A robot joint module and a wireless power supply apparatus, system, and method therefor. The apparatus includes: a wireless power receiver arranged at a connecting end of a current robot joint module and adapted to receive electrical power from a previous robot joint module of the current robot joint module; and a wireless power transmitter arranged at an output end of the current robot joint module and adapted to transmit the electrical power to a next robot joint module of the current robot joint module. By receiving electrical power from a previous robot joint module in a wireless power supply mode and sending the electrical power to a next robot joint module in a wireless power supply mode, the electrical power can be transferred between a plurality of robot joint modules, without arranging any power cable. The cost of and difficulty in arranging power cables can be reduced, and cable breakage caused by winding of the power cables can also be avoided, thereby implementing infinite continuous rotation of joints.

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 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.

An apparatus includes a drive; a movable arm connected to the drive and having a first link rotatable about the drive at a first rotary joint, a first actuator configured to cause a rotation of the first link about the first rotary joint, at least one second link connected to the first link at a second rotary joint, at least one second actuator configured to cause a rotation of the second link about the second rotary joint, and at least one gripper on the second link, the gripper being configured to carry a payload. The gripper includes a dielectric substrate, at least one electrode disposed on the dielectric substrate, the electrode being configured to produce an attractive force on a surface of the electrode to attract the payload, and a main electronic module configured to apply a voltage to the electrode from a source of current.

A wirelessly powered and controlled robotic apparatus enabling performance of tasks within a three-dimensional space includes a rail, a robotic unit, and a tool. The rail comprises negative and second paths to carry an electrical current. The robotic unit comprises a microcontroller having a drive motor and a transceiver engaged thereto and is engaged to and electrically coupled to the rail. A transfer unit is engaged to both the drive motor and the rail and thus can translate rotation of the drive motor to a force to motivate the robotic unit along the rail. The microcontroller selectively actuates the transfer unit to move the robotic unit along the rail to a location. The transceiver receives commands wirelessly from a control unit and transmits data thereto. The tool is engaged to the robotic unit and can perform a task at, or proximate to, the location.

A charging apparatus for wireless charging of one or more robotic devices includes a power transmitting unit having a plurality of conducting wires each configured to carry a respective alternating current signal and to generate a time-varying magnetic flux when the conducting wire carries the alternating current signal, a processor configured to detect a presence or an absence of an induction coil of a robotic device within a predetermined distance of a conducting wire and to generate control data based on the result of the detection, and a control unit configured to control at least one of an amplitude and a frequency of each respective alternating current signal supplied to each of the conducting wires based on the control data, where the control unit is configured to increase at least one of an amplitude and a frequency of an alternating current signal supplied to a conducting wire in response to control data indicating the presence of the induction coil within the predetermined distance of the conducting wire.

An apparatus includes a drive; a movable arm connected to the drive, the movable arm comprising a first link connected to the drive at a shoulder, a second link connected to the first link at an elbow, a third link connected to the second link at a wrist, and a fourth link connected to the second link at the wrist; at least one first actuator located in the second link configured to cause a rotation of the third link about the wrist; and at least one second actuator located in the second link configured to cause a rotation of the fourth link about the wrist. One or more of a thermal management, a power distribution, or a communication is effected through the second link.

An apparatus for labeling support structures includes: a chassis having a locomotive assembly; an effector assembly having a first end coupled to the chassis and a second end movable relative to the chassis; a label modification unit at the second end of the effector assembly, the label modification unit including an image sensor; and a controller coupled to the locomotive assembly, the effector assembly and the label modification unit, the controller configured to: obtain label modification data defining a location of a low powered display relative to a reference feature on a support structure for modifying content displayed by the display; control the locomotive assembly to travel to the support structure; detect the reference feature via image data captured at the image sensor; control the effector assembly to place the label modification unit at the location; and control the effector assembly and the label modification unit to modify the content.

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 method of inductively coupling a first body and a second body is provided, wherein the first body rotates relative to the second body. During rotation, alignment is maintained between a first and second coil. Signals are sent and received between the coils.