In a robot (1) for gripping and/or holding objects (2), in particular workpieces, tools or carrier parts, the robot comprising: at least one robot arm (3, 4, 5) which is supported on a support frame (19) and is movable in space in at least one translational and/or rotational degree of freedom, a gripping and/or holding device (6), on which the respective object (2) is supported in a positionally oriented manner and/or held in a rotational arrangement, at least one electric motor (9) provided in the gripping and/or holding device (6), by means of which a torque and/or a clamping force is generated which acts on the object (2), and a drive shaft (24) mounted in the robot arm (5), which is coupled in a driving manner to the gripping and/or holding device (6), preferably in such a way that the gripping and/or holding device (6) rotates about its own longitudinal axis (6′),
the gripping and/or holding device (6) arranged at the free end of the robot arm (5) should be freely movable in space, so that rotation about its own longitudinal axis (6′) can be carried out as often and as quickly as desired.

This is achieved in that an interface (31) is provided between a free end (10) of the robot arm (5) at the end and the gripping and/or holding device (6), which interface (31) is bridged by a coupler (25) fixed in a non-rotating arrangement to the robot arm (5) and by a flange (11) adapted thereto, which flange (11) is connected in a non-rotating arrangement to the gripping and/or holding device (6) and the drive shaft (24), in that a first inductively operated transceiver (12) is provided in the coupler (25), which transceiver (12) is connected to a power source (15) via an electrical line (14) fed to the robot arm (5), in that a second inductively operated transceiver (13) is provided in the flange (11), which is connected to the electric motor (9) in the gripping and/or holding device (6) via electrical lines (14), and in that an air gap (21) is provided between the coupler (25) and the flange (11) as a component of the interface (31).

An electrodynamic apparatus includes a first arm extending in a first direction, a second arm supported by the first arm, a linear actuator that moves the second arm along the first direction with respect to the first arm, a support extending in a second direction that is different from the first direction and supporting the first arm, and a rotating mechanism that rotates the support about an axis of rotation parallel to the second direction. The first arm includes a power transmission antenna. The second arm includes a power reception antenna. The power transmission antenna supplies electric power to the power reception antenna wirelessly. In rotating the support, the linear actuator moves the center of gravity of the second arm to the axis of rotation first, and then the rotating mechanism rotates the support.

A quick change end effector system for use with a robot includes: a quick change end effector configured for application to a task to be completed by a robot, the quick change end effector further comprising an end effector magnet; and a robotic manipulator configured to lock to the end effector, the robotic manipulator further configured to use the end effector to complete the task, the robotic manipulator comprising a manipulator magnet, the manipulator magnet being configured to magnetically attract the end effector magnet, thereby locking the manipulator in a mechanically strong connection to the quick change end effector, wherein upon disengagement of the magnetic attraction locking the manipulator to the quick change end effector, the quick change end effector can be quickly removed from the manipulator.

A magnetically controllable robotic device including a body having a first body part and a second body part movably connected with the first body part. The first body part and the second body part are both rigid. The first body part is magnetically-responsive such that the first body part can be controlled by an external magnetic field generated by an magnetic control system. The first body part may be controlled such that the magnetically controllable robotic device is moved by the external magnetic field.

A rotation axis module includes: an actuator which relatively rotates a fixed member and a movable member; a umbilical member which penetrates through the interior of the actuator to extend; a first fixing portion which fixes the umbilical member at a rotation axis of the fixed member or at a position corresponding to the vicinity thereof; a second fixing portion which fixes the umbilical member at an output axis of the movable member or in the vicinity thereof; a first relay portion which is positioned at a side of the fixed member, one end of the umbilical member being connected to the first relay portion; and a second relay portion which is positioned at a side of the movable member, the other end of the umbilical member being connected to the second relay portion.

A tool interchange for a submersible remote operated vehicle (ROV) arm includes a first interchange body that affixes to an ROV arm. A second interchange body is carried by the first interchange body to rotate on a rotation axis. The second interchange body includes a tool mount actuable between gripping an ROV tool to the second interchange body and releasing the ROV tool from the second interchange body. An inductive power coupling part is provided in the tool mount. The inductive power coupling part is presented outwardly in the tool mount opposite the first interchange body, resides on the rotation axis and is fixed with respect to the first interchange body while the second interchange body rotates. The inductive power coupling part is adapted to inductively communicate power with a corresponding inductor power coupling part of the ROV tool when the ROV tool is docked in the tool mount.

A robot includes: an arm; a shaft supported at a tip of the arm so as to be movable in a direction of a predetermined axis; a power transmitting unit fixed to the arm and connected to a power supply; and a power receiving unit and a battery that are fixed to the shaft. In a state in which the shaft is positioned at a predetermined position in the direction of the axis, the power receiving unit is close to the power transmitting unit to wirelessly receive power transmitted from the power transmitting unit, and the battery stores the power received by the power receiving unit and uses the power as a power source of a device attached to the shaft.

Proposed is a power supply apparatus capable of suppressing heat generation, and semiconductor manufacturing equipment and a transport system including the same. The power supply apparatus, which supplies power to a transport device in semiconductor manufacturing equipment, includes a first base member made of a conductive material installed along a moving path of the transport device, a second base member provided on a surface of the first base member and made of a magnetic core material, a track member provided as an installation structure disposed on a side of the second base member, a power supply member installed in the track member and to which current is applied to supply power, and a power reception member disposed in a power reception core member provided in the transport device at a predetermined interval from the power supply member, and magnetically coupled to the power supply member to generate an induced current.

An apparatus including a first base plate, where the first base plate is configured to have at least one linear drive component and/or at least one power coupling component connected to a top side of the first base plate, where the first base plate is configured to be located inside a vacuum chamber; and a plurality of rails or transport guides on the top side of the first base plate. An end of the first base plate includes at least one alignment feature configured to align an end of the first base plate to an end of a second base plate. The first base plate is configured to provide, in combination with the second base plate, a structural platform inside the vacuum chamber for a robot drive to move in the vacuum chamber along the plurality of transport guides.

A robot apparatus equipped with a driving source includes a power transmission module configured to transmit power to the driving source, a power reception module configured to receive the power transmitted by the power transmission module, and a control device configured to control a power transmission start timing in such a manner that the power reception module receives predetermined power at a timing at which the driving source operates.