Abstract: A motion teaching apparatus includes a teaching motion detection device, a demonstration tool, and circuitry. A robot includes a leading end to move in a first coordinate system. A teaching motion detection device detects a position of the demonstration tool in a second coordinate system. The circuitry derives a relationship between the first and second coordinate system based on a position of the demonstration tool in the first coordinate system at at least one spot and based on the position of the demonstration tool in the second coordinate system at the at least one spot; obtains a transition of the position of the demonstration tool during the demonstration using the demonstration tool; and generates a motion command to control motion of the leading end of the robot based on the transition and the coordinate system relationship information.

Abstract: The present invention is related to a separating agent for the purification of human insulin, ensuring that human insulin can be recovered in high yield when isolating human insulin from a solution containing human insulin and a specific insulin under specific liquid chromatography separation conditions by using the separating agent.

Abstract: A robot system includes a conveyor, a robot, a speed calculation circuit, and a robot control circuit. The conveyor is configured to convey a workpiece at a conveyance speed. The robot is configured to work on the workpiece while the workpiece is conveyed by the conveyor. The speed calculation circuit is configured to calculate the conveyance speed. The robot control circuit is configured to control a working speed of the robot according to the conveyance speed calculated by the speed calculation circuit.

Abstract: A robot system includes a robot arm, one or more actuators that are provided in the robot arm to drive the robot arm, a sensor unit that detects an external force applied to at least one of the robot arm and the actuators, and a controller that controls an operation of each of the actuators and limits a torque instruction value for each of the actuators on the basis of a detection result of the sensor unit.

Abstract: In a method for adjusting parameters of impedance control, an overshoot amount allowable value is set as an allowable maximum value of an overshoot amount of a time response of a force feedback from a force sensor provided for an end effector of a robot manipulator, and a setting time allowable value is set as an allowable maximum value of a setting time of the time response of the force feedback. A viscosity parameter with which the setting time is shortest is calculated while fixing the inertia parameter. An overshoot amount adjustment value and a setting time adjustment value which are obtained from a result of the calculating of the viscosity parameter are compared with the overshoot amount allowable value and the setting time allowable value, respectively, to determine whether a repeating process is finished or continued.

Abstract: A robot picking system includes a robot that picks up a work in a first stocker accommodating a plurality of works, a control device that controls an operation of the robot, and an image acquiring device that acquires image data including information related to the plurality of works. The control device includes a candidate data generating unit that generates candidate data including information of candidate works that are candidates of a picking-up target using the image data, and a target work selecting unit that selects a target work that is a picking-up target from the candidate works using the candidate data.

Abstract: A robot picking system includes a robot including a gripper that picks up a target work in a first stocker accommodating a plurality of works, a control device that controls an operation of the robot, and an image acquiring device that acquires image data including information related to the target work. The control device includes a trajectory calculating unit that sets a first trajectory including a first zone in which a posture of the gripper is changed and a second zone in which the gripper having the changed posture approaches the target work that is a picking-up target.

Abstract: A method for adjusting a control parameter of a robot comprising (A) inserting a part into a hole where a plurality of sections has been set in a depth direction by a robot, the robot having a force sensor that detects force applied from outside according to impedance control; and (B) setting one of the plurality of sections a target to be updated so as not to make the same section a target to be updated continuously, and lowering a viscosity parameter of the section, wherein the method adjusts the viscosity parameter of each section.

Abstract: A production system includes: a plurality of production robots configured to share and perform processing works on a workpiece; a controller configured to control the processing works by the plurality of production robots; and a conveying member configured to convey the workpiece between the plurality of production robots. The controller is configured to: acquire work-delay information on a first production robot in which a processing work is delayed compared with a predetermined processing time; acquire work-ready information on a second production robot that can substitutively perform the processing work being performed by the first production robot; and convey the workpiece from the first production robot to the second production robot using the conveying member based on a result of cross-checking the work-delay information and the work-ready information.

Abstract: A robot picking system includes a robot that picks up a work in a first stocker accommodating a plurality of works, a control device that controls an operation of the robot, and an image acquiring device that acquires image data including information related to the plurality of works. The control device includes a candidate data generating unit that generates candidate data including information of candidate works that are candidates of a picking-up target using the image data, and a target work selecting unit that selects a target work that is a picking-up target from the candidate works using the candidate data.

Abstract: A manufacturing system includes a first robot cell apparatus including a first manufacturing robot and a first rack to which the first manufacturing robot is fixed, a second robot cell apparatus including a second manufacturing robot and a second rack to which the second manufacturing robot is fixed, the second robot cell apparatus being disposed adjacent to the first robot cell apparatus, and a transport path setter that sets a transport path of a transport robot that performs at least one of receiving a workpiece from the first robot cell apparatus and supplying a workpiece component to the first robot cell apparatus. A space through which the transport robot is movable is provided under each of the first and second racks, and the transport path setter sets the transport path of the transport robot so that the transport path passes through at least one of the spaces.

Abstract: A robot picking system includes a robot including a gripper that picks up a target work in a first stocker accommodating a plurality of works, a control device that controls an operation of the robot, and an image acquiring device that acquires image data including information related to the target work. The control device includes a trajectory calculating unit that sets a first trajectory including a first zone in which a posture of the gripper is changed and a second zone in which the gripper having the changed posture approaches the target work that is a picking-up target.

Abstract: A robot system includes a robot arm, one or more actuators that are provided in the robot arm to drive the robot arm, a sensor unit that detects an external force applied to at least one of the robot arm and the actuators, and a controller that controls an operation of each of the actuators and limits a torque instruction value for each of the actuators on the basis of a detection result of the sensor unit.

Abstract: In a method for adjusting parameters of impedance control, an overshoot amount allowable value is set as an allowable maximum value of an overshoot amount of a time response of a force feedback from a force sensor provided for an end effector of a robot manipulator, and a setting time allowable value is set as an allowable maximum value of a setting time of the time response of the force feedback. A viscosity parameter with which the setting time is shortest is calculated while fixing the inertia parameter. An overshoot amount adjustment value and a setting time adjustment value which are obtained from a result of the calculating of the viscosity parameter are compared with the overshoot amount allowable value and the setting time allowable value, respectively, to determine whether a repeating process is finished or continued.

Abstract: A robot according to an embodiment includes an arm, a strain sensor, one or more actuator, and a sensor fixing jig. The strain sensor includes a piezoelectric body that has a natural frequency higher than a natural frequency of a structural material forming the arm. The one or more actuators are provided in the arm to drive the arm. The sensor fixing jig is provided in a base of the actuator, among the actuators in the arm, closest to a base end of the arm. The strain sensor is provided in the sensor fixing jig.

Abstract: An apparatus has a parameter initial value calculator, a force reference impression part, an evaluation data measurement part, an allowable value setting part, a viscosity parameter calculator, an end determining part, and an inertia parameter adjusting part. The force reference impression part intermittently supplies a force reference to an impedance controller. The evaluation data measurement part measures setting time of time response, an overshoot amount, and the number of vibration times. The allowable value setting part sets allowable values of the overshoot amount and the setting time. The viscosity parameter calculator calculates a viscosity parameter with which the setting time becomes shortest. The end determining part determines the end or continuation of the process by comparing the adjustment values with the allowable values. The inertia parameter calculator adjusts the inertia parameter according to the adjustment values of the overshoot amount and the setting time.

Abstract: First calculation means calculates a TCP velocity error vector Verr when wrist axes performs rotational following movement, second calculation means selects a component, including the sign, of the TCP velocity error vector Verr, third calculation means decomposes the selected velocity error vector into a joint velocity vector ?err, fourth calculation means integrates the joint velocity ?err and calculates a position correction amount vector ?add, and the position correction amount vector ?add is fed back to position control means with torque limits.

Abstract: To provide an automatic machine system for readily and reliably selecting a desired mechanism part from among the automatic machine systems composed of a plurality of mechanism parts and teaching the mechanism part. Each of a plurality of mechanism parts such as robots includes a first communication part. A teaching operation part includes a second communication part with directivity. When the second communication part of the teaching operation part is oriented to the first communication part included in a target mechanism part to select the same, the second communication part transmits selection request information to the first communication part. A controller for controlling the mechanism parts places the target mechanism part in an operable state based on the selection request information thereby operating the target mechanism part with the operation of the worker on the teaching operation part.

Abstract: A robot according to an embodiment includes arm and a strain sensor. The strain sensor includes a piezoelectric body that has a natural frequency higher than a natural frequency of a structural material forming the arm.

Abstract: An apparatus has a parameter initial value calculator, a force reference impression part, an evaluation data measurement part, an allowable value setting part, a viscosity parameter calculator, an end determining part, and an inertia parameter adjusting part. The force reference impression part intermittently supplies a force reference to an impedance controller. The evaluation data measurement part measures setting time of time response, an overshoot amount, and the number of vibration times. The allowable value setting part sets allowable values of the overshoot amount and the setting time. The viscosity parameter calculator calculates a viscosity parameter with which the setting time becomes shortest. The end determining part determines the end or continuation of the process by comparing the adjustment values with the allowable values. The inertia parameter calculator adjusts the inertia parameter according to the adjustment values of the overshoot amount and the setting time.