A setting-up arrangement and a method for setting up a mobile automaton includes at least the steps of a) coupling a movable element of the mobile automaton to a movable guide element of a guide device, b) exerting a force on the movable element via the movable guide element by operating the guide device, by which the movable element is moved in a guided manner along a predetermined movement profile via the guide element, c) acquiring a setup dataset characterizing the movement profile and, as a result, setting up the mobile automaton.

An overhead transport vehicle system includes an overhead transport vehicle to convey an object, and a teaching unit to teach transfer of the object by the overhead transport vehicle to a load port on which the object is to be placed. The teaching unit includes a body including a detector to be brought into contact with a positioning pin on the load port to detect a position of the positioning pin, and a flange movable up and down with respect to the body and to be held by a holder to be raised and lowered by an elevator of the overhead transport vehicle.

An overhead transport vehicle system includes an overhead transport vehicle to convey an object, and a teaching unit to teach transfer of the object by the overhead transport vehicle to a load port on which the object is to be placed. The teaching unit includes a body including a detector to be brought into contact with a positioning pin on the load port to detect a position of the positioning pin, and a flange movable up and down with respect to the body and to be held by a holder to be raised and lowered by an elevator of the overhead transport vehicle.

An industrial robot having a manipulator and a robot controller configured to control the motions of the manipulator. The robot controller is configured during lead-through programming of the robot to compare a robot position or a robot orientation (TCP) with at least one virtual position or virtual orientation defined in space, and to actively control the motions of the robot in relation to the at least one virtual position or virtual orientation when the difference between the robot position or robot orientation and the least one virtual position or virtual orientation is smaller than an offset value.

An industrial robot having a manipulator and a robot controller configured to control the motions of the manipulator. The robot controller is configured during lead-through programming of the robot to compare a robot position or a robot orientation (TCP) with at least one virtual position or virtual orientation defined in space, and to actively control the motions of the robot in relation to the at least one virtual position or virtual orientation when the difference between the robot position or robot orientation and the least one virtual position or virtual orientation is smaller than an offset value.

Systems and methods for simultaneously and economically providing high speed and precision robotic operations with operational safety include directly performing training movements of a desired task on a collaborative robot, recording data corresponding to the training movements, and transmitting the recorded data to a conventional robot to cause the conventional robot to autonomously execute the training movements in accordance with the received data.

Systems and methods for simultaneously and economically providing high speed and precision robotic operations with operational safety include directly performing training movements of a desired task on a collaborative robot, recording data corresponding to the training movements, and transmitting the recorded data to a conventional robot to cause the conventional robot to autonomously execute the training movements in accordance with the received data.

A robotic system includes a support structure, a motor mount assembly, first and second parallel chains, a serial translation assembly, a sensor and a control module. The motor mount assembly includes rotary motors, where the rotary motors include a first rotary motor and a second rotary motor. The first and second parallel chains are connected to the movable platform, the rotary motors and the motor mount assembly. The serial translation assembly is connected to the supporting structure and the motor mount assembly and includes a linear actuator and a third rotary motor. The sensor is connected to the movable platform and detects force applied by a human operator on the movable platform and generates a signal indicative of the force applied. The control module controls the rotary motors and the third rotary motor based on the signal to assist the human operator in moving the movable platform.

A robot control device is provided with a camera which images a teaching tool which includes a characteristic area, and a characteristic position detection unit which detects the position of the characteristic area. The robot control device includes a movement instruction generating unit which, when an operator has moved the teaching tool, changes the position and orientation of the robot such that the camera follows the characteristic area. The robot control device includes a calculation unit which, on the basis of the position of the characteristic area, calculates the position and orientation of an auxiliary coordinate system set for the teaching tool. The robot control device includes a setting unit which, on the basis of the position and orientation of the auxiliary coordinate system, sets the position of the teaching point and the orientation of the robot at the teaching point.

A robot control device is provided with a camera which images a teaching tool which includes a characteristic area, and a characteristic position detection unit which detects the position of the characteristic area. The robot control device includes a movement instruction generating unit which, when an operator has moved the teaching tool, changes the position and orientation of the robot such that the camera follows the characteristic area. The robot control device includes a calculation unit which, on the basis of the position of the characteristic area, calculates the position and orientation of an auxiliary coordinate system set for the teaching tool. The robot control device includes a setting unit which, on the basis of the position and orientation of the auxiliary coordinate system, sets the position of the teaching point and the orientation of the robot at the teaching point.