Abstract: A method of handling safety in a working area of an industrial system, wherein at least one machine is arranged to operate in the working area, at least one manually operable safety input device is provided in the working area, and one or more of the at least one machine and the at least one safety input device is movable to different positions in the working area, the method including continuously or repeatedly determining whether one or more of the at least one the machine is in proximity to one or more of the at least one safety input device; and associating at least one machine with the at least one safety input device upon determining that one or more of the at least one machine is in proximity to one or more of the at least one safety input device, such that the at least one associated machine can be brought to a safe state by means of the at least one safety input device.

Abstract: A method of handling safety in a working area of an industrial system, wherein at least one machine is arranged to operate in the working area, at least one manually operable safety input device is provided in the working area, and one or more of the at least one machine and the at least one safety input device is movable to different positions in the working area, the method including continuously or repeatedly determining whether one or more of the at least one the machine is in proximity to one or more of the at least one safety input device; and associating at least one machine with the at least one safety input device upon determining that one or more of the at least one machine is in proximity to one or more of the at least one safety input device, such that the at least one associated machine can be brought to a safe state by means of the at least one safety input device.

Abstract: An industrial robot device includes a swivel with an attachment mechanism for the attachment of a tool. The attachment mechanism includes at least two different attachment devices for two different kinds of tools. A first attachment device includes a positioning mechanism defining a certain angular position of an attached tool relative to the swivel. A second attachment device is arranged for allowing an arbitrary angular position of an attached tool relative to the swivel. Also contemplated is an industrial robot that is provided with the invented device and to a method for manipulating objects.

Abstract: A pick and place system including at least one input conveyor, at least one output conveyor, at least one pick and place robot and control circuitry. Available picking positions on an input conveyor at which a respective item can be picked are determined as well as available placing positions on an output conveyor at which a respective item can be placed. For the available picking positions and the available placing positions, a respective picking time and placing time is calculated, and the at least one robot is instructed to pick items at the picking positions and place the items at the placing positions in an order determined by the respective picking times and placing times.

Abstract: An industrial robot and an industrial robot transmission system for the transmission of movement to a robot part, including a motor and a gearbox containing a lubricant. The gearbox is provided with an integrated moisture absorbing device including a moisture absorbing material adapted to absorb moisture contained in the gearbox. The invention is also related to a method for preventing the deterioration of a lubricant due to absorption of moisture, inside an industrial robot used in surroundings with high humidity, which is characterized by integrating a moisture absorbing device including a moisture absorbing material in a robot part containing the lubricant.

Abstract: A method for optimizing performance of a robot. At least one experiment is designed including at least two tests. Each test differs from at least one other test in the experiment regarding the location of the task in relation to the robot. The boundaries that are allowable for location of a task are calculated/determined. The effect on optimality for at least one test in the experiment is calculated/determined. The experimental data is fit to an algorithm. The optimal location of the task is calculated/determined.

Abstract: A pick and place system including at least one input conveyor, at least one output conveyor, at least one pick and place robot and control circuitry. Available picking positions on an input conveyor at which a respective item can be picked are determined as well as available placing positions on an output conveyor at which a respective item can be placed. For the available picking positions and the available placing positions, a respective picking time and placing time is calculated, and the at least one robot is instructed to pick items at the picking positions and place the items at the placing positions in an order determined by the respective picking times and placing times.

Abstract: A control system for an industrial robot. The control system includes a memory unit configured to store at least one task program intended for controlling movements of the robot and including movement instructions for controlling the movements of the robot. A program executer is configured to generate instructions based on movement instructions included in the task program and data necessary to be able to carry out the instructions. A path planner is configured to receive the instructions from the program executer and based thereon to plan how the movements of the robot are to be designed to enable the robot to carry out the movement instructions. The control system includes a recording device, with at least one memory unit connected thereto, arranged for the purpose of recording and storing the instructions and the data sent to the path planner from the program executer.

Abstract: An industrial robot device includes a swivel with an attachment mechanism for the attachment of a tool. The attachment mechanism includes at least two different attachment devices for two different kinds of tools. A first attachment device includes a positioning mechanism defining a certain angular position of an attached tool relative to the swivel. A second attachment device is arranged for allowing an arbitrary angular position of an attached tool relative to the swivel. Also contemplated is an industrial robot that is provided with the invented device and to a method for manipulating objects.

Abstract: A method for optimizing performance of a robot. At least one experiment is designed including at least two tests. Each test differs from at least one other test in the experiment regarding the location of the task in relation to the robot. The boundaries that are allowable for location of a task are calculated/determined. The effect on optimality for at least one test in the experiment is calculated/determined. The experimental data is fit to an algorithm. The optimal location of the task is calculated/determined.

Abstract: An industrial robot for movement of an object in space comprising a stationary platform, a movable platform adapted for supporting the object, and a first, a second and a third arm to which the platforms are joined. The first arm comprises a first actuator, a first supporting arm influenced by the first actuator and rotatable around a first axis, and a first linkage. The second arm comprises a second actuator, a second supporting arm influenced by the second actuator and rotatable around a second axis, and a second linkage. The third arm comprises a third actuator, a third supporting arm influenced by the third actuator and rotatable around a third axis, and a third linkage. The second supporting arm is freely mounted around a cross-beam that is arranged at right angles to the second axis.

Abstract: An industrial robot for movement of an object in space comprising a stationary platform, a movable platform adapted for supporting the object, and a first, a second and a third arm to which the platforms are joined. The first arm comprises a first actuator, a first supporting arm influenced by the first actuator and rotatable around a first axis, and a first linkage. The second arm comprises a second actuator, a second supporting arm influenced by the second actuator and rotatable around a second axis, and a second linkage. The third arm comprises a third actuator, a third supporting arm influenced by the third actuator and rotatable around a third axis, and a third linkage. The second supporting arm is freely mounted around a cross-beam that is arranged at right angles to the second axis.