A tool includes a transmission mechanism, a shaft rotatable relative to the transmission mechanism, and a stop mechanism associated with the shaft, the stop mechanism being transitionable between a first state and a second state. In the first state, the shaft is free to rotate in a first direction and in a second direction opposite to the first direction. In the second state, the shaft is constrained from rotating in one of the first direction or the second direction by a defined first endpoint of a range of rotational motion of the shaft. Devices and methods relate to rotation stop mechanisms.

A robotic arm comprising an operation end, a base, a sensor unit and a control unit is provided. The operation end is connected to the base, and the operation end is configured to reach an operational area. The sensor unit provides a sensor signal according to the force applied by or the motion of an operator. When the operation end reaches the operational area, the control unit sets a fixed position on the robotic arm between the base and the operation end. When the sensor signal from the operator fulfills a default condition, the control unit moves the robotic arm away from the operator, without moving the fixed position on the robotic arm.

An active arm module and modular robot arm for an industrial robot comprises a housing, a heat exchanger, a drive device, and a connecting side with a connecting plate. The connecting plate can be mechanically connected to a further arm module or to a robot base for transmitting drive and support forces. The housing defines an interior space for receiving the drive device. The heat exchanger accommodates the drive device at least in sections, and is thermally coupled to the drive device. The heat exchanger has a fluid channel and can exchange heat between the drive device and the fluid. The arm module comprises a fluid contact device arranged at the connecting plate. Fluid can be exchanged with the further arm module or robot base via the fluid contact device; e.g., the fluid channel can be filled with the fluid for exchanging the fluid with the first fluid contact device.

An active arm module and modular robot arm for an industrial robot comprises a housing, a heat exchanger, a drive device, and a connecting side with a connecting plate. The connecting plate can be mechanically connected to a further arm module or to a robot base for transmitting drive and support forces. The housing defines an interior space for receiving the drive device. The heat exchanger accommodates the drive device at least in sections, and is thermally coupled to the drive device. The heat exchanger has a fluid channel and can exchange heat between the drive device and the fluid. The arm module comprises a fluid contact device arranged at the connecting plate. Fluid can be exchanged with the further arm module or robot base via the fluid contact device; e.g., the fluid channel can be filled with the fluid for exchanging the fluid with the first fluid contact device.

A management system is a management system which includes a remote work system having at least one master unit and a plurality of slave units which can be remotely operated and a management server, in which each of the plurality of slave units includes a gripping unit that is configured to grip a target, grip the target by means of autonomous control, and, when being connected to the master unit by the management server, grip the target by means of a remote operation by the master unit, the master unit is configured to perform the remote operation on the plurality of slave units, and the management server includes an operation management unit that is configured to connect the master unit and the plurality of slave units when a remote operation is required.

A management system is a management system which includes a remote work system having at least one master unit and a plurality of slave units which can be remotely operated and a management server, in which each of the plurality of slave units includes a gripping unit that is configured to grip a target, grip the target by means of autonomous control, and, when being connected to the master unit by the management server, grip the target by means of a remote operation by the master unit, the master unit is configured to perform the remote operation on the plurality of slave units, and the management server includes an operation management unit that is configured to connect the master unit and the plurality of slave units when a remote operation is required.

There is disclosed a motor (100) comprising: a stator (120), comprising a core (122) and a plurality of windings (124); and a rotor (140), comprising a plurality of permanent magnets (150, 152, 154), wherein a first portion of the magnets (150, 152) is disposed on two axial rotor portions (142, 144) in close proximity to two respective axial sides of the windings (124), and a second portion of the magnets (154) is disposed on a radial rotor portion (146) in close proximity to a radial side of the windings (124), and wherein energising the windings (124) causes a torque to be applied to the rotor (140) via said two axial rotor portions (144, 144) and said radial rotor portion (146).

There is disclosed a motor (100) comprising: a stator (120), comprising a core (122) and a plurality of windings (124); and a rotor (140), comprising a plurality of permanent magnets (150, 152, 154), wherein a first portion of the magnets (150, 152) is disposed on two axial rotor portions (142, 144) in close proximity to two respective axial sides of the windings (124), and a second portion of the magnets (154) is disposed on a radial rotor portion (146) in close proximity to a radial side of the windings (124), and wherein energising the windings (124) causes a torque to be applied to the rotor (140) via said two axial rotor portions (144, 144) and said radial rotor portion (146).

A linear-object management structure for a robot, where a post-attached linear object is guided via the same path as a basic cable from inside a base and fixed at the position of a first fixing member, is subsequently extended forward beyond the basic cable, through a path closer to a first axis than the basic cable is, is curved in a direction along a first arm, is fixed to a side surface of the first arm, at the position of a second fixing member, such that a certain length margin required for the operation of the first arm is provided between the position of the first fixing member and the position of the second fixing member, and is guided to an upper-side movable portion along the first arm.

A linear-object management structure for a robot, where a post-attached linear object is guided via the same path as a basic cable from inside a base and fixed at the position of a first fixing member, is subsequently extended forward beyond the basic cable, through a path closer to a first axis than the basic cable is, is curved in a direction along a first arm, is fixed to a side surface of the first arm, at the position of a second fixing member, such that a certain length margin required for the operation of the first arm is provided between the position of the first fixing member and the position of the second fixing member, and is guided to an upper-side movable portion along the first arm.