Abstract: This robot system comprises: a display control unit which controls an image to be displayed in a display region of a display unit; and a reference direction setting unit which sets a reference direction for determining the orientation of an image. On the basis of the axial positions of respective joint shafts of the robot and the reference direction, the display control unit controls the orientation of an image shown on the display unit so as to perform display that represents a prescribed postural relation with respect to the reference direction.

Abstract: This robot system includes a robot that includes torque sensors corresponding to joint axes. The robot system includes a sensor temperature determination unit that determines whether the temperature state of each of the torque sensors is an abnormal or appropriate temperature state on the basis of an output value of a temperature detection unit. The robot system includes an operation command unit that reduces at least one among the speed and the acceleration of a robot drive motor when there is a torque sensor of which the temperature state is an abnormal temperature state and not an appropriate temperature state.

Abstract: An industrial robot system includes: a robot that includes a torque sensor on at least one rotary shaft; and a controller that controls the robot. The controller includes a moment output unit that outputs a value of moment from a posture of the robot or the posture and a motion of the robot, a program storage unit that stores a motion program, a drive control unit that causes each of component parts of the robot to perform a rotating motion around the rotary shaft in accordance with the motion program, and an output calibration unit that associates a torque detection value detected by the torque sensor with the value of moment output from the moment output unit in the rotating motion of each of the component parts around the rotary shaft performed by the drive control unit.

Abstract: A displacement detection type force sensor, having a mechanism for relaxing deformation of a member due to a factor other than an external force. The force sensor has at least one of: a first relaxation part elastically deformable along a plane perpendicular to a first axis, and provided to at least one of a first substrate part, a first connection part, a second substrate part and a second connection part; and a second relaxation part elastically deformable along the first axis, and provided to at least one of the second substrate part, the second connection part, a third substrate part and a third connection part.

Abstract: An industrial robot system includes: a robot that includes a torque sensor on at least one rotary shaft; and a controller that controls the robot. The controller includes a moment output unit that outputs a value of moment from a posture of the robot or the posture and a motion of the robot, a program storage unit that stores a motion program, a drive control unit that causes each of component parts of the robot to perform a rotating motion around the rotary shaft in accordance with the motion program, and an output calibration unit that associates a torque detection value detected by the torque sensor with the value of moment output from the moment output unit in the rotating motion of each of the component parts around the rotary shaft performed by the drive control unit.

Abstract: A displacement detection type force sensor, having a mechanism for relaxing deformation of a member due to a factor other than an external force. The force sensor has at least one of: a first relaxation part elastically deformable along a plane perpendicular to a first axis, and provided to at least one of a first substrate part, a first connection part, a second substrate part and a second connection part; and a second relaxation part elastically deformable along the first axis, and provided to at least one of the second substrate part, the second connection part, a third substrate part and a third connection part.

Abstract: A robot system including a force-controlled pushing device which causes, when a robot is guided and moved, an object provided at a tip end of the robot to be brought into appropriate contact with another object. The robot system includes the robot, the force-controlled pushing device, a robot operation input measuring part, a robot movement command calculating part, a pushing direction setting part, a target pushing force setting part, a force measuring part, and a force-controlled pushing device movement command calculating part. The pushing direction setting part sets a pushing direction of the force-controlled pushing device, based on at least one of: the position/orientation of the first object; a force-controlled pushing device movement command for moving the first object; the position/orientation of the movement mechanism part of the force-controlled pushing device; the position/orientation of the robot; and a robot movement command for moving the robot.

Abstract: A monitoring device capable of properly detecting an object, even when a blind zone may occur for a sensor. The monitoring device has a sensor configured to a predetermined spatial area, and a judging section configured to judge presence or absence of an object within a predetermined monitoring area in the spatial area, based on measurement data obtained by the sensor. The judging section is configured to be previously set as to whether or not, when the sensor detects that the object exists within an intermediate area between the sensor and the monitoring area, the judging section judges that the object exists within the monitoring area, on the grounds of the existence of the object within the intermediate area.

Abstract: A robot system including a force-controlled pushing device which causes, when a robot is guided and moved, an object provided at a tip end of the robot to be brought into appropriate contact with another object. The robot system includes the robot, the force-controlled pushing device, a robot operation input measuring part, a robot movement command calculating part, a pushing direction setting part, a target pushing force setting part, a force measuring part, and a force-controlled pushing device movement command calculating part. The pushing direction setting part sets a pushing direction of the force-controlled pushing device, based on at least one of: the position/orientation of the first object; a force-controlled pushing device movement command for moving the first object; the position/orientation of the movement mechanism part of the force-controlled pushing device; the position/orientation of the robot; and a robot movement command for moving the robot.

Abstract: A system which calculates the relative posture or the relative position and posture between a first object and a second object. This invention provides an object posture calculation system including a first object and a second object contactable at three contact points, a driving unit which brings the first object and the second object into contact with each other, a force measuring unit which measures a force acting between the first object and the second object, and an object posture calculation unit which calculates the relative posture or the relative position and posture between the first object and the second object on the basis of the force measured by the force measuring unit when the first object and the second object come into contact with each other at the three contact points.

Abstract: A robot controller which uses a robot to more stably, more rapidly move a given object and a different object relative to each other to set the given object and the different object in a combined state in which portions of the two objects are in contact and combined with each other. The robot controller includes an unit which measures a force acting between two objects, an unit which sets a direction of translational force control, an unit which sets a translational force control target force, an unit which sets an axis of rotational force control, an unit which calculates a target amount of translational force control direction movement, an unit which calculates a target amount of rotational force control axis rotational movement, an unit which calculates a target amount of rotational movement, and an unit which generates an operation command for the robot.

Abstract: A robot controller and a robot system capable of stably changing the orientation of a front end of a robot by applying a force to the front end, and moving each axis to a desired position. The robot controller for moving the robot based on the force applied to the robot includes a control point specifying part which specifies a control point in relation to the robot, and an operation commanding part which outputs a command so that the robot performs rotational movement about the control point. The robot has a structure constituted by sequentially combining three or more axes including at least three rotation axes, and rotation centerlines of the three rotation axes intersect at an origin of a centerline-intersecting axis, the centerline-intersecting axis corresponding to one of the three rotation axes. The control point specifying part specifies the origin of the centerline-intersecting axis as the control point.

Abstract: An operation command unit of a robot control device includes a first control mode that, when a near-singular configuration determination unit determines that a robot is not near a singular configuration, outputs an operation command for moving a position and/or a posture of the tip of the robot on the basis of an operation force calculated by a first force calculation unit and a second control mode that, when the near-singular configuration determination unit determines that the robot is near the singular configuration, outputs an operation command for moving the position of an operation axis set by an operation axis setting unit on the basis of an operation force calculated by a second force calculation unit and a moving direction set by the operation axis setting unit.

Abstract: A system which calculates the relative posture or the relative position and posture between a first object and a second object. This invention provides an object posture calculation system including a first object and a second object contactable at three contact points, a driving unit which brings the first object and the second object into contact with each other, a force measuring unit which measures a force acting between the first object and the second object, and an object posture calculation unit which calculates the relative posture or the relative position and posture between the first object and the second object on the basis of the force measured by the force measuring unit when the first object and the second object come into contact with each other at the three contact points.

Abstract: A robot controller for easily moving a desired axis of a robot by applying a force to a front end of the robot, and a robot system including the robot controller. The robot controller has: a force measuring part which measures a force applied to the front end; an operation force calculating part which calculates an operation force for moving each axis based on the measured force; an operation commanding part which outputs a command for moving the robot; and an operation axis specifying part which specifies an operation axis to be moved in response to the force, and determines a direction of movement of the operation axis as a function of a direction of the force. When two or more operation axes are specified, the operation axis specifying part determines as to whether or not each operation axis can be moved, depending on a status of the movement operation.

Abstract: A robot control device includes an operation axis setting unit that sets a axis rotationally moved according to an applied force as an operation axis and sets a rotational moving direction of the operation axis; a first operation force acquisition unit that obtains a first virtual force that is virtually applied to the operation axis to assume that the first virtual force is a first operation force; and an operation command unit that outputs an operation command for moving the operation axis set by the operation axis setting unit on the basis of an operation force determined from the first operation force. The operation command unit obtains a target moving direction and a target moving velocity of the operation axis on the basis of the first operation force and the rotational moving direction set by the operation axis setting unit, so as to move the operation axis.

Abstract: A robot controller which uses a robot to more stably, more rapidly move a given object and a different object relative to each other to set the given object and the different object in a combined state in which portions of the two objects are in contact and combined with each other. The robot controller includes an unit which measures a force acting between two objects, an unit which sets a direction of translational force control, an unit which sets a translational force control target force, an unit which sets an axis of rotational force control, an unit which calculates a target amount of translational force control direction movement, an unit which calculates a target amount of rotational force control axis rotational movement, an unit which calculates a target amount of rotational movement, and an unit which generates an operation command for the robot.

Abstract: A control device for controlling a robot which has a tool for holding a workpiece and a force measuring part for measuring a force acting on the tool. The control device includes a calculating part for calculating a center-of-gravity position of the workpiece, based on force data measured by the force measuring part with a plurality of postures of the robot holding the workpiece, a processing part for performing at least one of a process for estimating a holding state of the workpiece, a process for determining a type of the workpiece, and a process for testing a quality of the workpiece, based on the position of the tool and the center-of-gravity position of the workpiece, and an operating command modifying part for modifying an operating command to the robot, based on a result of the process performed by the processing part.

Abstract: An operation command unit of a robot control device includes a first control mode that, when a near-singular configuration determination unit determines that a robot is not near a singular configuration, outputs an operation command for moving a position and/or a posture of the tip of the robot on the basis of an operation force calculated by a first force calculation unit and a second control mode that, when the near-singular configuration determination unit determines that the robot is near the singular configuration, outputs an operation command for moving the position of an operation axis set by an operation axis setting unit on the basis of an operation force calculated by a second force calculation unit and a moving direction set by the operation axis setting unit.

Abstract: A robot controller for easily moving a desired axis of a robot by applying a force to a front end of the robot, and a robot system including the robot controller. The robot controller has: a force measuring part which measures a force applied to the front end; an operation force calculating part which calculates an operation force for moving each axis based on the measured force; an operation commanding part which outputs a command for moving the robot; and an operation axis specifying part which specifies an operation axis to be moved in response to the force, and determines a direction of movement of the operation axis as a function of a direction of the force. When two or more operation axes are specified, the operation axis specifying part determines as to whether or not each operation axis can be moved, depending on a status of the movement operation.