the motion of the virtual robot 1A and processing such as various calculations and judgments.

Various programs executable by the control unit 51 are stored in the storage unit 52 . Various data received by the external input/output unit 53 can be stored in the storage unit 52 . The storage unit 52 includes, for example, a volatile memory such as a RAM (Random Access Memory) and a non-volatile memory such as a ROM (Read Only Memory). Note that the storage unit 52 is not limited to a non-detachable type, and may be configured to have a detachable external storage device (not shown).

Examples of the various programs include programs related to setting and execution of off-line teaching by the virtual robot 1A (teaching performed by the robot 1 without using the actual robot 1). The program includes an operation command for operating the virtual robot 1A, an output command for outputting a signal to be displayed on the display device 31, and the like. The various data include, for example, data relating to the position and orientation of the tool center point P, rotation angles of the virtual arms 11A to 16A, and the like.

The external input/output unit 53 has an external I/F (interface) and is used for each connection with the robot control device 2 , the display device 31 and the input device 32 . Therefore, the external input/output unit 53 functions as a receiving unit that receives an operation (command) of the input device 32 by the operator. The external input/output unit 53 also functions as an output unit that outputs signals related to various screens (for example, the screen WD1 in FIG. 3, etc.) to the monitor of the display device 31 .

In addition to the configuration described above, the simulation device 5 may have other configurations added. Various programs and data stored in the storage unit 52 may be stored in advance in the storage unit 52, or may be stored in a recording medium (not shown) such as a CD-ROM. It may be provided from this recording medium or may be provided via a network or the like.

<Display Device and Input Device> The display device 31 (display unit) shown in FIG. 2 includes a display, and has a function of displaying various screens such as the screen WD1 shown in FIG. 3, for example. Therefore, the operator can confirm the operation of the virtual robot 1A through the display device 31. FIG. The display device 31 is not particularly limited, and examples thereof include a direct-view display device such as a liquid crystal display device and an organic EL display device, and a projection display device such as a projector.

The input device 32 (input unit) includes, for example, a mouse and a keyboard. Therefore, by operating the input device 32 , the operator can give instructions (inputs) to the simulation device 5 regarding various processes and the like.

Specifically, the operator performs an operation of clicking on various screens (windows, etc.) displayed on the display device 31 with the mouse of the input device 32, or an operation of inputting characters, numbers, etc. with the keyboard of the input device 32. , it is possible to issue an instruction to the simulation device 5 . Hereinafter, this instruction by the operator using the input device 32 (input by the input device 32) is also referred to as "operation instruction". This operation instruction includes a selection operation for selecting desired contents from the contents displayed on the display device 31 by the input device 32, an input instruction for inputting characters, numbers, etc. by the input device 32, and the like. Input also includes selection.

One display device 31 and one input device 32 may be connected to the simulation device 5, or a plurality of each may be connected. Also, instead of the display device 31 and the input device 32, a display input device (not shown) having the functions of the display device 31 and the input device 32 may be used. For example, a touch panel or the like can be used as the display input device.

The basic configuration of the robot system 100 has been briefly described above. The robot system 100 includes a simulation device 5, a robot control device 2 that controls the motion of the robot 1 based on a simulation result (operation program) by the simulation device 5, the robot 1 controlled by the robot control device 2, have According to such a robot system 100 (simulation device 5), the virtual robot 1A can perform a predetermined work on the display (simulated space) of the display device 31 without using the robot 1 as a real machine. Able to teach and verify the work taught. Therefore, even without using the robot 1 which is an actual machine, for example, the cycle time and the like in the work by the robot 1 can be examined.

<<Simulation>> Next, a simulation performed by the simulation device 5 will be described.

The control unit 51 of the simulation device 5 controls driving of the display device 31, displays a screen WD1 on the display of the display device 31 (see FIG. 3), and displays the virtual robot 1A, the virtual object 71A, 72A etc. are displayed (see FIGS. 12 to 16). That is, the control unit 51 causes the display device 31 to display the simulation by the virtual robot 1A.

In this case, the operator can display the virtual objects 71A and 72A on the screen WD1 by performing a predetermined operation (operation instruction) with the input device 32 . Further, by performing a predetermined operation (operation instruction) with the input device 32, the virtual objects 71A and 72A are respectively arranged (attached) to the attachment portions of the virtual robot 1A. Also, the mounting portion of the virtual robot 1A and the virtual object 71A may be in contact with each other or may be separated from each other. Also, the mounting portion of the virtual robot 1A and the virtual object 72A may be in contact with each other or may be separated from each other.

The virtual objects 71A and 72A are not particularly limited as long as they can be attached to the virtual robot 1A. , virtual camera, virtual extension tube, virtual lens, virtual force sensor, virtual valve (e.g., virtual air valve, etc.), virtual tube (e.g., virtual air tube, etc.), virtual wiring (virtual cable), virtual piping, etc. be done. Such virtual objects 71A and 72A are, for example, CAD objects obtained by reading CAD files, objects generated by the simulation device 5 (for example, cuboids, spheres, prisms, cylinders, pyramids, cones, surfaces, etc.). can be configured with In the following description, as a representative example, the virtual object 71A is a virtual work, and the virtual object 72A is a virtual camera (including a mounting jig). Although specific examples of objects in the real machine corresponding to the virtual objects 71A and 72A are omitted, "virtual" may be removed from the above.

Also, as the attachment portion of the virtual robot 1A, the portion of the virtual robot 1A to which the virtual object 71A can be attached (Since this is a simulation, the virtual robot 1A and the virtual object 71A may be in contact with each other. Also, it is not particularly limited as long as it is spaced apart), and examples thereof include virtual arms 11A to 16A, virtual joints 171A to 176A, and virtual end effector 17A. In the following description, as a representative example, the attachment portion of the virtual object 71A is the tip of the virtual end effector 17A, and the attachment portion of the virtual object 72A is the virtual joint 175A connecting the arm 14A and the arm 15A. to explain.

Note that the number of virtual objects is two in this embodiment, but is not limited to this, and may be, for example, one, or three or more.

First, to explain the outline, the control unit 51 causes the display device 31 to display the virtual robot 1A and the virtual object 71A (see FIG. 12).

Next, the input device 32 is used to input information (operation instruction) regarding whether or not to interlock the virtual robot 1A and the virtual object 71A, and information regarding the attachment portion for attaching the virtual object 71A to the virtual robot 1A. input (operation instruction).

The external input/output unit 53 accepts input of information regarding whether or not to interlock the virtual robot 1A and the virtual object 71A, and input of information regarding the attachment portion for attaching the virtual object 71A to the virtual robot 1A.

Then, the control unit 51 arranges the virtual object 71A at the attachment portion received by the external input/output unit 53 . That is, the control unit 51 causes the display device 31 to display the virtual robot 1A and the virtual objects 71A and 72A arranged at the attachment portion received by the external input/output unit 53 (see FIG. 13).

In addition, when the external input/output unit 53 receives an input (operation instruction) for interlocking the virtual robot 1A and the virtual object 71A to operate, the control unit 51 interlocks with the operation of the virtual robot 1A to operate the virtual object 71A. Operate object 71A. That is, the mounting portion of the virtual object 71A and the virtual object 71A are interlocked (moved integrally). Accordingly, when the mounting portion of the virtual object 71A moves, the virtual object 71A moves along with the mounting portion, and when the orientation of the mounting portion changes, the orientation of the virtual object 71A changes along with the mounting portion. .

Here, "linking the virtual robot 1A (mounting portion) and the virtual object 71A" means that when the virtual robot 1A operates, the position (relative position) and orientation (relative orientation) of the virtual object 71 with respect to the mounting portion ), the virtual object 71A is moved together with the virtual robot 1A.

Since the virtual object 72A is the same as the virtual object 71A, the explanation thereof is omitted.

Next, the operating procedure of the operator, the display of the display device 31, and the like will be described.
First, the case of attaching the virtual object 71A to the virtual robot 1A will be described.

As shown in FIG. 3, the control unit 51 causes the display device 31 to display a screen WD1.
Further, as shown in FIG. 12, the control unit 51 causes the screen WD1 of the display device 31 to display a virtual object 71A. This virtual object 71A is a virtual work, and its shape is a cube.

The operator gives an operation instruction to select the target object [SBox1] from the object tree (see FIG. 4) on the left side of FIG. 3 on the screen WD1. When the external input/output unit 53 receives the operation instruction, the control unit 51 causes the display device 31 to display the context menu 41 as shown in FIG.

Next, the operator gives an operation instruction to select [Part/Mounted Device Setting] 411 in the context menu 41 . When the external input/output unit 53 receives the operation instruction, the control unit 51 displays a dialog 42 as shown in FIG.

Alternatively, instead of displaying the dialog 42, for example, in the property grid (see FIG. 6) on the lower side of the object tree in FIG. An operation instruction to select [Part] or [Mounted Device] may be given. When external input/output unit 53 receives the operation instruction, control unit 51 displays dialog 42 . When [Part] is selected from the drop-down list 431, [Part] is selected as the type (Type) in the dialog 42. FIG. When [Mounted Device] is selected from the drop-down list 431, [Mounted Device] is selected as the type (Type) in the dialog 42. FIG.

Next, as shown in FIG. 7, the worker selects one of [Layout], [Part], and [Mounted Device] as the type (Type) from the drop-down list 421 of the dialog 42. to perform the operation instruction.

[Part] is selected when the virtual object is a virtual part (virtual work) or the like. [Mounted Device] is selected when the virtual object is a virtual arm-mounted device (for example, a virtual camera). [Layout] is registered as the initial value of Type. When [Layout] is registered, the virtual object 71A does not move even if the virtual robot 1A moves, and its position and orientation does not change (keep stationary).

Here, since the virtual object 71A is a virtual work, [Part] is selected as the type (Type) accordingly. A case where [Part] is selected will be described below as an example. When the external input/output unit 53 receives the operation instruction, the control unit 51 sets [Part] as the Type. Then, when a later-described button 441 (see FIG. 8) is pressed, the control unit 51 registers [Part] as the Type (stores it in the storage unit 52).
Here, when [Part] is selected, "Joint" cannot be selected and only "Tool" can be selected as a mounting portion for mounting a virtual object 71A, which will be described later. Alternatively, such selection restrictions may not be imposed.

Next, as shown in FIG. 8, the operator gives an operation instruction to select a virtual robot (Robot) with numbers "1", "2", . . .

Here, a plurality of virtual robots (for example, virtual horizontal articulated robots such as virtual vertical articulated robots and virtual scalar robots) are associated with the numbers. For example, "1" corresponds to the virtual robot 1A shown in FIG. A case where "1" is selected, that is, a case where the virtual robot 1A is selected will be described below as an example. When the external input/output unit 53 receives the operation instruction, the control unit 51 sets "virtual robot 1A" as the virtual robot. When a button 441 (see FIG. 8) is pressed as will be described later, the controller 51 registers "virtual robot 1A" as a virtual robot.

Next, the operator selects the mounting portion (Tool) for mounting the virtual object 71A, that is, the tool coordinate system (coordinate system) provided in the mounting portion, in the drop-down list 423 of the dialog 42, from "0" to " 1”, “2”, . . .

Here, a plurality of tool coordinate systems (coordinate systems) having three mutually orthogonal axes are set in the virtual robot 1A, and at least a part of each tool coordinate system is associated with the number. is done. For example, "1" corresponds to the tool coordinate system 41A (see FIG. 12) whose origin is the tip center of the end effector 17A. Hereinafter, a case where "1" is selected, that is, a case where the tip of the virtual end effector 17A (the tool coordinate system 41A provided in the virtual end effector 17A) is selected as the attachment portion will be described as an example. When the external input/output unit 53 receives the operation instruction, the control unit 51 sets the "tip of the virtual end effector 17A (tool coordinate system 41A)" as the attachment portion. Thereby, as shown in FIG. 13, the controller 51 places the virtual object 71A at the tip of the virtual end effector 17A. When a button 441 (see FIG. 8) is pressed as will be described later, the controller 51 registers the "tip of the virtual end effector 17A (tool coordinate system 41A)" as the attachment portion. Thereby, the control unit 51 holds (attaches) the virtual object 71A to the tip of the virtual end effector 17A. That is, when the virtual robot 1A operates, the controller 51 interlocks the tip of the virtual end effector 17A and the virtual object 71A.

Also, in [Offset From Selected Tool or Joint] 46, the position (relative position) and orientation (relative orientation) of the virtual object 71A with respect to the [Tool] selected in the drop-down list 423 can be set (registered). That is, the virtual object 71A placed at the tip of the virtual end effector 17A can change its position and position from the tip of the virtual end effector 17A.

First, when each number of [Position] and [Rotation] of [Offset From Selected Tool or Joint] 46 is "0", the virtual object 71A is positioned between the origin coordinate system 46A described later of the virtual object 71A and the drop position. It is arranged so as to match the tool coordinate system 41A selected in the down list 423 (see FIG. 13). That is, the virtual object 71A is arranged so that the origin of the origin coordinate system 46A of the virtual object 71A coincides with the origin of the tool coordinate system 41A, and the posture of the origin coordinate system 46A and the posture of the tool coordinate system 41A become the same. placed in Therefore, when the external input/output unit 53 receives an input to operate the virtual robot 1A and the virtual object 71A in conjunction with each other, the control unit 51 controls the origin of the origin coordinate system 46A of the virtual object 71A and the tool coordinate system. It is displayed on the display device 31 in a state in which the origin of 41A is matched. This makes it possible to easily arrange the virtual object 71A at an appropriate position.

Then, the operator gives an operation instruction to input each number of [Position] and [Rotation] of [Offset From Selected Tool or Joint] 46, and when the external input/output unit 53 receives the operation instruction, the control unit 51 , the origin coordinate system 46A of the virtual object 71A moves (separates) from the tool coordinate system 41A selected in the drop-down list 423 in the respective axial directions corresponding to the numerical values entered in [Position], The virtual object 71A is displayed on the display device 31 so as to rotate around each corresponding axis by each numerical value input in [Rotation]. Thereby, the virtual object 71A can be arranged at a position spaced apart from the tip of the virtual end effector 17A.

Further, when the operator performs an operation instruction to the button 444 displayed as [Zero Clear] (presses the button 444) and the external input/output unit 53 receives the operation instruction, the control unit 51 performs [Position], [ Rotation] are all set to "0", and the virtual object 71A is arranged so as to correspond to it.

Similarly, in [Offset From Selected Tool or Joint] 46, the position (relative position) and orientation (relative orientation) of the virtual object 72A with respect to the [Joint] selected in the drop-down list 424 can be set (registered). can be done.

In addition, when the operator issues an operation instruction to put a check in the check box 451 displayed as [Render Object Origin], and the external input/output unit 53 receives the operation instruction, the control unit 51 causes the display device 31 to display a virtual The origin coordinate system 46A (coordinate system) of the object 71A (selected object) is displayed. The origin coordinate system 46A is a coordinate system having a predetermined point on the virtual object 71A as the origin and three mutually orthogonal axes. In this embodiment, the origin of the origin coordinate system 46A is located at the center of one surface of the virtual object 71A, and the two axes of the origin coordinate system 46A are parallel to the two sides of the surface that are perpendicular to each other. be.

In addition, when the operator issues an operation instruction to put a check in the check box 452 displayed as [Render Selected Tool], and the external input/output unit 53 accepts the operation instruction, the control unit 51 causes the display device 31 to display the drop The tool coordinate system 41A selected from the down list 423 is displayed.

As a result, by visually confirming that the origin coordinate system 46A of the virtual object 71A and the tool coordinate system 41A match, the virtual object 71A can be easily and accurately aligned with the virtual robot 1A. be able to.

Next, the operator gives an operation instruction to the button 441 displayed as "Register" (presses the button 441). When the external input/output unit 53 receives the operation instruction, the control unit 51 registers each setting (each setting value). As a result, when the virtual robot 1A operates, the controller 51 causes the tip of the virtual end effector 17A, which is the attachment portion of the virtual object 71, to interlock with the virtual object 71A. That is, when the virtual robot 1A operates, the control unit 51 moves the virtual object 71A together with the virtual robot 1A while maintaining the position (relative position) and orientation (relative orientation) of the virtual object 71 with respect to the virtual end effector 17A. make it work. The method of operating the virtual robot 1A is not particularly limited, and examples thereof include a method of jogging, a command, a program, and a method of dragging the virtual robot arm 10A or the like on the screen of the display device 31.

After the registration, if [Part] or [Mounted Device] is registered as the Type, as shown in FIG. press) becomes possible. This makes it possible to cancel the registration. That is, when the operator gives an operation instruction to the button 442 and the external input/output unit 53 receives the operation instruction, the control unit 51 cancels the registration. Accordingly, the control unit 51 does not move the virtual object 71 even if the virtual robot 1</b>A moves, and does not change the position and posture of the virtual object 71 .

Alternatively, instead of pressing the button 442 to cancel the registration, for example, in the property grid (see FIG. 6) on the lower side of the object tree in FIG. 3, the [Type] property drop-down list At 431, an instruction may be given to select Layout. When the external input/output unit 53 receives the operation instruction, the control unit 51 registers [Layout] as the Type. Accordingly, the control unit 51 does not move the virtual object 71 even if the virtual robot 1</b>A moves, and does not change the position and posture of the virtual object 71 .

Further, after the registration, as shown in FIG. 10, it becomes possible to give an operation instruction (press the button 443) to the button 443 displayed as "Update". This makes it possible to change each registered setting (each setting value). That is, when the operator gives an operation instruction to the button 443 and the external input/output unit 53 receives the operation instruction, the control unit 51 updates each registered setting.

Next, the case of attaching the virtual object 72A to the virtual robot 1A will be described, focusing on the differences from the case of attaching the virtual object 72A.

As shown in FIG. 14, the control unit 51 causes the display device 31 to display a virtual object 72A.
This virtual object 72A is a virtual camera.

As shown in FIG. 7, the operator gives an operation instruction to select one of [Layout], [Part], and [Mounted Device] from the drop-down list 421 of the dialog 42 .

Here, since the virtual object 72A is a virtual camera, as shown in FIG. 11, [Mounted Device] is selected as the type (Type) accordingly. A case where [Mounted Device] is selected will be described below as an example. When the external input/output unit 53 receives the operation instruction, the control unit 51 sets [Mounted Device] as the Type. Then, when the button 441 is pressed, the control unit 51 registers [Mounted Device] as the Type. Here, when [Mounted Device] is selected, "Tool" cannot be selected and only "Joint" can be selected as the mounting portion for mounting the virtual object 72A. Alternatively, such selection restrictions may not be imposed.

In addition, the operator selects the attachment portion (Joint) for attaching the virtual object 72A, that is, the coordinate system provided in the attachment portion, from the drop-down list 424 of the dialog 42 as "1", "2", . The operation instruction to select with the number is given.

In this case, a coordinate system is set for each of the joints 171 to 176, and each coordinate system is associated with the number. For example, "5" corresponds to the coordinate system 42A (see FIG. 14) provided at the virtual joint 175A connecting the virtual arm 14A and the virtual arm 15A. In the following, the case where "5" is selected, that is, the case where the virtual joint 175A (the coordinate system 42A provided in the virtual joint 175A) is selected as the attachment part will be described as an example. When the external input/output unit 53 receives the operation instruction, the control unit 51 sets the "virtual joint 175A (coordinate system 42A)" as the attachment portion. Thereby, as shown in FIG. 15, the control unit 51 arranges the virtual object 72A at the virtual joint 175A.
Then, when the button 441 (see FIG. 8) is pressed, the controller 51 registers the "virtual joint 175A (coordinate system 42A)" as the attachment part. Thereby, the controller 51 attaches the virtual object 72A to the virtual joint 175A. That is, when the virtual robot 1A operates, the controller 51 interlocks the virtual joint 175A and the virtual object 72A.

In addition, when the operator issues an operation instruction to put a check in the check box 451 displayed as [Render Object Origin], and the external input/output unit 53 receives the operation instruction, the control unit 51 causes the display device 31 to display a virtual The origin coordinate system 47A (coordinate system) of the object 72A (selected object) is displayed. The origin coordinate system 47A is a coordinate system having a predetermined point on the virtual object 72A as the origin and three mutually orthogonal axes. In this embodiment, the origin of the origin coordinate system 47A is arranged at a position spaced apart from the virtual object 72A.

Further, when the operator issues an operation instruction to put a check in the check box 453 labeled as [Render Selected Joint], and the external input/output unit 53 accepts the operation instruction, the control unit 51 causes the display device 31 to display the drop The coordinate system 42A provided for the virtual joint 175A selected in the down list 424 is displayed.

As a result, by visually confirming that the origin coordinate system 47A of the virtual object 72A and the coordinate system 42A match, the virtual object 72A can be easily and accurately aligned with the virtual robot 1A. can be done.

It should be noted that other than the operation procedures and actions described above are the same as in the case of attaching the virtual object 71A to the virtual robot 1A, so description thereof will be omitted.

As described above, the virtual objects 71A and 72A are attached to the virtual robot 1A as shown in FIG.

As described above, according to the robot system 100, in the simulation, the input of information regarding whether or not to interlock the virtual robot 1A and the virtual object 71A and the attachment of the virtual object 71A to the virtual robot 1A. By inputting information about the mounting portion, the virtual object 71A can be easily placed on the mounting portion, and the virtual object 71A can be moved in conjunction with the motion of the virtual robot 1A. As a result, it is possible to easily perform a simulation suitable for the actual machine.

In addition, off-line teaching can be performed by simulation, and an operation program for the robot 1 can be created and verified.

As described above, the simulation device 5 is a simulation device that performs a simulation using the virtual robot 1A, which is a virtualization of the robot 1. FIG. The simulation device 5 receives an input of information regarding whether or not to interlock the virtual robot 1A and the virtual object 71A and an input of information regarding an attachment portion for attaching the virtual object 71A to the virtual robot 1A. The output unit 53 (accepting unit), the virtual robot 1A, and the virtual object 71A attached to the attachment portion accepted by the external input/output unit 53 (accepting unit) are displayed on the display device 31, and the virtual robot 1A and the virtual robot 1A are displayed. a control unit 51 that operates the virtual object 71A in conjunction with the operation of the virtual robot 1A when the external input/output unit 53 (receiving unit) receives an input that causes the virtual object 71A to operate in conjunction with the object 71A; Prepare.

According to such a simulation apparatus 5, input of information regarding whether or not to interlock the virtual robot 1A and the virtual object 71A and input of information regarding the attachment portion for attaching the virtual object 71A to the virtual robot 1A. By doing the above, the virtual object 71A can be easily attached to the attachment portion, and the virtual object 71A can be operated in conjunction with the operation of the virtual robot 1A. As a result, it is possible to easily perform a simulation suitable for the actual machine.

Moreover, it is preferable that the position of the virtual object 71A attached to the attachment portion can be changed from the attachment portion. Thereby, the virtual object 71A can be arranged at a position spaced apart from the mounting portion.

Also, the attachment portion includes a virtual joint 175A that the virtual robot 1A has. Thereby, the virtual object 71A can be attached to the virtual joint 175A of the virtual robot 1A.

In addition, the external input/output unit 53 (accepting unit) can accept selection of one coordinate system from a plurality of coordinate systems possessed by the virtual robot 1A. When the external input/output unit 53 (receiving unit) receives an input to operate in conjunction with , the origin of the selected coordinate system is aligned with the origin of the coordinate system of the virtual object 71A, and the display on the device 31. This makes it possible to easily arrange the virtual object 71A at an appropriate position.

Also, the robot control device 2 (control device) controls the robot 1 based on the simulation result by the simulation device 5 .

According to such a robot control device 2 (control device), it is possible to cause the robot 1 to perform an appropriate motion using the motion program created by the simulation device 5 .

The robot 1 also has an attachment portion to which an object can be attached, and is controlled by a robot control device 2 (control device).

According to such a robot 1, it is possible to perform appropriate actions under the control of the robot control device 2 (control device).

Also, the simulation device 5 is a simulation device that performs a simulation using a virtual robot 1A that is a virtualization of the robot 1, and has a control unit 51 that includes a processor. The processor receives an input of information regarding whether or not to interlock the virtual robot 1A and the virtual object 71A and an input of information regarding an attachment portion for attaching the virtual object 71A to the virtual robot 1A. When the robot 1A and the virtual object 71A attached to the received attachment portion are displayed on the display device 31, and an input to operate the virtual robot 1A and the virtual object 71A in conjunction with each other is received, the virtual robot 1A is displayed. The virtual object 71A is moved in conjunction with the operation of .

According to such a simulation apparatus 5, input of information regarding whether or not to interlock the virtual robot 1A and the virtual object 71A and input of information regarding the attachment portion for attaching the virtual object 71A to the virtual robot 1A. By doing the above, the virtual object 71A can be easily attached to the attachment portion, and the virtual object 71A can be operated in conjunction with the operation of the virtual robot 1A. As a result, it is possible to easily perform a simulation suitable for the actual machine.

<Second embodiment>
FIG. 17 is a diagram showing an example of a screen displayed on the display device of the robot system according to the second embodiment. 18 to 23 are diagrams showing examples of simulations performed by the robot system simulation apparatus according to the second embodiment.

The second embodiment will be described below, but the description will focus on the differences from the above-described embodiment, and the description of the same items will be omitted.

As shown in FIGS. 19 and 21, in the simulation device 5 of the second embodiment, a virtual object as a virtual object is placed at the tip of the virtual arm 16A of the virtual robot 1A (between the virtual arm 16A and the virtual end effector 6A). It is possible to provide (attach) the force sensor 18A. Strictly speaking, a virtual flange 19A (virtual object) used to attach the virtual force sensor 18A to the virtual arm 16A and a virtual force sensor 18A (virtual object) are located at the tip of the virtual arm 16A. provided in order. In addition, the virtual force sensor 18A and the virtual flange 19A are integrated and operate in conjunction with each other. ”. A specific description will be given below.

The control unit 51 of the simulation device 5 controls driving of the display device 31, displays the screen WD1 on the display of the display device 31 (see FIG. 3), and performs simulation. displays a screen WD2 shown in FIG. On this screen WD2, it is possible to register various types of information regarding the virtual force sensor 18A.

When registering information related to the virtual force sensor 18A, the operator performs an operation instruction to enter the sensor name of the virtual force sensor 18A in the text box 471 for input. In this embodiment, "ForceSensor1" is entered as the sensor name. When the external input/output unit 53 receives the operation instruction, the control unit 51 registers "ForceSensor1" as the sensor name.

In addition, the operator performs an operation instruction to select a virtual robot (robot connection) to which the virtual force sensor 18A is provided by using numbers "1", "2", . . .

Here, a plurality of virtual robots (for example, virtual horizontal articulated robots such as virtual vertical articulated robots and virtual scalar robots) are associated with the numbers. Also, the fact that the virtual force sensor 18A is not provided is associated with the number. For example, "1" corresponds to the virtual robot 1A shown in FIG. Also, "3" corresponds to not providing the virtual force sensor 18A. A case where "1" is selected, that is, a case where the virtual robot 1A is selected will be described below as an example. When the external input/output unit 53 receives the operation instruction, the control unit 51 registers "virtual robot 1A" as a virtual robot.

When the registration is completed, simulation can be performed by the simulation device 5 . In the description of the simulation below, the operation procedure for attaching the virtual force sensor 18A to the virtual robot 1A is the same as or slightly modified from the first embodiment, so description thereof will be omitted.

First, a simulation in which the virtual force sensor 18A is provided at the tip of the virtual arm 16A of the virtual robot 1A will be described.

When the virtual end effector 6A is not provided at the tip of the virtual arm 16A as shown in FIG. 18, the virtual force sensor 18A is provided (arranged) at the tip of the virtual arm 16A as shown in FIG. ). That is, when the virtual end effector 6A is not provided to the virtual robot 1A and the virtual force sensor 18A is provided to the virtual robot 1A, the control unit 51 arranges the virtual force sensor 18A at the tip of the virtual arm 16A. state is displayed on the display device 31.

When the virtual end effector 6A is provided at the tip of the virtual arm 16A as shown in FIG. 20, the virtual end effector 6A moves from the tip of the virtual arm 16A in the tip direction as shown in FIG. The virtual force sensor 18A is provided between the virtual arm 16A and the virtual end effector 6A. That is, a virtual force sensor 18A is provided at the tip of the virtual arm 16A, and a virtual end effector 6A is provided at the tip of the virtual force sensor 18A. That is, when the virtual force sensor 18A is provided in the virtual robot 1A while the virtual end effector 6A is provided in the virtual robot 1A, the control unit 51 changes the position of the virtual end effector 6A in the distal direction, The display device 31 displays the sensor 18A arranged between the virtual robot 1A and the virtual end effector 6A. This makes it possible to easily arrange the virtual force sensor 18A and the virtual end effector 6A at the same positions as in the actual machine.

Further, as shown in FIG. 22, before the virtual force sensor 18A is provided, the tool center point P is the tip center of the virtual arm 16A. Then, as shown in FIG. 23, after the virtual force sensor 18A is provided, the tool center point P is changed to the tip center of the virtual force sensor 18A. As a result, there is no need to separately issue an operation instruction to change the tool center point P, labor can be reduced, and the simulation can be performed quickly.

The operator can select either a setting in which the tool center point P is automatically changed, or a setting in which the tool center point P is not changed even if the virtual force sensor 18A is provided. may be

According to the second embodiment as described above, it is possible to exhibit the same effect as the above-described embodiment.

As described above, the virtual object includes the virtual force sensor 18A. Thereby, the virtual force sensor 18A can be attached to the attachment portion.

The virtual object includes the virtual end effector 6A, and the control unit 51 attaches the virtual force sensor 18A to the virtual robot 1A in a state where the virtual end effector 6A is attached to the virtual robot 1A. The position of 6A is changed, and the display device 31 displays the virtual force sensor 18A attached between the virtual robot 1A and the virtual end effector 6A. This makes it possible to easily arrange the virtual force sensor 18A and the virtual end effector 6A at the same positions as in the actual machine.

<Third Embodiment>
24 and 25 are diagrams each showing an example of a simulation performed by the robot system simulation apparatus according to the third embodiment.

Hereinafter, the third embodiment will be described, but the description will focus on the differences from the above-described embodiments, and the description of the same items will be omitted.

As shown in FIG. 24, in the simulation device 5 of the third embodiment, the controller 51 causes the display device 31 to display the force sensor coordinate system 91A of the virtual force sensor 18A.
The force sensor coordinate system 91A is a three-dimensional coordinate system having three mutually orthogonal axes, and each axis is a force detection axis detected by the force sensor 18A. Thereby, the force sensor coordinate system 91A can be grasped.

Further, the control unit 51 causes the display device 31 to display a force coordinate system 92A whose origin is an action point 96A at which the virtual end effector 7A or the virtual object 80A held by the virtual end effector 7A acts on another virtual object. Let In this embodiment, as the force coordinate system 92A, a coordinate system whose origin is an action point 96A at which a virtual object 80A held by the virtual end effector 7A acts on another virtual object will be described as an example. Further, in the present embodiment, the case where the virtual object 80A to be held is a virtual work will be described as an example. This force coordinate system 92A is a three-dimensional coordinate system having three mutually orthogonal axes for performing functions using forces detected by the virtual force sensor 18A. It faces the direction of each component of the force applied to the point of action 96A. Thereby, the action point 96A of the virtual held object 80A held by the virtual end effector 7A and the force coordinate system 92A can be grasped.

Further, the control unit 51 causes the display device 31 to display the magnitude of the force acting on the point of action 96A. Thereby, the force applied to the point of action 96A of the virtual held object 80A held by the virtual end effector 7A can be grasped.

In addition, the method of displaying the magnitude of the force acting on the point of action 96A is not particularly limited. is mentioned. In addition, in the case of the method of displaying by the size of the arrow, it may be displayed by the size of the arrow that constitutes the force coordinate system 92A. You may display by the size of the other arrow.

In this embodiment, the magnitude of the force acting on the point of action 96A is represented by the magnitude of the arrows forming the force coordinate system 92A. Also, the size of the arrow means the length of the arrow and the thickness of the arrow. Also, the magnitude of the force may be displayed by the length of the arrow alone, may be displayed by the thickness of the arrow alone, or may be displayed by the length and thickness of the arrow.

Specifically, the translational force in each axial direction of the force coordinate system 92A is indicated by an arrow on each axis of the force coordinate system 92A. Also, the magnitude of each translational force is represented by at least one of the length and thickness of the arrow.

Also, as shown in FIG. 25, the torque (moment) around each axis of the force coordinate system 92A is indicated by arrows around each axis of the force coordinate system 92A. Also, the magnitude of each torque is represented by at least one of the length and thickness of the arrow.

As a result, the magnitude of the force applied to the point of action 96A of the virtual held object 80A held by the virtual end effector 7A can be expressed in a simple configuration in an easy-to-understand manner. This makes it possible to easily and quickly grasp the magnitude of the force.

According to the third embodiment as described above, it is possible to exhibit the same effect as the above-described embodiment.

As described above, the control unit 51 of the simulation device 5 causes the display device 31 to display the force sensor coordinate system 91A of the virtual force sensor 18A. Thereby, the force sensor coordinate system 91A can be grasped. Each axis of the force sensor coordinate system 91A is a force detection axis detected by the virtual force sensor 18A.

The virtual object includes the virtual end effector 7A, and the controller 51 controls the point of action 96A at which the virtual end effector 7A or the virtual held object 80A held by the virtual end effector 7A acts on another virtual object. The display device 31 displays the force coordinate system 92A. Thereby, the action point 96A of the virtual end effector 7A or the virtual held object 80A held by the virtual end effector 7A and the force coordinate system 92A can be grasped. This force coordinate system 92A is a coordinate system for executing a function using the force detected by the virtual force sensor 18A. facing the direction

Further, the control unit 51 causes the display device 31 to display the magnitude of the force acting on the point of action 96A. Thereby, the force applied to the point of action 96A of the virtual end effector 7A or the virtual held object 80A held by the virtual end effector 7A can be grasped.

Also, the magnitude of the force acting on the point of action 96A is represented by the size of the arrow. This makes it possible to easily grasp the force applied to the point of action 96A of the virtual end effector 7A or the virtual held object 80A held by the virtual end effector 7A.

<Fourth Embodiment>
26 and 27 are diagrams respectively showing examples of simulations performed by the robot system simulation device according to the fourth embodiment.

The fourth embodiment will be described below, but the description will focus on the differences from the above-described embodiments, and the description of the same items will be omitted.

The simulation device 5 of the fourth embodiment detects interference (for example, collision, contact, etc.) between a virtual object different from the attachment portion and the virtual object, and when interference occurs (interference is detected), the virtual object It has a function of displaying (notifying) on the display device 31 that an object and a virtual object interfere with each other.

As shown in FIGS. 26 and 27, in this embodiment, the virtual object is a virtual force sensor 18A and a virtual flange 19A used for attaching the virtual force sensor 18A to the virtual arm 16A. A virtual object 76A will be described as an example of a virtual object different from the attachment portion. In addition, examples of the virtual object include those exemplified in the first embodiment. good. A specific description will be given below.

When the external input/output unit 53 receives an input for interlocking the virtual robot 1A and the virtual force sensor 18A, the control unit 51 detects interference between the virtual force sensor 18A and the virtual object 76A. , to detect interference between the virtual flange 19A and the virtual object 76A. In this case, the detection of the interference between the virtual force sensor 18A and the virtual object 76A and the detection of the interference between the virtual flange 19A and the virtual object 76A may be performed first, or may be performed simultaneously. .

Further, the control unit 51 does not detect interference between the virtual force sensor 18A and the virtual arm 16, and does not detect interference between the virtual flange 19A and the virtual arm 16. FIG. Further, the control unit 51 does not detect interference between the virtual force sensor 18A and the virtual end effector (not shown), and does not detect interference between the virtual flange 19A and the virtual end effector (not shown). Further, in the case of the virtual objects 71A and 72A of the first embodiment, the control unit 51 does not detect interference between the virtual object 71A and the virtual end effector 17A, and the virtual object 72A and the virtual joint 175 ( Interference with virtual arm 14 and virtual arm 15) is not detected.

As shown in FIG. 26, when the virtual force sensor 18A and the virtual object 76A interfere with each other, the control unit 51 causes the display device 31 to display that the virtual force sensor 18A and the virtual object 76A interfere with each other. This makes it possible to easily grasp that the virtual force sensor 18A and the virtual object 76A interfere with each other.

Further, as shown in FIG. 27, when the virtual flange 19A and the virtual object 76A interfere with each other, the control unit 51 causes the display device 31 to display that the virtual flange 19A and the virtual object 76A interfere with each other. Thereby, it is possible to easily grasp that the virtual flange 19A and the virtual object 76A interfere with each other.

When the virtual force sensor 18A and the virtual flange 19A interfere with the virtual object 76A (not shown), the controller 51 controls the virtual force sensor 18A and the virtual flange 19A to interfere with the virtual object 76A. The display device 31 displays what has been done. Thereby, it is possible to easily grasp that the virtual force sensor 18A and the virtual flange 19A interfere with the virtual object 76A.

Therefore, it is possible to easily verify the arrangement of the peripheral devices, verify the operation paths, etc. before creating the actual device.

Here, in order to display the interference on the display device 31, the display mode of the display device 31 is changed, but the display method (notification method) is not particularly limited. A method of displaying, a method of changing colors, and the like can be mentioned.

This embodiment employs a method of changing the color of the object that interferes.
That is, as shown in FIG. 26, when the virtual force sensor 18A interferes with the virtual object 76A, the entire color of the virtual force sensor 18A is changed to another color. In FIG. 26, the virtual force sensor 18A is shaded to indicate that the color has been changed. Thereby, it is possible to easily and accurately grasp that the virtual force sensor 18A interferes with the virtual object 76A instead of the virtual flange 19A. It should be noted that a part of the color of the virtual force sensor 18A may be changed to another color instead of the color of the entire virtual force sensor 18A. In addition, not only the virtual force sensor 18A but also the entire or partial color of the virtual object 76A may be changed to another color. In this case, the changed color of the virtual object 76A and the changed color of the virtual force sensor 18A may be the same or different.

In addition, the color after change is not particularly limited, and can be appropriately set according to various conditions. Examples include red, yellow, orange, purple, etc. One color may be used, and multiple colors may be used. Among the above colors, red is preferable because it is a color that makes it easy to imagine that the virtual force sensor 18A and the virtual object 76A interfere with each other. Moreover, the color after the change can be changed to various colors, for example, an arbitrary color can be selected from a plurality of colors such as red, yellow, orange, and purple.

Also, as shown in FIG. 27, when the virtual flange 19A and the virtual object 76A interfere with each other, the entire color of the virtual flange 19A is changed to another color. The changed color of the virtual flange 19A and the changed color of the virtual force sensor 18A may be the same or different. In addition, in FIG. 27, the imaginary flange 19A is shaded to indicate that the color has been changed. Thereby, it is possible to easily and accurately grasp that the virtual flange 19A and the virtual object 76A interfere with each other, not the virtual force sensor 18A. Note that a part of the virtual flange 19A may be changed to another color instead of the entire color. Further, not only the virtual flange 19A but also the entire color of the virtual object 76A or a part of the virtual object 76A may be changed to another color. In this case, the changed color of the virtual object 76A and the changed color of the virtual flange 19A may be the same or different. Note that the post-change colors are the same as those of the virtual force sensor 18A, so description thereof will be omitted.

Also, although not shown, if the virtual force sensor 18A and the virtual flange 19A interfere with the virtual object 76A, the entire color of the virtual force sensor 18A and the virtual flange 19A is changed to another color. The changed color of the virtual flange 19A and the changed color of the virtual force sensor 18A may be the same or different. This makes it possible to easily and accurately grasp that the virtual force sensor 18A and the virtual flange 19A interfere with the virtual object 76A. It should be noted that a part of the color of the virtual force sensor 18A may be changed to another color instead of the color of the entire virtual force sensor 18A. Further, instead of changing the color of the entire virtual flange 19A, a part of the virtual flange 19A may be changed to another color. Also, not only the virtual force sensor 18A and the virtual flange 19A, but also the color of the entire virtual object 76A or a part thereof may be changed to another color. In this case, the changed color of the virtual object 76A and the changed color of the virtual force sensor 18A may be the same or different. Further, the changed color of the virtual object 76A and the changed color of the virtual flange 19A may be the same or different. Note that the post-change colors are the same as those of the virtual force sensor 18A, so description thereof will be omitted.

According to the fourth embodiment as described above, the same effects as those of the above-described embodiments can be exhibited.

As described above, when the external input/output unit 53 (receiving unit) receives an input that causes the virtual robot 1A and the virtual force sensor 18A (virtual object) to operate in conjunction with each other, the control unit 51 controls the attachment portion. When the virtual object 76A different from the installation part and the virtual force sensor 18A (virtual object) interfere with each other, it is displayed that the virtual object 76A different from the mounting part interferes with the virtual force sensor 18A (virtual object). display on the device 31. Thereby, it is possible to easily grasp that the virtual object 76A different from the attachment portion interferes with the virtual force sensor 18A (virtual object). This makes it possible to easily verify the arrangement of peripheral devices, verify the operation paths, etc., before creating an actual device.

<Fifth Embodiment>
28 to 34 are diagrams showing examples of simulations performed by the robot system simulation apparatus according to the fifth embodiment.

The fifth embodiment will be described below, but the description will focus on the differences from the above-described embodiments, and the description of the same items will be omitted.

As shown in FIGS. 28 to 34, in the simulation device 5 of the fifth embodiment, the controller 51 causes the display device 31 to display the motion direction of the virtual robot 1A. In this embodiment, the control unit 51 causes the force coordinate system 922A to be displayed, and the display device 31 uses at least one of the arrow 502A indicating the translational direction and the arrow 504A indicating the rotational direction of the virtual arm 16A as the movement direction of the virtual robot 1A. to display. In this embodiment, the translational direction of the virtual arm 16A is the direction in which the tip center P2 of the virtual arm 16A moves. In this embodiment, the force coordinate system 922A has the tip center P2 of the virtual arm 16A as its origin, and has three mutually orthogonal axes for performing functions using the force detected by the virtual force sensor 18A. It is a three-dimensional coordinate system. For example, the force coordinate system 92A in the third embodiment is obtained by subjecting the force coordinate system 922A in the present embodiment to coordinate transformation. In this embodiment, the control unit 51 calculates the movement amount of the virtual arm 16A according to the instructed work, and changes the arrow 502A indicating the translation direction and the arrow 504A indicating the rotation direction according to the calculated movement amount. create.

FIG. 28 shows an example of display when the virtual arm 16A translates in the direction along the Fz direction. In this embodiment, the direction indicated by the arrow 502A is the direction of pressing accompanying the operation. In this embodiment, the controller 51 changes the size of the arrow 502A according to the magnitude of the translational force.

In this embodiment, the simulation device 5 can display the arrow 502A even when the virtual arm 16A moves in a direction in which a plurality of direction components among the Fx direction, the Fy direction, and the Fz direction are synthesized. be. For example, as shown in FIG. 29, the simulation device 5 can display an arrow 502A even when the virtual arm 16A translates along the combined direction of the Fz direction component and the Fy direction component. Further, as shown in FIG. 30, the arrow 502A can be displayed even when the virtual arm 16A translates along the combined direction of the Fx direction component, the Fy direction component, and the Fz direction component.

FIG. 31 shows an example of display when the virtual arm 16A rotates about the Fz direction as the rotation axis, that is, rotates in the Tz direction. In this embodiment, arrow 504A indicates the direction of rotation associated with operation. An arrow 506A indicates the rotation axis when the virtual arm 16A rotates. In this embodiment, the controller 51 changes the size of the arrow 502A according to the magnitude of the rotational force. It is preferable that the arrow 506A indicating the axis of rotation and the arrow 502A indicating the direction of translation be displayed so as to be distinguishable from each other. In this case, for example, the arrows 506A and 502A may be displayed in different colors and may be displayed in different sizes.

In the present embodiment, the simulation device 5 is configured so that when the virtual arm 16A rotates around a rotation axis extending in a direction in which a plurality of directional components of the Fx direction, the Fy direction, and the Fz direction are combined, that is, the Tx direction and the Ty The arrow 504A can be displayed even when rotating in more than one of the direction and the Tz direction. As shown in FIG. 32, the simulation device 5 can display the arrow 506A even when the virtual arm 16A rotates around the combined rotation axis of the Tz rotation direction component and the Ty rotation direction component. Further, as shown in FIG. 33, even when the virtual arm 16A rotates around the rotation axis obtained by synthesizing the Tx rotation direction component, the Ty rotation direction component, and the Tz rotation direction component, the arrow 506A can be displayed. be.

In this embodiment, the simulation device 5 can display the arrows 502A and 504A even when the virtual robot 1A translates and rotates the virtual arm 16A. For example, FIG. 34 shows an example of display when the virtual arm 16A translates in the Fz direction and rotates in the Tz direction.

According to the simulation apparatus 5 of the fifth embodiment described above, the control section 51 causes the display device 31 to display the movement direction of the virtual robot 1A. Therefore, the operator can confirm the movement direction of the virtual robot 1A using the simulation device 5 without actually moving the robot 1 (see 502A and 504A in FIGS. 28 to 34). As a result, for example, when teaching a task using [Offset From Selected Tool or Joint] 46 in FIGS. You can check whether it is correct or not.

In this embodiment, the controller 51 creates the arrows 502A, 504A, and 506A based on the force coordinate system 922A whose origin is the center of the distal end of the virtual arm 16A, but is not limited to this. For example, when the virtual end effector 17A is provided at the tip of the virtual arm 16A, the control unit 51 moves the arrows 502A, 504A, and 506A based on the tool coordinate system having the center of the tip of the virtual end effector as the origin. may be created.

<Sixth Embodiment>
35 and 36 are diagrams respectively showing examples of simulations performed by the robot system simulation apparatus according to the sixth embodiment.

The sixth embodiment will be described below, but the description will focus on the differences from the above-described embodiments, and the description of the same items will be omitted.

In the simulation device 5 of the sixth embodiment, the control unit 51 sets the entry detection plane 510 for indicating the target end position of the motion of the virtual robot 1A and causes the display device 31 to display it. In this embodiment, the control unit 51 sets one of the spaces partitioned by the entry detection plane 510 as the inner side 512 indicating that the virtual arm 16A is passing through the target end position of the motion. In addition, the control unit 51 sets the other of the spaces partitioned by the entry detection plane 510 as an outer side 514 indicating that the virtual arm 16A has not reached the target end position of the motion. In this embodiment, the entry detection plane 510 is displayed on the display device 31 as a plane having a predetermined size and having edges.

The control unit 51 creates the entry detection plane 510 using, for example, the target end position of the motion calculated according to the motion start position, moving direction, and moving distance of the end effector 17A set by the operator. Specifically, the control unit 51 creates, as the entry detection plane 510, a plane that is perpendicular to the direction of movement of the end effector 17A when it moves to the target end position and that includes the tip center of the end effector 17A at the target end position. .

The control device 51 displays a coordinate system 520A having an origin O on the entry detection plane 510. FIG. The coordinate system 520A is a coordinate system independent of the motion of the virtual robot 1A. In this embodiment, the Z-axis of coordinate system 520A is a coordinate axis orthogonal to entrance detection plane 510 . The +Z-axis direction of the coordinate system 520A is the direction away from the entrance detection plane 510 toward the inner side 512 . By displaying the coordinate system 520</b>A, the operator can easily distinguish between the inside 512 and the outside 514 .

As shown in FIGS. 35 and 36, in the present embodiment, the control unit 51 causes the display device 31 to display the posture of the virtual robot 1A at the end of the work when the instructed work is executed, together with the entry detection plane 510. display. As shown in FIG. 35, when the virtual end effector 17A has not reached the target end position as a result of simulating the taught work, the virtual end effector 17A is positioned outside 514 of the entry detection plane 510. . As a result of simulating the taught work, as shown in FIG. 36, when the virtual end effector 17A passes the target end position, the tip side of the virtual end effector 17A is positioned inside 512 of the entrance detection plane 510. ing. As a result of simulating the taught work, the tip side of the virtual end effector 17A is positioned on the entry detection plane 510 when the virtual end effector 17A has reached the target end position.

According to the sixth embodiment described above, the control unit 51 sets the entry detection plane 510 for indicating the target end position of the motion of the virtual robot 1A and causes the display device 31 to display it. Therefore, the operator can use the simulation device 5 to compare the end position of the motion taught by the virtual robot 1</b>A with the target end position without actually operating the robot 1 . Therefore, the operator can easily confirm whether the end position of the taught motion is appropriate.

In the present embodiment, the control unit 51 uses the entry detection plane 510 to display the motion end position of the virtual robot 1A, but the present invention is not limited to this. For example, instead of the entry detection plane 510, the control unit 51 may display an infinite plane perpendicular to the Z-axis of the tool coordinate system 41A at the end position. Further, instead of the entry detection plane 510, the control unit 51 may set and display a space having a three-dimensional spread. The space displayed in this case may be, for example, a space of a predetermined size centered on the tool center point P at the end position. Even in these cases, as in the case where the entry detection plane 510 is displayed, the operator is not allowed to actually move the robot 1, but the end position of the motion taught using the simulation device 5 is appropriate. You can easily check if there is

Further, the control unit 51 changes the color of the virtual robot 1A instead of displaying the coordinate system 520A to determine whether the virtual robot 1A is positioned inside 512 or outside 514 of the entrance detection plane 510. may be displayed. Specifically, for example, the inner area 512 and the outer area 514 of the virtual robot 1A may be displayed in different colors. Even in this case, the operator can easily distinguish between the inner side 512 and the outer side 514 .

In addition to the virtual robot 1</b>A, the control unit 51 may display other virtual robots corresponding to other robots arranged around the robot 1 . In this case, the worker can confirm the relationship between the motion end position of the virtual robot 1A and the positions of the other virtual robots. When displaying other virtual robots on the display device 31 in addition to the virtual robot 1A, the virtual robot 1A and the other virtual robots are preferably displayed in different colors. As a result, even when a plurality of virtual robots including the virtual robot 1A are displayed, the operator can determine whether the robot that has entered the entry detection plane 510 is the virtual robot 1A itself or another virtual robot. or can be determined.

In addition to the entry detection plane 510 of the virtual robot 1A, the control unit 51 may display the entry detection planes of other virtual robots. In this case, the control unit 51 can cause the display device 31 to display the area in which the other virtual robot can move according to the motion using the detection plane of the other virtual robot. It is preferable that the entry detection plane 510 of itself and the entry detection planes of other virtual robots are displayed in different colors. In this case, the worker can easily distinguish between the case where the virtual robot 1A reaches the entry detection plane 510 of the virtual robot 1A itself and the case where the entry detection plane of another virtual robot is reached. .

The robot system 100 has been described above using the first to sixth embodiments. The "robot system" may be in the form shown in FIGS. 37 and 38. FIG.

37 and 38 are diagrams (block diagrams) showing other configuration examples of the robot system.

FIG. 37 shows an overall configuration diagram of a robot system 100B in which a computer 63 is directly connected to the robot 1. As shown in FIG. The control of the robot 1 is directly executed by reading the instructions in the memory by the processor present in the computer 63 . The computer 63 has the functions of the robot control device 2 and the simulation device 5 described above.

FIG. 38 shows the overall configuration of a robot system 100C in which a robot 1 with a built-in controller 61 and a computer 66 are connected, and the computer 66 is connected to a cloud 64 via a network 65 such as a LAN (Local Area Network). Figure shows. The control of the robot 1 may be executed by reading instructions in memory by a processor existing in the computer 66, or may be executed by reading instructions in memory via the computer 66 by a processor existing in the cloud 64. good. The controller 61 has the functions of the robot control device 2 described above, and the computer 66 or the cloud 64 has the functions of the simulation device 5 described above.

Further, in the robot systems 100B and 100C, each processor may be composed of one device, or may be composed of a plurality of devices, that is, may be divided into a plurality of unit processors. good.

The simulation apparatus, control apparatus, and robot of the present invention have been described above based on the illustrated embodiments, but the present invention is not limited to this, and the configuration of each part may be any configuration having similar functions. can be replaced with Also, other optional components may be added.

Further, the present invention may be a combination of any two or more configurations (features) of the above embodiments.

In the above-described embodiment, the robot is a 6-axis vertical multi-joint robot, but the robot is not limited to this. Other forms of robots such as (running) robots may also be used. Further, the robot is not limited to a single-arm robot, and may be another robot such as a double-arm robot. Therefore, the number of robot arms (movable parts) is not limited to one, and may be two or more. Also, the robot arm (movable part) has six arms in the above-described embodiment, but may have one to five arms or seven or more arms.

DESCRIPTION OF SYMBOLS 1... Robot, 1A... Virtual robot, 2... Robot control device, 5... Simulation apparatus, 6A... Virtual end effector, 7A... Virtual end effector, 10... Robot arm, 10A... Virtual robot arm, 11... Arm, 11A... Virtual Arm 12 Arm 12A Virtual Arm 13 Arm 13A Virtual Arm 14 Arm 14A Virtual Arm 15 Arm 15A Virtual Arm 16 Arm 16A Virtual Arm 17 End Effector 17A Virtual end effector 18A Virtual force sensor 19A Virtual flange 21 Control unit 22 Storage unit 23 External input/output unit 31 Display device 32 Input device 41 Context Menu, 41A... Tool coordinate system, 42... Dialog, 42A... Coordinate system, 46... Offset From Selected Tool or Joint, 46A... Origin coordinate system, 47A... Origin coordinate system, 51... Control unit, 52... Storage unit, 53... External input/output unit 61 controller 63 computer 64 cloud 65 network 66 computer 70 installation location 71A virtual object 72A virtual object 76A virtual object 80A virtual Object to be held 91A Force sensor coordinate system 92A Force coordinate system 96A Action point 100 Robot system 100B Robot system 100C Robot system 110 Base 110A Virtual base 130 140 Angle sensor 171 Joint 171A Virtual joint 172 Joint 172A Virtual joint 173 Joint 173A Virtual joint 174 Joint 174A Virtual joint 175 Joint 175A ... Virtual joint 176 ... Joint 176A ... Virtual joint 411 ... Part/Mounted Device Setting 421 ... Drop-down list 422 ... Drop-down list 423 ... Drop-down list 424 ... Drop-down list 431 ... Drop-down list , 441... Button, 442... Button, 443... Button, 444... Button, 451... Check box, 452... Check box, 453... Check box, 471... Text box, 472... Drop down list, 502A... Arrow, 504A... Arrow , 506A... arrow, 510... entrance detection plane, 512... inner side, 514... outer side, 520A... coordinate system, 9 22A... force coordinate system, O... origin, P... tool center point, P2... tool center point, WD1... screen, WD2... screen

Claims (12)

A simulation device that performs a simulation with a virtual robot that virtualizes a robot,
a reception unit that receives input of information regarding whether or not to operate the virtual robot and the virtual object in conjunction with each other, and input of information regarding a mounting portion for mounting the virtual object on the virtual robot;
displaying on a display unit the virtual robot and the virtual object attached to the mounting portion accepted by the accepting unit, and receiving an input to operate the virtual robot and the virtual object in conjunction with each other; a control unit that operates the virtual object in conjunction with the operation of the virtual robot when the
The reception unit receives selection of one coordinate system from a plurality of coordinate systems possessed by the virtual robot.
can be attached,
The control unit receives an input for interlocking and operating the virtual robot and the virtual object.
When the receiving unit receives, the origin of the selected coordinate system and the coordinates of the virtual object
A simulation apparatus characterized in that the display is displayed in a state in which the origin of the reference system coincides with the display . 2. The simulation apparatus according to claim 1, wherein the virtual object attached to the attachment portion can change its position from the attachment portion. 3. The simulation device according to claim 1, wherein the attachment portion includes virtual joints of the virtual robot. When the reception unit receives an input to cause the virtual robot and the virtual object to operate in conjunction with each other, the control unit is configured to control the virtual object to interfere with the virtual object different from the attachment portion, 4. The simulation apparatus according to any one of claims 1 to 3 , wherein the display unit displays that the virtual object different from the attachment portion and the virtual object interfere with each other. 5. The simulation device according to any one of claims 1 to 4 , wherein the virtual object includes a virtual force sensor. the virtual object includes a virtual end effector;
When the virtual force sensor is attached to the virtual robot while the virtual end effector is attached to the virtual robot, the control unit changes the position of the virtual end effector and attaches the virtual force sensor to the virtual robot. 6. The simulation device according to claim 5 , wherein the display is displayed in a state of being attached between the virtual robot and the virtual end effector. 7. The simulation device according to claim 5 , wherein the control unit causes the display unit to display a force sensor coordinate system of the virtual force sensor. the virtual object includes a virtual end effector;
6. The control unit causes the display unit to display a force coordinate system whose origin is a point of action at which the virtual end effector or the virtual held object held by the virtual end effector acts on another virtual object . 8. The simulation device according to any one of 7 . 9. The simulation device according to claim 8 , wherein the control section causes the display section to display the magnitude of the force acting on the point of action. 10. The simulation device according to claim 9 , wherein the magnitude of said force is represented by the magnitude of an arrow. A control device for controlling a robot based on a simulation result by the simulation device according to any one of claims 1 to 10 . Having an attachment part to which an object can be attached,
A robot controlled by the control device according to claim 11 .

Images