Source: https://patents.google.com/patent/JP5893666B2/en
Timestamp: 2020-06-06 06:12:33
Document Index: 295160852

Matched Legal Cases: ['art 58', 'art 72', 'art 21', 'art 58', 'art 58', 'art 22', 'art 23', 'art 24', 'art 25', 'art 31', 'art 58', 'art 59', 'art 72']

JP5893666B2 - Robot control device and robot system for robots that move according to force - Google Patents
Robot control device and robot system for robots that move according to force Download PDF
JP5893666B2
JP5893666B2 JP2014082732A JP2014082732A JP5893666B2 JP 5893666 B2 JP5893666 B2 JP 5893666B2 JP 2014082732 A JP2014082732 A JP 2014082732A JP 2014082732 A JP2014082732 A JP 2014082732A JP 5893666 B2 JP5893666 B2 JP 5893666B2
JP2014082732A
JP2015202537A (en
隆裕 岩竹
2014-04-14 Application filed by ファナック株式会社 filed Critical ファナック株式会社
2014-04-14 Priority to JP2014082732A priority Critical patent/JP5893666B2/en
2015-11-16 Publication of JP2015202537A publication Critical patent/JP2015202537A/en
2016-03-23 Publication of JP5893666B2 publication Critical patent/JP5893666B2/en
The present invention relates to a robot control device that moves a robot based on a force acting on the robot, and the robot and a robot system including the robot control device.
Direct teach is known as a robot operation method for moving a robot by applying a force to the robot and a method for teaching a position by moving the robot. By using this, it is possible to move the robot to a desired position and / or posture on the Cartesian coordinate system by directly guiding the robot by applying a force in a desired moving direction.
As a technology related to this, Patent Document 1 discloses a tip of a robot arm based on a signal generated from the force detector when a manual operation unit of a force detector attached to the tip of the robot arm is operated. A method for moving the position and posture of the camera is disclosed.
Further, in Patent Document 2, when a force sensor provided on a robot detects a force artificially applied to a hand effector and the operation of a robot arm is controlled using a force signal obtained by this detection, an operation is performed. A robot direct teaching apparatus that guides the robot arm only in the direction set by the direction setting means is disclosed.
JP-A-56-85106 Japanese Patent Laid-Open No. 06-250728
The method described in Patent Document 1 can move the position and / or posture of the tip of the robot on the Cartesian coordinate system according to the force, but each axis can be moved to a desired position during direct teaching. It cannot be moved.
In the apparatus described in Patent Document 2, when the robot is moved by direct teaching, the movement direction is limited, and the operability is improved by moving only in the limited direction. This restricting direction is a direction related to the position and / or posture of the robot tip on the Cartesian coordinate system, and during direct teaching, the control is switched to control of each axis and only a desired axis is moved. No method has been proposed for limiting the drive shaft.
Therefore, the present invention can move the robot tip to a position where movement is difficult when a force is applied to the tip of the robot to change the position and / or posture of the robot tip on the Cartesian coordinate system. Furthermore, a robot control device capable of easily moving an axis to a desired position without using a special input device or the like and without performing an input operation for switching the movement method, the robot control device, and the robot It aims at providing the robot system containing.
In order to achieve the above object, the first invention of the present application is directed to a force applied to a tip portion of the robot in a robot control apparatus for moving the robot based on a force applied to a robot composed of a plurality of axes. A force measuring unit for measuring the operating force, an operating force calculating unit for calculating an operating force for moving the position of each axis of the robot based on the force measured by the force measuring unit, and a command for moving the robot And an operation command unit that outputs one or two or more axes that are moved according to the force when the movement is permitted according to the force among the plurality of axes, An operation axis setting unit that sets a movement direction of the operation axis according to the direction of force, and the operation axis setting unit responds to the force according to the force when there is one operation axis. As an operation axis allowed to move Constant, and when the operation shaft is two or more, depending on the circumstances of the move operation based on the direction of the force the force measuring portion is measured with respect to the operating shaft, each of the axis of the said operating shaft The operation axis that is allowed to move according to the force or the operation axis that is not moved even when the force is applied is set, and the operation command unit is the operation axis setting unit And a robot control device that outputs an operation command for moving the position of the operation axis based on the operation force calculated by the operation force calculation unit.
According to a second aspect of the present invention, in the robot control apparatus for moving the robot based on the force applied to the robot composed of a plurality of axes, a force measuring unit that measures the force applied to the tip of the robot; Based on the force measured by the force measurement unit, an operation force calculation unit that calculates an operation force for moving the position of each axis of the robot, an operation command unit that outputs a command to move the robot, Among the plurality of axes, one or two or more axes that are moved according to the force when the movement according to the force is permitted are set as the operation axes, and further according to the direction of the force An operation axis setting unit that sets a movement direction of the operation axis, and the operation axis setting unit is allowed to move the operation axis according to force when the operation axis is one. is set as the operating shaft, the operating shaft are two or more When it is, depending on the status of the mobile operator, on the basis of the positional relationship between the tip portion of the said operating shaft robot, for each of the axis of the said operating shaft, to move in response to a force The operation command unit is set to the operation axis setting unit, and the operation force calculation unit is configured to set the operation axis to be moved. Provided is a robot control device that outputs an operation command for moving the position of the operation axis based on the calculated operation force.
According to a third aspect of the present invention, in the robot control apparatus for moving the robot based on the force applied to the robot composed of a plurality of axes, a force measuring unit that measures the force applied to the tip of the robot; Based on the force measured by the force measurement unit, an operation force calculation unit that calculates an operation force for moving the position of each axis of the robot, an operation command unit that outputs a command to move the robot, Among the plurality of axes, one or two or more axes that are moved according to the force when the movement according to the force is permitted are set as the operation axes, and further according to the direction of the force An operation axis setting unit that sets a movement direction of the operation axis, and the operation axis setting unit is allowed to move the operation axis according to force when the operation axis is one. is set as the operating shaft, the operating shaft are two or more And depending on the situation of the moving operation, at least one of the direction of the force measured by the force measuring unit relative to the operation axis and the positional relationship between the operation axis and the tip of the robot, Based on a predetermined priority order, either the operation axis allowed to move according to the force or the operation axis that does not move even if the force is applied to each of the axes as the operation axis. The operation command unit outputs an operation command for moving the position of the operation axis based on the setting of the operation axis setting unit and the operation force calculated by the operation force calculation unit. A robot control device is provided.
According to a fourth aspect of the present invention, in a robot control apparatus for moving the robot based on a force applied to a robot composed of a plurality of axes including two or more rotation axes, the force applied to the tip of the robot A force measuring unit for measuring the operating force, an operating force calculating unit for calculating an operating force for moving the position of each axis of the robot based on the force measured by the force measuring unit, and a command for moving the robot An operation command unit that outputs the operation axis, and an operation axis setting unit that sets, as the operation axis, an axis to be moved according to a force among the plurality of axes, and further sets a movement direction of the operation axis according to the direction of the force; The operation axis setting unit sets, as the operation axes, two rotation axes in which rotation center lines of the rotation axes are orthogonal regardless of positions of the plurality of axes among the plurality of axes. The command unit is set by the operation axis setting unit, And, based on the operating force the operating force calculating unit is calculated, and outputs an operation command to move the position of the operating shaft, to provide a robot control device.
According to a fifth aspect of the present invention, there is provided a robot control apparatus for moving a robot based on a force applied to a robot including a plurality of axes including two or more rotation axes. A force measuring unit for measuring the operating force, an operating force calculating unit for calculating an operating force for moving the position of each axis of the robot based on the force measured by the force measuring unit, and a command for moving the robot And an operation command unit that outputs, and among the plurality of axes, an axis that is moved according to the force when it is permitted to move according to the force is set as an operation axis, and further according to the direction of the force An operation axis setting unit that sets a movement direction of the operation axis, and the operation axis setting unit has a rotation center line of the rotation axis orthogonal to the position of the plurality of axes among the plurality of axes. Set two rotation axes as the operation axes Depending on the situation of the moving operation, at least one of the direction of the force measured by the force measuring unit with respect to the operation axis, the positional relationship between the operation axis and the tip of the robot, and a predetermined priority order. Based on the above, for each of the axes as the operation axis, either the operation axis allowed to move according to the force or the operation axis that does not move even when a force is applied is set The operation command unit outputs an operation command for moving the position of the operation axis based on the setting of the operation axis setting unit and the operation force calculated by the operation force calculation unit ; provide.
A sixth invention of the present application provides a robot system including the robot control device according to any one of the first to fifth inventions and the robot.
According to a seventh invention of the present application, in the sixth invention, the robot system includes a teaching operation device that inputs a setting to the robot control device, and the operation axis setting unit is based on an input from the teaching operation device. The operation axis is set, and the teaching operation device provides a robot system that selects and inputs from the combinations of the axes that can be set as the operation axis among the axes that can be set as the operation axis.
According to an eighth aspect of the present invention, in the sixth aspect, the robot system includes a teaching operation device that inputs a setting to the robot control device, and the operation axis setting unit receives an input from the teaching operation device. The teaching operating device indicates an axis that can be selected as the operating axis among the plurality of axes, and the axis other than the selected axis is selected based on the selected axis. A robot system is provided that displays at least one of being selectable as the operation axis simultaneously with the selected axis and not being selectable simultaneously with the selected axis.
A ninth invention of the present application is a robot system including the robot control device according to any one of the first to third and fifth inventions and the robot, wherein the robot system includes a display device, and the display device Is a setting when the operation axis setting unit sets an operation axis that is permitted to move the operation axis according to a force or an operation axis that is not moved even when a force is applied. A robot system that displays conditions is provided.
According to a tenth aspect of the present invention, in the seventh or eighth aspect, the teaching operation device is configured based on a rotation center line of a rotation axis among the plurality of axes based on a current axis position of the robot. When the shortest distance to the tip of the robot is equal to or less than a predetermined threshold, it indicates that the tip of the robot exists near the rotation center line of the rotation axis, or the axis as the operation axis A robot system is provided which indicates that the setting of an axis including can not be set.
According to the present invention, in the operation method for moving the robot by applying a force to the tip of the robot, without using a special input device or the like, and without performing an input operation for switching the movement method, The desired axis position can be moved more easily.
It is a figure showing a schematic structure of a robot system provided with a robot controlled by a robot control device concerning one embodiment of the present invention. It is a figure which shows functionally the structure of the robot control apparatus which concerns on one Embodiment of this invention. It is a flowchart which shows the process of the process by the robot control apparatus which concerns on one Embodiment of this invention. It is a figure for demonstrating an example of the method of calculating operation force by the operation force calculation part. It is a figure for demonstrating an example of the method of calculating operation force by the operation force calculation part. It is a figure for demonstrating an example of the method of determining and setting whether it is set as the operation axis to move with respect to an operation axis. It is a figure for demonstrating an example of the method of determining and setting whether it is set as the operation axis to move with respect to an operation axis. It is a figure for demonstrating an example of the method of determining and setting whether it is set as the operation axis to move with respect to an operation axis. It is a flowchart which shows the process of the process by the robot control apparatus which concerns on one Embodiment of this invention. It is a flowchart which shows the process of the process by the robot control apparatus which concerns on one Embodiment of this invention. It is a figure which shows an example of the attachment position of a teaching operation apparatus in the robot system provided with the robot controlled by the robot control apparatus which concerns on one Embodiment of this invention. It is a figure which shows an example of the attachment position of a teaching operation apparatus in the robot system provided with the robot controlled by the robot control apparatus which concerns on one Embodiment of this invention. It is a figure which shows an example of the screen displayed on the teaching operation apparatus which inputs a setting to the robot control apparatus which concerns on one Embodiment of this invention. It is a figure which shows an example of the screen displayed on the teaching operation apparatus which inputs a setting to the robot control apparatus which concerns on one Embodiment of this invention.
Embodiments of the present invention will be described below with reference to the accompanying drawings. In the following drawings, the same members are denoted by the same reference numerals. In order to facilitate understanding, the scale in the drawings is appropriately changed.
In this specification, unless otherwise specified, “force” includes a translational direction component of force and a moment component of force, and “position and / or posture” includes at least one of position and posture. The “axis” is a joint portion that connects the links constituting the robot and links, and is a portion that changes the positional relationship and angular relationship between the links. For example, by changing the position of the axis (the position in the case of the rotation axis is an angle), the positional relationship between the links can be changed, and the position and / or posture of the robot tip can be changed. it can. Note that an actuator for moving the position of the shaft may be arranged at a location different from the portion used as the shaft. Furthermore, the “force control gain” is the force control for moving the robot in accordance with the applied force, and based on the magnitude of the applied force, the robot tip on the Cartesian coordinate system for each control cycle. The coefficient is used to determine the amount of movement such as the position and / or posture and the position of each axis of the robot.
The force acting around the rotation center line of the robot axis or the force acting around the rotation center line of the robot axis means that the robot axis is a rotation axis, and one axis of the coordinate system is When setting the coordinate system for the robot axis so that it coincides with the rotation axis of the robot axis, the plane perpendicular to the rotation axis of the robot axis on the coordinate system and the origin is A translational force existing in the plane, which is the intersection of the axis of rotation of the axis and the plane, or a moment of force acting around the axis of rotation of the robot axis.
FIG. 1 is a schematic diagram illustrating a configuration example of a robot system 11 including a robot control device 10 according to an embodiment of the present invention and a robot 50 controlled by the robot control device 10. The robot control apparatus 10 is configured to control the position of each axis of the robot 50 at a predetermined control cycle.
In the robot system 11, when the operator 60 applies a force (external force) to the distal end portion 58 of the robot 50, the robot control device 10 detects the distal end portion 58 of the robot 50 measured by the force measuring unit 21 (see FIG. 2). Based on the force acting on the robot, the set data, and the position data of the robot 50, the actuator for moving each axis of the robot 50 is controlled to change the position of the axis constituting the robot 50 and move the robot 50. Let The robot control apparatus 10 has a hardware configuration including an arithmetic processing unit, ROM, RAM, and the like, and executes various functions to be described later.
Hereinafter, the structure of the robot 50 will be described more specifically with reference to FIG. In the embodiment of FIG. 1, the robot 50 is a 6-axis vertical articulated robot. However, any robot having the above structure may be used as long as the position of each axis can be controlled and the orthogonal position can be controlled. It can be similarly applied to the known robot. In the present embodiment, all of the six axes are rotational axes, but may include linear motion axes.
The robot 50 has six axes, that is, in order from the side closer to the pedestal 59 of the robot 50, the first axis is the J1 axis 51, the second axis is the J2 axis 52, the third axis is the J3 axis 53, the fourth axis. The axis includes the J4 axis 54, the fifth axis as the J5 axis 55, and the sixth axis as the J6 axis 56. The J1 axis 51, the J4 axis 54, and the J6 axis 56 have a rotation axis R1 that rotates around a link that connects the axes to each other in the drawing (that is, parallel to the paper surface at this axis position), and a J2 axis 52, The J3 axis 53 and the J5 axis 55 have a rotation axis R2 that rotates about a direction that connects the axes to each other and is orthogonal to the link in the drawing (that is, perpendicular to the paper surface at this axis position). FIG. 1 is a simple explanatory diagram for illustrating the configuration of the axis of the robot 50. If the origin of each axis is defined as the origin of the coordinate system set for each axis and the link is connected to the link, the position of the origin of each axis is the coordinate system set in the space (hereinafter, (Also referred to as a reference coordinate system). In the configuration of FIG. 1, the origins of the J1 axis 51 and the J2 axis 52 are at the same position, the origins of the J3 axis 53 and the J4 axis 54 are at the same position, and the origins of the J5 axis 55 and the J6 axis 56 are the same position. Suppose that
In this embodiment, when it is described that the position of the axis is moved with respect to the rotation axis, the position of the axis is a rotation angle of the rotation axis, and “move the position of the axis” means that the rotation axis is moved. It means to change the position by rotating. Further, “the position of the origin of the axis” represents the position of the origin of the coordinate system set for each axis on the coordinate system (reference coordinate system) set for the space. Further, the reference coordinate system is a coordinate system set for each axis on a front end portion 58 and a flange portion 57 (attachment portion of the front end portion 58 to the robot 50) on an orthogonal coordinate system fixed to space. A coordinate system for representing a position and / or posture.
Further, in order to represent the position and / or posture of the robot 50 on the reference coordinate system set for the space, the coordinate system set for the robot 50 is a tool coordinate system, which is the origin of the tool coordinate system, and The control point is a point to be translated or a center point to be rotationally moved. Further, a coordinate system set for the control points in parallel with the reference coordinate system is defined as a control coordinate system. Note that the position of the control point may be any position as long as it is a position set for the robot 50.
The distal end portion 58 of the robot 50 is a portion where an object attached to the distal end side (the flange portion 57 of the robot 50) of the axis farther from the pedestal 59 of the robot 50 (here, the J6 axis 56) exists. Although not shown, a six-axis force sensor is attached to the tip 58 of the robot 50. Based on the output of the force sensor detected every predetermined time, the robot control apparatus 10 measures the force applied by the operator to the tip portion 58 of the robot 50 by the force measuring unit 21.
The force measuring unit 21 sets a coordinate system having an origin at a point at which the force is measured at the tip 58 of the robot 50, and the force measured on the coordinate system is applied to the tip 58 of the robot 50. The component F in the translational direction and the moment component M of the force are measured. Hereinafter, this coordinate system is a force measurement coordinate system, and the origin of the force measurement coordinate system is a force measurement point. At this time, the translational direction components of the X-axis, Y-axis, and Z-axis forces of the coordinate system set at the tip portion 58 of the robot 50 are represented as Fx, Fy, and Fz, respectively, and around the X-axis, Y-axis, and Z-axis. The detected moment components of the force are represented as Mx, My, and Mz, respectively.
Here, the force measurement point can be set to an action point where the operator applies force, or an origin of the sensor coordinate system set on the force sensor, a point on an axis of the sensor coordinate system, or the like. In this embodiment, six components are measured, but a force translation direction component F or a force moment component M may be measured. Further, the position where the force sensor is attached may be an arbitrary position as long as the force applied to the tip portion 58 of the robot 50 can be measured. Further, the measuring means for measuring the force acting on the distal end portion 58 of the robot 50 may not be a 6-axis force sensor, and for example, a 3-axis force sensor may be used. Alternatively, instead of using the force sensor, the current value when the actuator that moves the axis constituting the robot 50 is a motor, or the deviation between the command position of the axis and the actual axis position, or You may estimate the force which acts on the front-end | tip part 58 of the robot 50 based on the output of the torque sensor attached to the axis | shaft.
A tool for performing work such as processing a workpiece or transporting a workpiece, a control device for performing a moving operation according to a force, and the like can be attached to the distal end portion 58 of the robot 50. The control device has, for example, a handle that can be gripped by the operator 60 and a control stick, and can include buttons and the like for teaching. When the force sensor is attached to the tip portion 58 of the robot 50, a tool or a control device may be attached to the force sensor attached to the robot 50, or a force sensor may be attached to the tool attached to the robot 50, You may attach a control device to that point. When a force is applied to the distal end portion 58 of the robot 50, a force may be applied to a tool attached to the force sensor without using the control device, or to a control device attached to the force sensor. A force may be applied.
When the operator moves the robot 50 by applying a force to the tool or the control device attached to the force sensor, the force measuring unit 21 is based on the force detected by the force sensor. The net force applied by the operator to 58 is measured. Here, when a device that combines a force sensor and a steering device is attached to the tool attached to the tip 58 of the robot 50, the influence of the object attached to the force sensor on the force sensor due to gravity or inertial force is reduced. In addition, the error in obtaining the net force is also reduced.
Further, the robot 50 can be attached to the tool using a mechanism or the like configured using a magnet, a spring, or the like so that a device combining a force sensor and a steering device can be easily attached and detached. It is possible to attach a device for detecting the force only when the is moved. As a result, the apparatus can be removed when teaching operation is not required, or can be used in another robot system as necessary.
FIG. 2 is a diagram functionally showing the configuration of the robot control apparatus 10 according to the first embodiment of the present invention. As illustrated, the robot control apparatus 10 includes a force measurement unit 21, an operation force calculation unit 22, an operation command unit 23, an operation axis setting unit 24, a storage unit 25, an input unit 71, and a display output. Part 72.
The force measuring unit 21 measures the net force that the operator acts on the tip 58 of the robot 50. At this time, the force measuring unit 21 detects the force or the inertial force (Coriolis force, gyro effect) of an object such as a tool or a steering device attached to the force sensor or a gripped work with respect to the force detected by the force sensor. The net force applied by the operator to the distal end portion 58 of the robot 50 is measured by compensating for the influence exerted by the robot on the tip 58 of the robot 50 as necessary. Compensation of the influence of gravity and inertial force exerted by an object attached to the force sensor can be performed by a known method. For example, before an operator applies a force to an object attached to a force sensor, the mass and the center of gravity are calculated, and the calculated mass and center of gravity of the object and the movement operation of the robot are referred to. For example, it can be calculated by a technique disclosed in Japanese Patent Application Laid-Open No. 2008-142810.
The operating force calculation unit 22 uses each force of the robot 50 based on the force measured by the force measurement unit 21 and acting on the distal end portion 58 of the robot 50 including the force translational direction component and / or the force moment component. The operating force for moving the axis position is calculated. For example, when the axis to be moved is a rotation axis as in the present embodiment, the operation force calculation unit 22 calculates the operation force as follows.
The operating force is calculated based on the net force (measured value) actually measured on the tip portion 58 of the robot 50 measured by the force measuring unit 21. Alternatively, based on the force acting on the distal end portion 58 of the robot 50, a virtual force that is a force virtually acting on the axis to be moved may be calculated as the operation force. Specifically, when a translational force acting on the tip 58 of the robot 50 is projected on a plane perpendicular to the axis of rotation of the axis with respect to the axis to be moved, either positive or negative with respect to the axis. In other words, based on the direction of the rotation direction, in other words, based on the direction of the translational force acting around the rotation center line of the shaft, the direction of the operating force for moving the shaft is determined, and the force measuring unit 21 The magnitude of the force in the translational direction measured by, or the magnitude of the projected force, or the magnitude of the component orthogonal to the position vector of the projected force from the rotation center line to the point of application of the projected force Based on the above, obtain the magnitude of the operating force.
Further, based on the force acting on the tip portion 58 of the robot 50 measured by the force measurement unit 21, the moment of the force around the rotation center line is calculated for the axis to be moved to obtain the operation force. Also good. Alternatively, when the moment of the force around the rotation center line is calculated with respect to the axis to be moved based on the force acting on the distal end portion 58 of the robot 50 measured by the force measuring unit 21, The moment may be calculated to improve the operability by devising a vector or position vector calculation method, and the operation force may be obtained.
Further, the direction of the operating force for moving the shaft is determined based on the positive / negative of the moment of the force acting around the rotation center line of the shaft, and the magnitude of the force measured by the force measuring unit 21 is determined. Based on the above, an appropriate magnitude of the operation force according to the operation may be obtained. It should be noted that the direction of the operating force only needs to determine the forward direction or the reverse direction, such as a direction or a positive / negative sign, so that the moving direction of the axis to be moved can be determined. Further, in order to improve the operability of the robot when moving in accordance with the force, it is preferable to adjust the operating force in consideration of the moving direction, moving speed, etc. of the operating robot as necessary. In the present embodiment, the case of the rotating shaft has been described. However, when the operating shaft is a linear motion shaft, the component in the translational direction of the axial force is calculated.
The operation axis setting unit 24 operates an operation axis among the plurality of axes (that is, the J1 axis 51, the J2 axis 52, the J3 axis 53, the J4 axis 54, the J5 axis 55, and the J6 axis 56). And the moving direction of the operation axis according to the direction of the force is set. In addition, when there are a plurality of operation axes, the setting of whether or not to move the operation axis according to the status of the movement operation, in other words, which axis among the axes as the operation axis is moved and which axis is Set whether to prevent movement.
In selecting the axis to be moved according to the force (that is, the operation axis), the axis may be set based on an input from the operator, or may be set based on the current position of each axis of the robot 50. . The movement direction of the operation axis corresponding to the direction of force may be set based on a preset value, or the position of each axis of the robot 50 during the movement operation, or the tip 58 of the robot 50. You may make it set according to the force which acts on. When there are multiple operation axes, when setting whether to move relative to the operation axis according to the status of the move operation (in other words, when selecting the axis to be moved among the operation axes) The setting is made based on the direction of the force measured by the force measuring unit 21 with respect to the operation axis, the positional relationship between the operation axis and the distal end portion 58 of the robot 50, a predetermined priority order, and the like.
The operation command unit 23 is based on the setting of the operation axis setting unit 24 and the force measured by the force measurement unit 21 so as to move the robot 50 based on the force applied to the tip 58 of the robot 50. Based on the operation force calculated by the operation force calculator 22, an operation command for moving the position of the operation axis is output. When there are a plurality of operation axes, the operation command unit 23 determines which of the operation axes is to be moved according to the state of the movement operation based on the setting of the operation axis setting unit 24, and sets the axis. The operation command to move is output. When the operation command is generated based on the operation force, the moving speed with respect to the operation force may be determined by a force control gain. Further, it is preferable to adjust the moving speed as necessary, such as decreasing the response to the operating force or accelerating / decelerating the speed according to the situation at the time of operation.
In the storage unit 25, parameters necessary for the force measurement unit 21 to measure force, parameters necessary for the operation force calculation unit 22 to calculate operation force, and operation axis setting unit 24 to set operation axes. Parameters and calculation results necessary for various calculations, such as parameters necessary for setting and setting results, are stored.
The input unit 71 is connected to the robot control device 10 and receives data transferred from an input device that can input various settings, and settings input to other control devices and computers via the network. 10 receives and processes data input to the robot controller 10 such as data transferred to the controller 10.
The display output unit 72 includes information necessary for inputting various settings, the operation axis set by the operation axis setting unit 24, the movement direction according to the direction of the force of the operation axis, and whether to move the operation axis. Display output processing such as setting of.
Next, an example of processing by the robot control apparatus 10 according to the first embodiment of the present invention when the operator moves the robot 50 by applying a force to the distal end portion 58 of the robot 50, see FIG. To explain. FIG. 3 is a flowchart illustrating an example of a process performed by the robot control apparatus 10.
When the process of moving the robot 50 is started and an external force is applied to the tip portion 58 of the robot 50 by the operator 60 or the like, the force measuring unit 21 measures the force acting on the tip portion 58 (step S1). Next, the operation axis setting unit 24 sets an operation axis to be moved according to the force, and sets the movement direction of the operation axis according to the direction of the force (step S2).
Next, based on the force acting on the tip 58 of the robot 50 measured by the force measurement unit 21, the operation force calculation unit 22 performs the operation axis position with respect to the operation axis set by the operation axis setting unit 24. An operation force for moving the operation axis is calculated (step S3), and the operation axis setting unit 24 determines whether or not there are two or more operation axes (step S4). This determination is for determining whether or not to set the axis to be moved and the axis not to be moved among the axes to be moved according to the force according to the state of the movement operation when there are a plurality of operation axes. It is. If there are two or more operation axes, the process proceeds to step S6. If there are less than two operation axes, the process proceeds to step S5.
When there is only one operation axis, the operation axis setting unit 24 sets the operation axis as a “move axis” (in other words, not an “move axis”) (step S5). On the other hand, when there are two or more operation axes, the operation axis setting unit 24 sets whether to move each of the axes as the operation axes according to the state of the moving operation (step S6). ). That is, when there are a plurality of operation axes that are to be moved according to the force, in order to move the desired axis, in step S6, the axis to be moved and the axis that is not to be moved are set according to the state of the movement operation. Next, the operation command unit 23 generates and outputs an operation command for moving the position of the operation axis based on the operation force calculated by the operation force calculation unit 22 and the setting of the operation axis setting unit 24 (step S7). .
Here, some examples of the process in which the operation force calculation unit 22 calculates the operation force for moving the position of the operation axis in step S3 will be further described. In addition, these calculation processes may differ for every operation axis | shaft, and may differ suitably according to the condition of movement operation.
FIG. 4 is a diagram showing that the force measuring unit 21 measures that the force Fs is acting on the distal end portion 58 of the robot 50. The force Fs includes a force translation direction component F and a force moment component M, and is composed of force translation direction components Fx, Fy, Fz and force moment components Mx, My, Mz. When setting the coordinate system for the operation axis, the coordinate system is set so that the rotation center line of the operation axis coincides with the Z axis of the coordinate system. By converting the force Fs measured by the force measuring unit 21 into a force on the coordinate system set on the operation axis, the moment of the force around the Z axis in the calculated force can be obtained as the operation force.
Alternatively, the operating force may be obtained as follows. FIG. 5 shows an operation force based on the force Fs measured by the force measurement unit 21 when any one of a plurality of axes constituting the robot 50 shown in FIG. FIG. 6 is a diagram for explaining a method by which a calculation unit 22 calculates an operation force with respect to an operation shaft 31. First, a coordinate system including the point P1, the X axis Ax, the Y axis Ay, and the Z axis Az axis is set for the operation axis 31. In this setting, the point P1 representing the position of the operation axis 31 on the reference coordinate system is the origin of the coordinate system, the Z axis Az coincides with the rotation center line of the operation axis 31, and the plane formed by the X axis Ax and the Y axis Ay. C is performed so that C is a plane orthogonal to the rotation center line of the operation shaft. The plane C is a plane (XY plane) formed by the X axis Ax and the Y axis Ay in the coordinate system set on the operation axis 31. Point P2 is a point obtained by projecting the force measurement point onto the plane C, which is the origin of the force measurement coordinate system when measuring the force applied to the tip 58 of the robot 50. Here, the force moment M21 obtained by coordinate-converting the force M (Mx, My, Mz) of the moment component of the force Fs measured by the force measurement unit 21 into the force moment on the plane C, or the operation The moment of force around the Z axis Az when converted to the moment of force on the coordinate system set for the axis 31 is defined as a moment of force M21.
The position vector Pv is a position vector on the plane C from the point P1 to the point P2. The magnitude of the position vector Pv is the shortest distance between the rotation center line of the operation axis and the force measurement point. The force Fp is a force acting around the rotation center line of the operation axis on the plane C based on the force Fs (Fx, Fy, Fz) of the component in the translation direction of the force Fs measured by the force measuring unit 21. The calculated force in the translation direction. Alternatively, the force in the translation direction obtained by projecting the force F of the component in the translation direction onto the plane C may be used as the force Fp. Further, when the force Fp is obtained based on the force F of the component in the translation direction of the force Fs, based on the direction in which the force F of the component in the translation direction of the force Fs acts and the rotation operation in the direction toward the predetermined direction. Alternatively, the force Fp may be calculated. Note that, when the force Fp on the plane C is obtained, fluctuations in the magnitude of the force Fp obtained by the force F due to fluctuations in the direction of the force F of the component in the translation direction of the force Fs may be reduced. .
Next, the operating force is obtained based on the moment of force M11 or the moment of force M21 obtained by calculating the outer product of the force Fp on the plane C and the position vector Pv. Specifically, when the magnitude of the position vector Pv is smaller than a predetermined threshold, the force moment M21 is used as the operating force. On the other hand, when the magnitude of the position vector Pv is greater than or equal to a predetermined threshold, a moment of force is calculated from the cross product calculation of the position vector Pv and the force Fp, and the calculated moment of force M11 is used as the operating force. Alternatively, a force moment obtained by adding the calculated force moment M11 and the force moment M21 may be used as the operation force. Alternatively, a coefficient may be applied to each of the force moment M11 and the force moment M21, that is, the weights may be added in consideration of each influence. At that time, these coefficients may be adjusted based on the magnitude of the position vector Pv, the magnitude of the force Fp, and the like.
When it is desired to eliminate the influence of the force M of the moment component of the force Fs measured by the force measuring unit 21, or when it is desired to move only with the force in the translational direction of the force Fs, the force moment M21 is not considered. It is preferable that only the moment of force M11 is used as the operating force. Even if the magnitude of the force Fp is the same, the magnitude of the calculated force moment M11 varies depending on the magnitude of the position vector Pv. For this reason, unlike the force moment M21, the magnitude of the force moment M11 changes due to the movement of the position of the tip 58 of the robot 50, and the operating force fluctuates. For this reason, when the magnitude of the position vector Pv is greater than or equal to a predetermined threshold and the magnitude of the force Fp is smaller than the predetermined threshold, it may be preferable to use only the force moment M21 as the operating force.
As mentioned above, it calculated | required based on the force Fp on the plane C calculated | required based on the force F of the component of the translation direction of the force Fs which the force measurement part 21 measured, and the position vector Pv on the plane C. Based on the moment M21 of the force obtained from the moment M11 of the force and / or the moment component of the force component of the force Fs measured by the force measuring unit 21, a force that virtually acts on the operation shaft 31 is obtained. Sought as operating force. When obtaining the moment M11 of the force, the force Fp is obtained so that the magnitude of the force Fp does not vary as much as possible due to the variation in the direction of the force F as described above, or the direction of the force Fp is representative according to the direction. By calculating the force in the translation direction that is the direction, or by obtaining a representative position vector according to the magnitude of the position vector Pv, and determining the moment of force, the fluctuation of the operating force during the moving operation can be reduced. The robot 50 can be moved stably and the operability can be improved. At this time, when changing the direction and magnitude of the force Fp, the magnitude of the position vector Pv, etc., the change is made so that the required operating force does not change suddenly, that is, changes smoothly. It is preferable to do this.
Further, as another calculation method of the operating force, it may be calculated as follows. By calculating the angle formed by the position vector Pv and the force Fp, it is determined whether the sign of the moment of force determined by the position vector Pv and the force Fp is positive or negative, and the position of the operation shaft 31 is set in the positive direction. The sign of the operating force is determined by deciding whether to move in the negative direction or the negative direction. The magnitude of the operating force is the magnitude of the force Fp, the magnitude of the force F as a component in the translation direction of the force Fs, or the like. In this way, the operation force may be obtained. At this time, when the position vector Pv is small, a force moment M21 is used. In addition, a value obtained by multiplying the value obtained by calculating the sign and magnitude in this way by a coefficient, and a value obtained by multiplying the force moment M21 by another coefficient so that the moment M21 of the force is also considered. The combined virtual force may be used as the operation force.
Next, the process of the operation axis setting unit 24 of the robot control apparatus 10 according to the first embodiment of the present invention will be described in more detail. The operation axis setting unit 24 sets, as an operation axis, an axis to be moved according to force among a plurality of axes, and further sets a moving direction of the operation axis according to the direction of force. Also, whether to move the axis as the operation axis is set according to the status of the moving operation. In step S6, the operation axis setting unit 24 determines whether or not to move the operation axis with respect to the operation axis based on the direction of the force measured by the force measuring unit 21 with respect to the operation axis in accordance with the state of the moving operation. Set. The operation axis setting unit 24 determines and sets whether to move the axis as the operation axis according to the state of the moving operation. These methods will be described with reference to FIGS.
The operation axis setting unit 24 sets an axis as an operation axis among a plurality of axes constituting the robot 50 based on input, setting, the position of the current axis of the robot 50, and the like. Here, it is assumed that two or more axes are set as the operation axes. When there are two or more operation axes, depending on the direction of the force applied to the tip 58 of the robot 50, when the operation axes are moved based on the operation force calculated by the operation force calculation unit 22, a plurality of axes move simultaneously. There are things to do. At this time, in order to move a desired axis or an axis satisfying a predetermined condition from among a plurality of operation axes, and not to move an axis satisfying another predetermined condition, depending on the situation of the moving operation, Based on the direction of the force measured by the force measuring unit 21 with respect to the operation axis, an operation axis to be moved and an operation axis not to be moved are set. The “operation axis to be moved” means an operation axis that is allowed to move according to a force, and the “operation axis that is not moved” means an operation axis that is not moved even when a force is applied. .
Based on the direction of the force measured by the force measurement unit 21 with respect to the operation axis, a method for determining whether or not to move the operation axis is based on the direction of the force measured by the force measurement unit 21 with respect to the operation axis. It is possible to determine whether or not to move by comparing the originally obtained value with a predetermined threshold or by comparing it with the value obtained in the same way for other operation axes. Any method can be used.
Hereinafter, an example of a determination method for setting whether to move the operation axis based on the direction of the force measured by the force measurement unit 21 will be described. Whether or not the plurality of operation axes are moved by the operation force when a force is applied to the distal end portion 58 of the robot 50 is determined by the operation force calculation unit 22 according to the magnitude of each operation force of the operation axis. Can be determined based on whether or not is equal to or greater than a predetermined threshold. As a result, when it is determined that the plurality of operation axes are moved by the force applied to the tip portion 58 of the robot 50, the operation axes that are not moved may be determined.
When determining whether or not to move the operation axis, there are a plurality of axes that satisfy the conditions at the same time, and when further restricting or selecting the axes to be moved, It is preferable to further select an axis to be moved by combining a plurality of determination methods so as not to contradict each other by using another operation axis selection method or the like at the same time. In addition, when determining whether or not to use the operation axis to be moved, a predetermined priority is set for determination for all the operation axes, and the determination is made in order according to the priority for all the operation axes. I will do it. At this time, if there is an axis to be moved, only the operation axis is moved, and the operation axis to be moved is searched in order for all the operation axes until the operation axis to be moved is found. Also good.
As described above, FIG. 4 shows that the force measuring unit 21 measures that the force Fs is acting on the tip 58 of the robot 50. As an example of a method for determining whether or not to move the operation axis, the force F of the component in the translation direction of the force Fs acting on the distal end portion 58 of the robot 50 measured by the force measurement unit 21 and the operation axis Among the plurality of operation axes, the operation axis that is closest to the rotation center line is determined as the operation axis that is not moved. Alternatively, an operation axis that is within a predetermined threshold from an angle when the force F and the rotation center line of the operation axis are parallel may be determined as an operation axis that is not moved.
As another method, as shown in FIG. 5, the angle formed by the force Fp on the plane C obtained when calculating the operating force on the operating shaft 31 and the position vector Pv is predetermined from the angle when orthogonal. You may determine with the operation axis which is the range within a threshold value as the operation axis to move. Alternatively, an operation axis close to the angle at which the angle formed by the force Fp on the plane C and the position vector Pv is the most orthogonal among the plurality of operation axes may be determined as the operation axis to be moved.
Another method is described with reference to FIG. FIG. 6 is a diagram for explaining another method for determining whether or not to move the operation axis based on the direction of the force Fp. In FIG. 6, a straight line Lw, a straight line Lv, a range Ra, and a range Rb, which will be described later, are added to FIG. The straight line Lw extends on the plane C and is a straight line including the points P1 and P2. The straight line Lv extends on the plane C and is a straight line orthogonal to the straight line Lw at the point P2. Based on the angle formed by the force Fp and the straight line Lw, the direction of the force Fp is within a predetermined range Ra on the side where the point P1 exists with respect to the straight line Lv on the plane C, or outside the range Ra (point P1 In the predetermined range Rb on the non-existing side), and determines whether or not the operation axis is to be moved according to the direction of the force Fp. However, when the angle formed by the force Fp with the position vector Pv and the straight line Lw is within a predetermined threshold from the angle when the force Fp is parallel to the position vector Pv, the axis is set so as not to move. In other words, when the direction of the force Fp is close to the direction of the position vector Pv or the straight line Lw, the operation axis is set as an axis that is not moved. Using this method, for a certain operation axis, when the force Fp obtained for a certain operation axis is within the predetermined range Ra, the operation axis is moved. When the force Fp obtained for the axis is within the predetermined range Rb, it may be determined that the operation axis is to be moved.
Another method is described with reference to FIG. FIG. 7 shows whether or not the operation axis to be moved is based on the angle formed by the direction of the force F as the component of the translation direction of the force Fs measured by the force measurement unit 21 and the rotation center line of the operation axis. It is a figure for demonstrating another method of determining. Note that, as with others, description of symbols having the same meaning is omitted. In FIG. 7, the force F on the coordinate system set to the operating shaft 31 is shown so that the rotation center line of a certain operating shaft 31 and the Z-axis Az may correspond. The force F acts at the force measurement point P3. In addition, an axis obtained by translating the Z axis Az so that the point P3 exists thereon is defined as an axis Aza.
At this time, an angle Da formed by the direction of the force F with respect to the axis Aza is calculated, and it is determined whether the angle Da is within 0 to 90 degrees or within 90 to 180 degrees. Based on the range in which the angle Da exists, it is determined whether or not the operation axis is to be moved. Based on the range in which this angle Da exists, the direction of the force F with respect to the rotation center line of the operation shaft is obtained, and it is determined whether or not the operation shaft is to be moved. Using this method, for an operation axis, an operation axis is moved when the angle Da obtained for the operation axis is within 0 to 90 degrees, and for another operation axis, the operation axis When the angle Da obtained for the axis is within 90 to 180 degrees, it may be determined as the operation axis to be moved.
By using a plurality of methods as described above singly or in combination, based on the direction of the force measured by the force measuring unit 21 with respect to the operation axis, depending on the situation of the moving operation, It can be determined whether or not to move.
A method of generating and outputting an operation command for moving the position of the operation axis by the operation command unit 23 in step S7 will be further described. The operation command unit 23 is based on the setting among the plurality of axes set by the operation axis setting unit 24 as the operation axis, the movement direction according to the direction of the force, and whether to move the axis. Thus, the operation axis to be moved is moved based on the operation force obtained by the operation force calculation unit 22 and the movement direction according to the direction of the force set by the operation axis setting unit 24. At this time, the operation command unit 23 determines the operation axis based on the sign of the operation force and the direction of the force set by the operation axis setting unit 24, here, the movement direction of the operation axis according to the sign of the operation force. A target movement direction (rotation direction in the case of a rotation axis) is determined, and a target movement speed of the operation axis is calculated based on the magnitude of the operation force.
At this time, it is preferable to calculate the target moving speed of the operating axis by force control obtained by multiplying the magnitude of the operating force by a force control gain that determines the response of movement to the force. Further, the force control gain may be changed according to the shortest distance from the rotation center line of the operation axis to the tip portion 58 of the robot 50. Thereby, the responsiveness to the operating force can be changed depending on the position of the tip portion 58 of the robot 50, and the moving speed of the robot 50 can be adjusted for each region in the space.
Further, when the shortest distance from the rotation center line of the operation shaft to the tip portion 58 of the robot 50 is relatively large and small, the speed of the operation shaft is moved at the same angular velocity with respect to the same operation force. When the shortest distance is large, the speed of the distal end portion 58 of the robot 50 in the translation direction is faster than when the shortest distance is small. In some cases, the angular velocity of the operation axis is not made the same for the same operation force, but when the position of the tip portion 58 of the robot 50 is far from the operation axis, the tip portion 58 of the robot 50 is moved away from the operation axis. It is safer and slower to operate the robot 50 than when the position is close.
For this reason, the force control gain may be reduced based on the shortest distance as the shortest distance from the rotation center line of the operation shaft to the tip 58 of the robot 50 increases. As a result, even when the magnitude of the operation force is the same, the speed of the tip portion 58 of the robot 50 can be reduced as the tip portion 58 of the robot 50 is further away from the operation axis, improving safety and improving operability. It becomes possible to improve.
Further, in the case where the target speed of the operation axis is changed according to the magnitude of the operation force, even if the magnitude of the operation force is the same, as the tip portion 58 of the robot 50 becomes farther from the operation axis, the tip of the robot 50 The tangential speed of the part 58 will become large. Therefore, the operation command unit 23 is moved based on the operation force obtained as described above with respect to the operation axis and the movement direction corresponding to the direction of the force set by the operation axis setting unit 24. The target moving direction and the target tangential speed of the front end portion 58 of the robot 50 around the rotation center line of the operation axis are obtained based on the operating force, and the target of the front end portion 58 of the robot 50 is determined. Based on the moving direction and the target tangential speed, the target moving direction and the target moving speed of the operating axis may be obtained to move the operating axis.
Thus, when the magnitude of the operation force is the same, the tangential speed of the tip portion 58 of the robot 50 can be made the same regardless of the position of the tip portion 58 of the robot 50. In this case, as the distal end portion 58 of the robot 50 moves away from the operation axis, the rotation speed of the operation axis decreases even if the operation force is the same. Further, in order to obtain such an effect, when calculating the target moving speed of the operation axis based on the magnitude of the operation force, when calculating the operation force, from the rotation center line of the operation axis Alternatively, a division operation may be performed with the shortest distance to the tip portion 58 of the robot 50. Further, the movement direction and tangential speed of the tip 58 of the robot 50 around the rotation center line of the operation axis are obtained based on the operation force, and then the target movement direction and target movement speed of the operation axis are obtained. At this time, the target tangent of the tip portion 58 of the robot 50 is obtained by force control that obtains the amount of movement of the tip portion 58 of the robot 50 by multiplying the magnitude of the operating force by a force control gain that determines the responsiveness of movement to the force. The speed may be calculated. As described above, the operation command unit 23 sets the operation axis among the plurality of axes set by the operation axis setting unit 24, the movement direction according to the direction of the force, and whether to move the axis. Based on the setting, the operation axis to be moved is moved in accordance with the operation force obtained by the operation force calculation unit 22 and the movement direction according to the direction of the force set by the operation axis setting unit 24. Generate and output a command.
Next, a robot control apparatus according to the second embodiment of the present invention will be described. The robot control device according to the second embodiment is different from the robot control device 10 according to the first embodiment of the present invention in that the operation axis setting unit 24 in step S6 moves the operation axis with respect to the operation axis. Since only the setting method when setting is different and the others are the same as those of the first embodiment, description of the same parts as those of the first embodiment in FIG. 2 and FIG. 3 will be omitted. That is, in the second embodiment, the setting method used by the operation axis setting unit 24 is to set whether or not to move the operation axis according to the state of the moving operation. The technical idea is common to the first embodiment.
In the second embodiment of the present invention, the operation axis setting unit 24 sets, as an operation axis, an axis to be moved according to a force among a plurality of axes, and further, the movement direction of the operation axis according to the direction of the force Set. Also, whether to move the axis as the operation axis is set according to the status of the moving operation. In step S6, the operation axis setting unit 24 according to the second embodiment moves each operation axis based on the positional relationship between the operation axis and the tip portion 58 of the robot 50 according to the state of the movement operation. Set whether or not.
The function of the operation axis setting unit 24 of the robot control apparatus according to the second embodiment will be described in more detail. First, the operation axis setting unit 24 sets an axis as an operation axis among a plurality of axes constituting the robot 50 based on input, setting, and the current position of the robot 50. Here, it is assumed that two or more axes are set as the operation axes.
When there are two or more operation axes, depending on the direction of the force applied to the tip 58 of the robot 50, if the operation axes are moved based on the operation force calculated by the operation force calculation unit 22, a plurality of axes are moved simultaneously. I might let you. At this time, in order to move a desired axis or an axis satisfying a predetermined condition among a plurality of operation axes, and in order not to move an axis satisfying another predetermined condition, according to the situation of the moving operation, an operating shaft, based on the positional relationship between the tip portion 58 of the robot 50, to set the operating shaft that moves, an operation shaft is not moved. The “operation axis to be moved” means an operation axis that is allowed to move according to a force, and the “operation axis that is not moved” means an operation axis that is not moved even when a force is applied. .
Based on the positional relationship between the operation axis and the distal end portion 58 of the robot 50, a method for determining whether or not the operation axis is to be moved is based on the positional relationship between the operation axis and the distal end portion 58 of the robot 50. It is possible to determine whether or not to move by comparing the value obtained in step 1 with a predetermined threshold value or comparing it with the value obtained in the same way for other operation axes. Any method may be used.
Whether or not the plurality of operation axes are moved by the operation force when a force is applied to the distal end portion 58 of the robot 50 is determined by the operation force calculation unit 22 according to the magnitude of each operation force of the operation axis. It can be determined by whether or not the length is greater than or equal to a predetermined threshold. Accordingly, when it is determined that a plurality of operation axes move due to the force applied to the tip portion 58 of the robot 50, an operation axis that is not moved may be determined.
An example of a determination method for setting whether or not to move based on the positional relationship between the operation axis and the distal end portion 58 of the robot 50 will be described with reference to FIG. FIG. 8 shows a coordinate system set for a certain operation axis as described above. First, a coordinate system including a point P1, an X axis Ax, a Y axis Ay, and a Z axis Az axis is set for a certain operation axis. In this setting, the point P1 representing the position of the operation axis on the reference coordinate system is the origin of the coordinate system, the Z axis Az coincides with the rotation center line of the operation axis, and the plane C formed by the X axis Ax and the Y axis Ay is It is performed so as to be a plane orthogonal to the rotation center line of the operation shaft. The point P3 is a point representing the position of the distal end portion 58 of the robot 50, and is a force measurement point here. The plane C is a plane (XY plane) formed by the X axis Ax and the Y axis Ay in the coordinate system set to a certain operation axis.
In an example of a method for determining whether or not to move the operation axis, a distance Ea between the point P1 at the origin of the operation axis and a point P3 representing the position of the tip portion 58 of the robot 50 is obtained for each operation axis. The operation axis having the smallest distance Ea among the plurality of operation axes is determined as the operation axis for moving. Alternatively, an operation axis whose distance Ea is within a predetermined threshold may be determined as an operation axis to be moved.
In another method, the shortest distance Eb between the rotation center line of the operation axis and the point P3 representing the position of the tip portion 58 of the robot 50 is obtained for each operation axis, and the operation axis having the smallest distance Eb among the plurality of operation axes. Is determined as the operation axis to be moved. Alternatively, an operation axis whose distance Eb is within a predetermined threshold may be determined as an axis to be moved.
In another method, the shortest distance Ec between the plane C perpendicular to the rotation axis of the operation axis and including the point P1 of the origin of the operation axis and the point P3 representing the position of the tip end 58 of the robot 50 is set for each axis. The obtained operation axis is determined as the operation axis that moves the operation axis having the smallest distance Ec among the plurality of operation axes. Alternatively, an operation axis whose distance Ec is within a predetermined threshold may be determined as an operation axis to be moved.
In yet another method, whether or not to move the robot 50 may be determined according to which region on the coordinate system set as the operation axis the tip portion 58 of the robot 50 exists. For example, an area on the coordinate system is divided into a first quadrant (the position in the X-axis Ax direction is positive, the position in the Y-axis Ay direction is positive, and the position in the Z-axis Az direction is positive), and the second quadrant (in the X-axis Ax direction). Position is negative, position in Y axis Ay direction is positive, position in Z axis Az direction is positive), third quadrant (position in X axis Ax direction is negative, position in Y axis Ay direction is negative, position in Z axis Az direction Position is positive), quadrant 4 (position in the X-axis Ax direction is positive, position in the Y-axis Ay direction is negative, position in the Z-axis Az direction is positive), quadrant 5 (position in the X-axis Ax direction is positive, Position in the Y-axis Ay direction is positive, position in the Z-axis Az direction is negative), quadrant 6 (position in the X-axis Ax direction is negative, position in the Y-axis Ay direction is positive, position in the Z-axis Az direction is negative) , 7th quadrant (X axis Ax direction position is negative, Y axis Ay direction position is negative, Z axis Az direction position is negative), 8th quadrant (X axis Ax direction position is positive, Y axis Ay direction Position of Negative, when the position of the Z-axis Az direction is divided into eight negatively), so as to correspond whether to move for each quadrant. At this time, it is determined whether or not the operation axis to be moved is determined depending on in which quadrant the point P3 representing the position of the tip portion 58 of the robot 50 exists. At this time, an area restriction may be further set in each quadrant. For example, the region restriction may be set based on whether or not the position in each direction of the X axis Ax, the Y axis Ay, and the Z axis Az is within a predetermined range. You may perform based on whether Eb, distance Ec, etc. exist in a predetermined range. As described above, when the point P3 representing the position of the tip portion 58 of the robot 50 exists in a certain predetermined area in a certain quadrant on the coordinate system set as the operation axis, the operation axis is determined to be moved.
By using a plurality of determination methods as described above alone or in combination, the operation axis and the operation axis can be determined based on the positional relationship between the operation axis and the distal end portion 58 of the robot 50 according to the situation of the moving operation. Thus, it can be determined whether or not to move.
Next, a robot control apparatus according to the third embodiment of the present invention will be described. The robot control device according to the third embodiment is different from the robot control device 10 according to the first embodiment of the present invention in that the operation axis setting unit 24 in step S6 moves the operation axis with respect to the operation axis. Since only the setting method when setting is different and the others are the same as those of the first embodiment, description of the same parts as those of the first embodiment in FIG. 2 and FIG. 3 will be omitted. That is, in the second embodiment, the setting method used by the operation axis setting unit 24 is to set whether or not to move the operation axis according to the state of the moving operation. The technical idea is common to the first embodiment.
In the third embodiment of the present invention, the operation axis setting unit 24 sets, as an operation axis, an axis to be moved according to a force among a plurality of axes, and further, the movement direction of the operation axis according to the direction of the force Set. Also, whether to move the axis as the operation axis is set according to the status of the moving operation. In the operation axis setting unit 24 according to the third embodiment, the direction of the force measured by the force measurement unit 21 with respect to the operation axis, the operation axis, and the distal end portion 58 of the robot 50 in step S6 according to the state of the moving operation. Whether or not to move with respect to the operation axis is set based on at least one of the positional relationships and a predetermined priority.
The function of the operation axis setting unit 24 of the robot control apparatus according to the third embodiment will be described in more detail. First, the operation axis setting unit 24 sets an axis as an operation axis among a plurality of axes constituting the robot 50 based on input, setting, and the current position of the robot 50. Here, it is assumed that two or more axes are set as the operation axes. At this time, in order to move a desired axis or an axis satisfying a predetermined condition among a plurality of operation axes, and in order not to move an axis satisfying another predetermined condition, according to the situation of the moving operation, An operation axis to be moved and an operation axis not to be moved are set for the operation axis . The “operation axis to be moved” means an operation axis that is allowed to move according to a force, and the “operation axis that is not moved” means an operation axis that is not moved even when a force is applied. .
At this time, as a method of determining whether or not the operation axis is the operation axis to be moved, based on the direction of the force measured by the force measuring unit 21 as described in the first or second embodiment. At least one of a determination method and a determination method based on the positional relationship between the operation axis and the tip portion 58 of the robot 50, and a method of determining whether or not to move based on a predetermined priority. Use.
The method of determining based on the direction of the force measured by the force measuring unit 21 with respect to the operation axis and the method of determining based on the positional relationship between the operation axis and the tip portion 58 of the robot 50 are appropriately combined, Whether or not to move the operation axis can be determined by a combination of a plurality of conditions. For example, when it is determined that any one of a plurality of conditions is moved for a certain operation axis, it is determined that the operation axis is moved. Alternatively, when it is determined that the movement is performed under all of the plurality of conditions, it may be determined that the operation axis is moved. Alternatively, for a plurality of conditions, a score is determined when it is determined to move under each condition, and the score is moved when the total score when determined under a plurality of conditions is equal to or greater than a predetermined value. The operation axis may be determined.
Further, when the operation axis to be moved cannot be determined only by the determination method based on the direction of the force measured by the force measuring unit 21 with respect to the operation axis, or the positional relationship between the operation axis and the tip portion 58 of the robot 50. If the operation axis to be moved cannot be determined only by the determination method based on the method, it can be determined using another method. At this time, the determination may be made in consideration of the direction of the force measured by the force measuring unit 21 with respect to the operation axis, the positional relationship between the operation axis and the distal end portion 58 of the robot 50, and a predetermined priority order. For example, when there are a plurality of operation axes that are determined to be moved by the above-described determination of whether or not to move, and when it is desired to select an operation axis to be moved with respect to those operation axes, for each operation axis Select with priorities. As described above, the determination is made using a plurality of conditions such as a force direction condition, a positional relationship condition, and a predetermined priority condition, so that the operation axis is moved or is not moved. In such a determination, it is possible to move a desired operation axis more or to move an unnecessary axis.
Next, a robot control apparatus according to the fourth embodiment of the present invention will be described. The robot control apparatus according to the fourth embodiment differs from the robot control apparatus 10 according to the first embodiment of the present invention in steps S4 to S6 from the flowchart shown in FIG. It differs in that it is omitted. In the fourth embodiment, the operation axis setting unit 24 illustrated in FIG. 2 does not set whether to move the operation axis, and makes it easier to move the desired operation axis. Accordingly, two operation axes are selected and set from among a plurality of axes constituting the robot 50.
In the robot control apparatus according to the first to third embodiments of the present invention, when there are a plurality of operation axes, whether or not to move the axis set as the operation axis according to the situation of the moving operation. Set the desired axis and move the desired axis. On the other hand, the robot control apparatus according to the fourth embodiment of the present invention has two axes in advance so that it is easier to move the desired axis when there are a plurality of operation axes. Set as the operation axis. That is, it is possible to selectively move a desired axis during a moving operation by using appropriate two axes as operation axes from a plurality of axes constituting the robot 50. The fourth embodiment is the first to third aspects of the present invention in that a method of selectively moving a desired axis is realized when there are a plurality of operation axes that are axes to be moved according to force. The technical idea is the same as that of the robot control apparatus according to the embodiment.
As shown in FIG. 9, when the process of moving the robot 50 is started, when an external force is applied to the distal end portion 58 of the robot 50 by the operator 60 or the like, the force measuring unit 21 measures the force acting on the distal end portion 58. (Step S1). The operation axis setting unit 24 sets an operation axis to be moved according to the force, and sets the movement direction of the operation axis according to the direction of the force (step S2).
Based on the force acting on the tip 58 of the robot 50 measured by the force measurement unit 21, the operation force calculation unit 22 moves the position of the operation axis with respect to the operation axis set by the operation axis setting unit 24. The operation force for making it calculate is calculated (step S3). The operation command unit 23 generates and outputs an operation command for moving the position of the operation axis based on the operation force calculated by the operation force calculation unit 22 and the setting of the operation axis setting unit 24 (step S7).
Processing of the operation axis setting unit 24 of the robot control apparatus according to the fourth embodiment will be further described. In step S2, the operation axis setting unit 24 sets, as an operation axis, an axis to be moved according to force among a plurality of axes, and further sets a moving direction of the operation axis according to the direction of the force. At this time, the operation axis setting unit 24 sets, as the operation axes, two rotation axes whose rotation center lines are orthogonal to each other regardless of the positions of the plurality of axes among the plurality of axes constituting the robot 50.
As described above, the tip end portion 58 of the robot 50 is obtained by using, as operation axes, two rotation axes whose rotation center lines are orthogonal to each other regardless of the positions of the plurality of axes constituting the robot 50. When the direction of the force to be applied is set to an appropriate direction, the operation axis can be moved independently, and the desired axis can be moved according to the force. That is, when it is desired to move only one desired operation axis with respect to the two operation axes set in this way, the distal end portion 58 of the robot 50 is moved in a direction parallel to the rotation center line of the other operation axis. By applying a force, it is possible to move only one desired operation axis.
An example of such an axis setting method will be described with reference to FIG. Here, the operation force calculation unit 22 is based on the force acting around the rotation center line of the operation shaft, as described in relation to the robot control device 10 according to the first embodiment of the present invention. The operating force shall be calculated. The moving direction of the operating shaft according to the direction of force is the same as the direction in which the operating force acts.
In the case of a robot 50 configured with axes as shown in FIG. 1, for example, a J1 axis 51 and a J2 axis 52 can be set as two operation axes. These axes are two rotation axes in which the rotation center lines of the rotation axes are orthogonal regardless of the positions of the plurality of axes constituting the robot 50 (the same applies to the two axes described later). In this case, if a translational force in a direction parallel to the rotation center line of the J2 axis 52 is applied to the tip 58 of the robot 50, a force acts on the J1 axis 51 around the rotation center line. In order to do this, it can be moved based on the operating force calculated by the operating force calculator 22. On the other hand, the J2 axis 52 cannot be moved because no force acts around the rotation center line. Further, if a translational force in a direction parallel to the rotation center line of the J1 axis 51 is applied to the distal end portion 58 of the robot 50, a force is applied to the J2 axis 52 around the rotation center line. Therefore, it can be moved based on the operating force calculated by the operating force calculator 22. On the other hand, the J1 axis 51 cannot be moved because no force acts around the rotation center line.
On the other hand, you may set the J3 axis | shaft 53 and the J4 axis | shaft 54 as two operation axes. Also in this case, when only one operation axis is desired to be moved, it is possible to move only one desired operation axis by applying a force in a direction parallel to the rotation center line of the other operation axis. . Alternatively, the J4 axis 54 and the J5 axis 55 may be set as the two operation axes. Also in this case, when only one operation axis is desired to be moved, it is possible to move only one desired operation axis by applying a force in a direction parallel to the rotation center line of the other operation axis. . Alternatively, the two operation axes may be set to the J5 axis 55 and the J6 axis 56. Also in this case, when only one operation axis is desired to be moved, it is possible to move only one desired operation axis by applying a force in a direction parallel to the rotation center line of the other operation axis. .
As described above, of the plurality of axes constituting the robot 50, two rotation axes whose rotation center lines are orthogonal to each other regardless of the positions of the plurality of axes are set as operation axes, and the distal end portion 58 of the robot 50 is set. When the force to be applied to is set to an appropriate direction, only the desired operation axis can be moved with respect to the two operation axes. Accordingly, the axis to be moved can be selected without switching and setting the axis to be moved by using a teaching operation device or the like, or two axes depending on the position of the axis of the robot 50 and the direction of the force to be applied. Can be moved simultaneously.
In the robot control device according to the fifth embodiment of the present invention, in the fourth embodiment, the operation axis setting unit 24 further determines the force measured by the force measurement unit 21 for the operation axis according to the state of the movement operation. Whether or not to move with respect to the operation axis is set based on at least one of the direction, the positional relationship between the operation axis and the distal end portion 58 of the robot 50, and a predetermined priority order.
The robot control device according to the fifth embodiment is different from the robot control device according to the fourth embodiment in the flowchart shown in FIG. The difference is that a step (step S6) for setting whether or not to move the operation axis is added. However, the robot control device according to the fifth embodiment also realizes a method of selectively moving a desired operation axis when there are a plurality of operation axes, as in the robot control devices according to other embodiments. It is an object.
In the operation of moving the operation axis by the robot control apparatus according to the fourth embodiment of the present invention, when only one operation axis is desired to be moved, a force is applied in a direction parallel to the rotation center line of the other operation axis. Thus, it is possible to move only one desired operation axis. At this time, depending on the situation of the moving operation, there is a case where it is difficult to apply a force in a direction parallel to the rotation center line of the other operation shaft. In addition, even if a force is applied in a direction parallel to the rotation center line of the other operation shaft, the magnitude of the operation force is zero or the operation force does not act. There are cases where it is difficult to move. In the fifth embodiment, even in such a situation, in order to be able to move a desired operation axis, the force that acts on the tip 58 of the robot 50 is the rotation center line of the other operation axis. Even if the directions are not parallel, one operation axis can be moved.
In step S <b> 2 shown in FIG. 10, the operation axis setting unit 24 sets an axis to be moved according to a force among a plurality of axes as an operation axis, and further sets a movement direction of the operation axis according to the direction of the force. . At this time, the operation axis setting unit 24 does not depend on the position of a plurality of axes among the plurality of axes constituting the robot 50 based on the input from the operator or the current position of each axis of the robot 50. Two rotation axes whose rotation center lines are orthogonal to each other are set as operation axes.
In step S6 shown in FIG. 10, the operation axis setting unit 24 sets whether or not to move the operation axis according to the state of the movement operation. More specifically, the operation axis setting unit 24 determines the direction of the force measured by the force measurement unit 21 with respect to the operation axis and the positional relationship between the operation axis and the tip 58 of the robot 50 according to the state of the moving operation. Whether or not to move the operation axis is set based on at least one of the predetermined priority relationships.
At this time, as a method of determining whether or not the operation axis is the operation axis to be moved, a method of determining based on the direction of the force measured by the force measuring unit 21 with respect to the operation axis, the operation axis and the robot 50 At least one of the determination method based on the positional relationship with the distal end portion 58 and the determination method based on a predetermined priority order is used. Since there are two operation axes, when both of the operation axes move due to the operation force calculated based on the force applied to the tip 58 of the robot 50, A predetermined priority order may be set, and one of them may be moved based on the priority order.
Similarly to the method in which the operation axis setting unit 24 determines and sets whether to move the axis as the operation axis according to the state of the movement operation, for the two operation axes, You may make it determine and determine whether to move.
In the sixth embodiment of the present invention, as shown in FIG. 11, the robot system 11 includes a teaching operation device 70 that inputs various settings and the like to the robot control device 10, and the operation axis setting unit 24 includes a teaching operation. An operation axis is set based on the input from the device 70, and the teaching operation device 70 selects and inputs from the combinations of the axes that can be set as the operation axis among the axes that can be set as the operation axis.
As shown in FIG. 11, in the robot system 11 including the robot 50 controlled by the robot control device 10, a teaching operation device 70 that inputs various settings to the robot control device 10 is connected to the robot control device 10. Yes. Further, when inputting various settings, the display device 70 is placed at an appropriate location on the robot 50, for example, as shown in FIG. 12, so that the operator 60 does not have to hold the display device 70. The robot 50 may be configured so that it can be mounted on the tip 58 of the robot 50 or on a link connecting the axes constituting the robot 50. In addition, the teaching operation device 70 may be a device having a display function for displaying and outputting various states, and further, inputs various settings, etc., and performs input operations for moving and stopping the robot 50. A device that can display various states related to the moving operation of the robot 50 may be used.
The operation axis setting unit 24 sets an operation axis based on an input from the teaching operation device 70. Here, it is assumed that the operation axes can be set as two operation axes whose rotation center lines are orthogonal to each other regardless of the positions of the plurality of axes constituting the robot 50.
13A and 13B show display examples in which an axis that can be set as the operation axis is displayed as an option, and the operation axis can be input (set) from the option. For example, “J1-J2” indicates that the operation axes are the J1 axis and the J2 axis, and the combination of the operation axes depending on the color of the mark (displayed on the left side of the character in the illustrated example) associated therewith. Whether or not is selected. It is preferred that when one combination is selected, the other combination is deselected.
For example, in the display example of FIG. 13B, “J4-J5” representing the combination of the J4 axis and the J5 axis is included in the options as the two operation axes. However, in the display example of FIG. Therefore, “J4-J5” cannot be selected. In this way, combinations of operation axes that are not preferable to be set can be prevented from being set. In addition, among the plurality of axes constituting the robot 50, when two rotation axes whose rotation center lines are orthogonal to each other regardless of the positions of the plurality of axes should be used as operation axes, which combination of axes is such When it is difficult to determine whether the combination is possible or the selection is possible, it is possible to easily set the operation axis by such an input method.
In the seventh embodiment of the present invention, as shown in FIG. 12, the robot system 11 includes a teaching operation device 70 for inputting various settings and the like to the robot control device 10, and the operation axis setting unit 24 includes a teaching operation. An operation axis is set based on an input from the apparatus 70, and the teaching operation apparatus 70 indicates an axis that can be selected as an operation axis among a plurality of axes constituting the robot 50, and based on the selected axis. In addition to the selected axis, it is possible to indicate whether the operation axis can be selected simultaneously with the selected axis and / or is not selectable simultaneously with the selected axis.
In the seventh embodiment, as shown in FIGS. 14A and 14B, the teaching operation device 70 indicates an axis that can be selected as an operation axis among a plurality of axes constituting the robot 50. Based on the selected axis, it indicates whether or not selection is possible in an axis other than the selected axis. At this time, with respect to the axis displayed as an option, it is possible to select it by changing the color, shape, size, etc. of the mark, button, character, etc., adding a box or line, etc. And / or indicates not selectable. As the operation axis, two rotation axes whose rotation center lines are orthogonal to each other can be set as the operation axes, regardless of the positions of the plurality of axes constituting the robot 50.
FIG. 14A shows an axis that can be selected as the operation axis among the axes constituting the robot 50, and the J4 axis is already selected as the operation axis. At this time, in order to show that the J3 axis or the J5 axis can be combined with the J4 axis as the operation axis, in the display part of the J3 axis and the J5 axis, display of the mark color, the mark shape, etc. on the left side of the character Has been shown to change. In addition, the display of the mark on the left side of the character is changed so that the other J1 axis, J2 axis, and J6 axis cannot be combined with the J4 axis as the operation axis.
On the other hand, in FIG. 14B, when the J5 axis is already selected as the operation axis, the J4 axis and the J6 axis can be combined with the J5 axis as the operation axes at the same time as the operation axes. For the other axes, the mark on the left side of the character is changed to indicate that they cannot be combined at the same time.
As described above, when one of the plurality of axes constituting the robot 50 is set as the operation axis, it is visually displayed which other axis can or cannot be selected simultaneously. . As a result, of the plurality of axes constituting the robot 50, which axis of rotation should be selected as the operation axis, two rotation axes whose rotation axis is orthogonal to each other regardless of the positions of the plurality of axes. When it is difficult to determine whether the combination is possible, the operation axis can be easily set.
In the eighth embodiment of the present invention, in the first, second, third and fifth embodiments, the robot system 11 further includes a display device such as the teaching operation device 70, and the display device is The setting condition when the operation axis setting unit 24 sets whether or not to move the operation axis is displayed. The display device may be a device different from the teaching operation device 70. In addition, the display device may be a device that performs only display, unlike the teaching operation device 70 that enables input and display. By displaying the setting condition when the operation axis setting unit 24 sets whether or not to move the operation axis on the display device, it is possible to move the desired axis by performing the moving operation. Therefore, it is possible to improve the operability during the moving operation.
In the ninth embodiment of the present invention, in the sixth and seventh embodiments, when the teaching operation device is a rotation axis, based on the position of the current axis of the robot 50, When the shortest distance from a rotation center line of a certain axis to a tip end portion 58 of the robot 50 among a plurality of axes constituting the robot 50 is equal to or less than a predetermined threshold value, the tip of the robot 50 is located near the rotation center line of the axis. It can be shown that the part 58 exists, or that it is not possible to set the setting of the axis including the axis as the operation axis.
When the shortest distance from the rotation center line of a certain operation axis to the position of the tip portion 58 of the robot 50 is smaller than a predetermined threshold depending on the position of the axis of the robot 50, a force in the translation direction is applied to the tip portion 58 of the robot 50. In this case, since the operation force for the operation axis cannot be obtained appropriately, the operation axis may not be moved as intended. In order to notify the operator of this and possibly avoid it, it is indicated that the tip 58 of the robot 50 exists near the rotation center line of the axis, or the axis including the axis as the operation axis Indicates that the setting is not configurable.
In the sixth and seventh embodiments of the present invention, when setting the operation axis from the teaching operation device 70, the robot 50 is selected from the rotation center line of a certain operation axis in the selection of the operation axis and the combination of the operation axes. An option including an axis whose shortest distance to the position of the distal end portion 58 is smaller than a predetermined threshold value may not be selected. Further, when setting an operation axis from the teaching operation device 70, when an axis is selected as the operation axis, it is preferable to indicate that such an axis cannot be selected among axes other than the selected axis. As a result, the operation axis can be set appropriately, and operability can be improved.
Although the present invention has been described with reference to particular embodiments selected for illustration, it will be apparent to those skilled in the art that numerous modifications can be made without departing from the basic concept and scope of the invention. It is. That is, other forms conceivable within the scope of the technical idea of the present invention are also included in the scope of the present invention.
DESCRIPTION OF SYMBOLS 10 Robot control apparatus 11 Robot system 21 Force measurement part 22 Operation force calculation part 23 Operation command part 24 Operation axis setting part 25 Storage part 31 Operation axis 50 Robot 51 J1 axis 52 J2 axis 53 J3 axis 54 J4 axis 55 J5 axis 56 J6 Shaft 57 Flange part 58 Tip part 59 Base 60 Operator 70 Teaching operation device 71 Input part 72 Display output part
In a robot control apparatus for moving the robot based on a force applied to a robot composed of a plurality of axes,
A force measurement unit that measures the force applied to the tip of the robot;
Based on the force measured by the force measurement unit, an operation force calculation unit that calculates an operation force for moving the position of each axis of the robot;
An operation command unit that outputs a command to move the robot;
Among the plurality of axes, one or two or more axes that are moved according to the force when the movement according to the force is permitted are set as the operation axes, and further according to the direction of the force An operation axis setting unit for setting the movement direction of the operation axis,
The operation axis setting unit sets the operation axis as an operation axis permitted to move according to force when the operation axis is one, and when the operation axis is two or more Depending on the situation of the moving operation, it is permitted to move according to the force with respect to each of the axes as the operation axis based on the direction of the force measured by the force measuring unit with respect to the operation axis. Set the operation axis that will not be moved even if force is applied ,
The robot control device, wherein the operation command unit outputs an operation command for moving the position of the operation axis based on the setting of the operation axis setting unit and the operation force calculated by the operation force calculation unit.
The operation axis setting unit sets the operation axis as an operation axis permitted to move according to force when the operation axis is one, and when the operation axis is two or more Depending on the situation of the moving operation, it was permitted to move according to the force with respect to each of the axes as the operation axis based on the positional relationship between the operation axis and the tip of the robot . Set either the operation axis or the operation axis that does not move even if force is applied .
The operation axis setting unit sets the operation axis as an operation axis permitted to move according to force when the operation axis is one, and when the operation axis is two or more Depending on the situation of the moving operation, at least one of the direction of the force measured by the force measuring unit with respect to the operation axis and the positional relationship between the operation axis and the tip of the robot, and a predetermined priority Based on the above, for each of the axes as the operation axis, either an operation axis allowed to move according to force or an operation axis that does not move even when a force is applied. Set,
In a robot control device for moving the robot based on a force applied to a robot composed of a plurality of axes including two or more rotation axes,
An operation axis setting unit that sets an axis to be moved according to a force among the plurality of axes as an operation axis, and further sets a movement direction of the operation axis according to the direction of the force, and
The operation axis setting unit sets, as the operation axes, two rotation axes in which rotation center lines of the rotation axes are orthogonal regardless of positions of the plurality of axes among the plurality of axes.
Of the plurality of axes, when the movement according to the force is permitted, the axis to be moved according to the force is set as the operation axis, and the movement direction of the operation axis is set according to the direction of the force. An operation axis setting unit for
The operation axis setting unit sets, as the operation axes, two rotation axes in which the rotation center lines of the rotation axes are orthogonal, regardless of the positions of the plurality of axes, according to the state of the movement operation. Te, wherein the force measuring unit the direction of the force measured for the operating shaft, the positional relationship between the tip portion of said operating shaft the robot, and, among the predetermined priority, to at least Tsuomoto, the operation For each of the axes, set either the operation axis allowed to move according to the force or the operation axis that does not move even if force is applied ,
The robot control device , wherein the operation command unit outputs an operation command for moving the position of the operation axis based on the setting of the operation axis setting unit and the operation force calculated by the operation force calculation unit .
A robot system including the robot control device according to claim 1 and the robot.
The robot system includes a teaching operation device that inputs settings to the robot control device,
The operation axis setting unit sets the operation axis based on an input from the teaching operation device,
The robot system according to claim 6, wherein the teaching operation device selects and inputs from a combination of axes that can be set as operation axes among the axes that can be set as the operation axes.
The teaching operation device indicates an axis that can be selected as the operation axis among the plurality of axes, and the axis other than the selected axis is selected as the operation axis based on the selected axis. The robot system according to claim 6, wherein at least one of being selectable simultaneously with the selected axis and not being simultaneously selectable with the selected axis is displayed.
A robot system including the robot control device according to any one of claims 1 to 3 and 5 and the robot,
The robot system includes a display device,
In the display device, the operation axis setting unit sets whether the operation axis is permitted to move in accordance with force or is not moved even when force is applied. Robot system that displays the setting conditions when.
In the teaching operation device, based on the current axis position of the robot, the shortest distance from the rotation center line of the rotation axis of the plurality of axes to the tip of the robot is a predetermined threshold value or less. Sometimes, it indicates that the tip of the robot exists in the vicinity of the rotation center line of the rotation axis, or indicates that setting of an axis including the axis cannot be set as the operation axis. The robot system according to 7 or 8.
JP2014082732A 2014-04-14 2014-04-14 Robot control device and robot system for robots that move according to force Active JP5893666B2 (en)
JP2014082732A JP5893666B2 (en) 2014-04-14 2014-04-14 Robot control device and robot system for robots that move according to force
CN201510152002.7A CN104972463B (en) 2014-04-14 2015-04-01 The robot controller of the robot according to power action and robot system
DE102015004484.2A DE102015004484B4 (en) 2014-04-14 2015-04-07 Robot controller and robot system for moving a robot in response to a force
US14/684,930 US9566707B2 (en) 2014-04-14 2015-04-13 Robot controller and robot system for moving robot in response to force
JP2015202537A JP2015202537A (en) 2015-11-16
JP5893666B2 true JP5893666B2 (en) 2016-03-23
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JP2014082732A Active JP5893666B2 (en) 2014-04-14 2014-04-14 Robot control device and robot system for robots that move according to force
US (1) US9566707B2 (en)
JP (1) JP5893666B2 (en)
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DE (1) DE102015004484B4 (en)
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