An attaching mechanism includes a fastening member, a first member, a second member including an insertion portion through which the fastening member passes, and a third member configured to enable the fastening member to pass through the insertion portion when the third member is located at a first position, and engage with the fastening member and disable the fastening member from passing through the insertion portion when the third member is located at a second position. When the third member is located at the second position, and the fastening member is moved toward a predetermined direction, the third member is pressed by the fastening member toward the predetermined direction, and the second member is attached to the first member.

An end effector adaptor device for a robotic arm may have a body adapted to be secured to a working end of a robotic arm at a proximal face, the body having a distal face configured for connection of an end effector thereto. A proximal connector is in the proximal face, the proximal connector configured to be connected to a complementary connector at the working end of the robotic arm for signal and power transmission between the robotic arm and the body. A distal connector is in the distal face, the distal connector configured to be connected to a complementary connector at the end effector connected to the distal face for signal transmission and/or power transmission between the body and the end effector. Circuitry is between the proximal connector and the distal connector.

A modular configurable robot, comprising robot modules comprising a coupling mechanism including an electrical coupling member comprising a network communication signal connection, an arrangement forming upon coupling an orientation signal, an integrated circuit comprising a microcontroller circuit with unique identification code and I/O ports coupled to said electrical coupling to receive orientation electrical signal, a communication slave module comprising ports and registers storing state values of the ports, one port pre-designated as input, the ports being open or closed depending on the port state, the robot comprising a master communication module forming with said slave modules a master slave communication network topology, a server hosting a database of robot module parameters, accessible by unique identification code, said master module retrieving from said communication slave module the unique identification code, and from the database robot module parameters, and from said microcontroller circuit said information of a relative orientation.

Described is a robotic apparatus (10) for investigating a confined area comprising: an articulated robot (20) for insertion into a confined area, the robotic apparatus further comprising a robot control system (30) for controlling the articulated robot. Further, the robot control system comprises a control unit (50), a robot driving means, a seal (70) for isolating the confined area from the external environment and at least one transmission member (80), wherein the control unit is configured to send control signals to the robot driving means, and the at least one transmission member extends from the robot driving means to connect to the articulated robot, the at least one transmission member extending through the seal.

An automatic tool exchange coupler and an automatic tool exchange device are provided that achieve further improvement in the user-friendliness of the automatic tool exchange device. The coupler includes a coupler body, a first direction switching valve and a second direction switching valve that are provided to a first side surface of the coupler body. The coupler body has: in a first side surface, an uncoupling input port being connected to a pipe for introducing a gas for uncoupling; and in the second side surface opposite to the first side surface, an uncoupling output port being configured to connected to the uncoupling port. The uncoupling input port is located at a position where a center of the uncoupling input port is radially offset with respect to the uncoupling output port by at least an amount corresponding to a length of a diameter of the uncoupling input port.

A device for transmission of rotary motion and transfer of a fluid medium, comprising a planetary gear train for transmission of rotary motion about a main axis which has at least one reduction stage which is provided with a sun gear, which rotates about the main axis, and a toothed ring gear which are mutually concentric and between which at least two planetary gears are engaged which are supported in rotation at least about the respective longitudinal axes which are parallel to the main axis by a planetary gear carrier; such planetary gear train is provided with a driving input sun gear and with an output ring gear and with an output planetary gear carrier, of which one can move in rotation about the main axis with respect to the other; and a rotary joint which extends externally to the planetary gear train for transfer of the fluid medium.

Described herein is an atomizer changing system, including a master unit and at least one slave unit, where the master unit has at least the following components: a releasable connecting element, surrounding a center of the master unit, for a nonpositive and positive connection (KS, FS) of the master unit to the slave unit, a coupling plate arranged in the center of the master unit and having a plurality of coupling points for supplying an atomizer that can be connected thereto with substances, energy and/or information, and an adapter for connecting the master unit to a hollow wrist of a coating robot; and where the slave unit has at least the following components: a coupling plate for connecting the slave unit to the master unit and to the atomizer; and a releasable connecting element for connecting the slave unit to the atomizer.

A tool changing system of a robot manipulator is proposed. The tool changing system includes: a master coupled to an end of the robot manipulator at a first side thereof; and a slave coupled to a tool at a first side thereof and coupled removably to a second side of the master at a second side thereof, wherein the master includes an actuator and a master magnet rotating according to the rotation of the actuator, and the slave includes a slave magnet rotating in synchronization with the rotation of the master magnet by magnetism therebetween with the master and the slave coupled to each other, whereby the rotating force of the slave magnet as a rotating force necessary for operating the tool is transmitted to the tool.

An adaptive tooling interface comprises a plurality of motors, disposed at least partially within a housing, which are operatively in communication with a controller and where a first power output is operatively in communication with a first motor of the plurality of motors and a second power output operatively in communication with a second motor of the plurality of motors. A drive interface, comprising a tooling adapter, is operatively in communication with the plurality of motors and configured to mate with and provide power to one or more tools, which comprise a matching subsea tool tooling interface, via the first power output and the second power output. The adaptive tooling interface may be connected to or otherwise integrated into a subsea vehicle system comprising a subsea vehicle.

A power supplying module that can be reduced in size is provided. The power supplying module includes a module body, and a lead-in unit provided on one surface of the module body. The lead-in unit includes a plate unit that fixes at least one sealing tube to the one surface of the module body, and at least one circumference holding unit that holds a circumference of the corresponding sealing tube. The plate unit is provided with, in a longitudinal direction of the one surface of the module body, a plurality of cable insertion holes, and a plurality of positioning portions that position the plurality of circumference holding units to the corresponding cable insertion holes.