Abstract: A controller includes a parameter setting unit that invalidates first mechanism error parameters. The controller includes a measurement control unit that drives a robot with a plurality of orientations at a plurality of positions by using second mechanism error parameters other than the first mechanism error parameters and measures the actual measurement position of the robot by a three-dimensional measuring device. The controller includes a parameter calculation unit that calculates the first mechanism error parameter based on the actual measurement position of the robot and the rotation position of a robot drive motor. The controller includes a correction unit that changes the first mechanism error parameter invalidated by the parameter setting unit to the first mechanism error parameter calculated by the parameter calculation unit.

Abstract: A device, a method and a program, by which a weight and a horizontal position of a gravity center of a load attached to a movable part of a robot can be estimated by a simple configuration. The device has: two torque sensors configured to detect a first torque applied to a first axis of a robot, and a second torque applied to a second axis of the robot; and a calculation section configured to calculate a weight and a horizontal position of a gravity center of a workpiece, by using two detection values of the torque sensors in one posture in which a hand attached to a movable part of the robot holds the workpiece.

Abstract: An interference region setting apparatus capable of setting an interference region in a coordinate system of a mobile robot, with an inexpensive configuration and a little effort. The apparatus has: a shape model storage section configured to store a shape, a position, and an orientation of an obstruction present in a work region of the mobile robot as an obstruction shape model, in a reference coordinate system; a position and orientation calculation section configured to analyze an image, captured by the image capturing apparatus, of a shape feature in a fixed position within the work region, and calculate a position and orientation of the reference coordinate system represented in a robot coordinate system; and an interference region setting section configured to set an interference region based on the position and orientation of the reference coordinate system converted into the robot coordinate system and the stored obstruction shape model.

Abstract: A robot system including a robot, a control unit, a sensor to detect a magnitude of force applied to the robot, a determination unit configured to determine, based on the magnitude of the detected force, whether there is application of an external force different from a load acting on the robot during a task performed by the robot, and a storage unit to store the magnitude of force detected by the sensor when the control unit executes at least one operation command when there is no application of the external force, in association with the operation command, where the determination unit determines, when the operation command is executed by the control unit, presence or absence of the external force based on the magnitude of force stored in the storage unit in association with the operation command and the magnitude of force detected by the sensor.

Abstract: A conveying system includes an external force calculation unit which calculates an external force applied to a robot based on a force or torque applied to the robot detected by a force detection unit, and workpiece parameters changed in accordance with the holding state of a workpiece, and a robot stopping unit which stops the robot when the calculated external force exceeds a threshold. The conveying system further includes a relative movement unit which moves the held workpiece and a workpiece support relative to each other. By the relative movement unit, the workpiece and workpiece support are moved relative to each other without changing the position and posture of the robot.

Abstract: A device, a method and a program, by which a weight and/or a position of a gravity center of a load attached to a movable part of a robot can be estimated by a simple configuration. The device has a torque sensor configured to detect a torque applied to an axis for driving the movable part of the robot, and a calculation section configured to calculate the weight of the article, by using: a first torque applied to the axis, when the article attached to the movable part is positioned at a first position and represents a first posture; a second torque applied to the axis, when the article attached to the movable part is positioned at a second position different from the first position and represents the first posture; the first position; and the second position.

Abstract: A robot controller and a robot control method, by which a human can be prevented from being sandwiched between a collaborative robot and a workpiece conveyed by a conveyor. The robot controller controls the robot configured to perform a predetermined operation for the workpiece conveyed by a convey section moving in a convey direction. The robot controller has: a receive section configured to receive a signal representing that an abnormality of the robot is detected or contact against the robot is detected; and a motion control section configured to control a motion of robot so that, after the receive section receives the signal, a minimum distance between a movable section of the robot and the workpiece is not less than a predetermined safe distance.

Abstract: A robot controller and a robot control method, capable of preventing an operator from being sandwiched between a robot and a workpiece, when a conveyor for conveying the workpiece is stopped. The robot controller is configured to output a robot stop command when a conveyor starts the stop operation thereof. The robot stop command includes at least one of: a first stop command by which, when a movable section of the robot is positioned anterior to the workpiece, the movable section is moved at a higher velocity than the conveyor, and then is stopped after traveling a distance longer than a coasting distance of the conveyor; and a second stop command by which, when the movable section is positioned posterior to the workpiece, the movable section is moved at a lower velocity than the conveyor, and then is stopped after traveling a distance shorter than the coasting distance.

Abstract: A redox flow battery includes a battery cell to which a positive electrolyte and a negative electrolyte are supplied, and an electrical quantity measurement system configured to measure a quantity of electricity when a predetermined amount of electrolyte is discharged, for at least one of the positive electrolyte and the negative electrolyte.

Abstract: There is provided a robot control device enabling a robot to carry various types of objects without exceeding an allowable weight thereof. The robot control device for controlling the robot for carrying an object in cooperation with a person includes a force acquisition part configured to acquire force applied from the object to the robot when the object is lifted, a comparison part configured to compare a force component in a gravity direction of the force acquired by the force acquisition part with a first threshold value predetermined with respect to the force component, and a stop command part configured to stop the robot when the force component is greater than the first threshold value.

Abstract: An object is to prevent automatic operation from being started while a monitoring function is in a disabled state. The present invention provides a robot system includes a robot, a control unit controlling the robot, and an operation monitoring unit having a monitoring function for monitoring contact or the possibility of contact between the robot and a peripheral object. The operation monitoring unit has a monitoring changeover switch that switches between enabling and disabling of the monitoring function. The control unit has a mode changeover switch that switches between a manual operation mode, and an automatic operation mode. The control unit performs control so as to inhibit the operation of the robot in a state in which the monitoring function is disabled and in which the operation mode is set to the automatic operation mode.

Abstract: A robot system including a robot, a control unit, a sensor to detect a magnitude of force applied to the robot, a determination unit configured to determine, based on the magnitude of the detected force, whether there is application of an external force different from a load acting on the robot during a task performed by the robot, and a storage unit to store the magnitude of force detected by the sensor when the control unit executes at least one operation command when there is no application of the external force, in association with the operation command, where the determination unit determines, when the operation command is executed by the control unit, presence or absence of the external force based on the magnitude of force stored in the storage unit in association with the operation command and the magnitude of force detected by the sensor.

Abstract: An interference region setting apparatus capable of setting an interference region in a coordinate system of a mobile robot, with an inexpensive configuration and a little effort. The apparatus has: a shape model storage section configured to store a shape, a position, and an orientation of an obstruction present in a work region of the mobile robot as an obstruction shape model, in a reference coordinate system; a position and orientation calculation section configured to analyze an image, captured by the image capturing apparatus, of a shape feature in a fixed position within the work region, and calculate a position and orientation of the reference coordinate system represented in a robot coordinate system; and an interference region setting section configured to set an interference region based on the position and orientation of the reference coordinate system converted into the robot coordinate system and the stored obstruction shape model.

Abstract: A robot system and a maintenance method, capable of easily managing maintenance information and/or predicting a failure, with respect to each module constituting a robot. The robot system includes a plurality of robots each having an arm configured as an exchangeable module. The robot system also includes: a robot information storing section configured to store robot information including at least one of an operational status, failure prediction information, failure diagnosis information and maintenance history information of each module; a reading section configured to read a unique identifiable information of the module; a robot information referring section configured to refer to the stored robot information with respect to the module corresponding to the read unique identifiable information; and a robot information outputting section configured to output the robot information with respect to each module of the robot.

Abstract: A human-collaborative robot, by which the robot is unlikely to be accidentally operated despite the intention of the human, even if a relatively simple action pattern is determined as a command to the robot. When an external force by a human is applied to the robot, the force is detected by a force sensor. The robot is configured to be stopped when the detected external force exceeds a predetermined threshold. In order to restart the stopped motion of the robot, the human purposely applies the external force to the robot. When a judging section judges that the external force is applied to a specified portion the robot based on a predetermined action pattern, a commanding section commands the robot so that the robot performs a motion which is previously associated with the pattern.

Abstract: A human cooperation robot system includes: an external force detecting unit that detects an external force acting on a robot; a retreat operation commanding unit that commands a retreat operation for causing the robot to be moved in a direction such that the external force is decreased when the external force detected by the external force detecting unit is greater than a first threshold value; and an external force variation monitoring unit that stops the retreat operation when a variation width of the external force at a predetermined time after the retreat operation is commanded by the retreat operation commanding unit is smaller than a second threshold value.

Abstract: A multi-joint robot using substantially one sensor, capable of performing a proper repositioning motion of an arm of the robot. The controller has a disturbance torque estimating part which estimates a first disturbance torque and a second disturbance torque, by calculating a torque generated by a mass and motion of the robot and subtracting the calculated torque from the first torque and the second torque detected by a torque detecting part. The controller has a repositioning commanding part which generates a motion command for rotating each axis so that the disturbance torque is reduced, when the disturbance torque exceeds a torque threshold. Since the axis is repositioned based on the motion command, a portion of the robot pushed by the operator is repositioned, whereby the operator can easily perform one's work without using a teaching board, etc.

Abstract: A robot control apparatus comprises a contact detection unit which judges whether or not a robot is in contact with an object other than the robot, and an operation direction monitor unit which detects an operation direction of the robot after the robot comes in contact with the object and monitors operation of the robot. After the robot comes in contact with the object, the operation direction monitor unit permits operation of the robot being within a permissible range and inhibits operation of the robot falling outside the permissible range.

Abstract: An object is to prevent automatic operation from being started while a monitoring function is in a disabled state. The present invention provides a robot system includes a robot, a control unit controlling the robot, and an operation monitoring unit having a monitoring function for monitoring contact or the possibility of contact between the robot and a peripheral object. The operation monitoring unit has a monitoring changeover switch that switches between enabling and disabling of the monitoring function. The control unit has a mode changeover switch that switches between a manual operation mode, and an automatic operation mode. The control unit performs control so as to inhibit the operation of the robot in a state in which the monitoring function is disabled and in which the operation mode is set to the automatic operation mode.

Abstract: A human cooperation robot system includes: an external force detecting unit that detects an external force acting on a robot; a retreat operation commanding unit that commands a retreat operation for causing the robot to be moved in a direction such that the external force is decreased when the external force detected by the external force detecting unit is larger than a first threshold value; a position acquiring unit that a current position of the robot; and a retreat operation stopping unit that stops the retreat operation when the current position of the robot acquired by the position acquiring unit departs from a retreat area.