The present invention provides a main body with a coupling section, wherein the circuit board includes terminals for power supply and for signal, wherein the coupling section has a first positioning section and a second positioning section, and wherein the assembly is configured so that in a state where positioning has been performed by the first positioning section, positioning by the second positioning section is performed and the coupling section is coupled to another coupling section of another main body. Thus, coupling the coupling section is performed in the state where positioning has been performed, wherein connection of the terminals for power supply and for signal to power supply and signal terminal sections is performed in this state, which may enable the operability for coupling a coupling section to be improved while ensuring a mechanically and electrically correct coupled state.

A robot system includes one or more combinations of a driving section configured to receive supply of electric power and generate a rotation output of an output shaft and receive supply of a rotating force to the output shaft and generate electric power, a movable section moved by the rotation output, a detecting section configured to detect an angular position of the output shaft, resistor equipment coupled to the driving section, and a switch that can turn on and off coupling of the resistor equipment and the driving section and a control section configured to control the robot system. The control section can execute first braking control targeting the driving section to which the electric power is not supplied, the first braking control calculating speed of the rotation output of the driving section based on an output of the detecting section and causing the switch to turn on and off the coupling of the resistor equipment and the driving section at timing determined in a time-series manner according to target deceleration of the driving section and the speed of the rotation output.

The invention relates to a handling device (1), having a drive carriage (2) that is movable relative to a carrier (3), wherein a scissor lift (7) having a plurality of scissor-lift members (8) is arranged with its first end on the drive carriage (2), wherein a carrier plate (11) that is movable relative to the drive carriage (2) by means of the scissor lift (7) is arranged at the second end of the scissor lift (7), wherein: a gripping tool is arranged on the carrier plate (11), the scissor-lift members (8) are hollow throughout and are sealingly interconnected in order to actuate the gripping tool by means of a gaseous medium.

An industrial robot includes: a first-member and a second-member that are rotatable about a particular axis and that each have a hollow portion extending along the axis; a cylindrical member inserted into the hollow portions along the axis, and fixed to the first-member; and a wire disposed in a cylindrical gap between the cylindrical member, the first-member, and the second-member, the wire having a length that enables rotation between the first-member and the second-member and having one end fixed to the first-member and another end fixed to the second-member. The second-member includes a first-portion rotatably supported by the first-member, a second-portion that fixes the end of the wire, and a third portion serially connected between the second-portion and the first-portion, and the third portion has an inner circumferential surface that faces the gap and has been subjected to a friction reducing process.

An installing device includes a connection member and a linear motion support. The connection member is disposed at a base end portion of a hollow arm which extends in an extension direction and which has a hollow extending in the extension direction. A linear object passing through the hollow is connectable to the connection member. The linear motion support supports the connection member slidably with respect to the hollow arm in the extension direction.

An extensible mast allows a payload to be supported at a distance from a supporting device. The payload may be connected via a cable to one or more components in the supporting device. A cable rotation apparatus allows a cable to rotate during dispensation of the cable, such as during extension or retraction of the extensible mast, while minimizing strain on the cable. The apparatus comprises a stationary spool, a furling core, and a rotating spool. A beveled gear on each of the spools engages a pair of beveled gears in the furling core. As the rotating spool rotates with respect to the stationary spool, the furling core rotates at one-half the speed and the cable is dispensed from an opening in the rotating spool. The furling core incorporates a guide wheel that maintains an orderly transfer of the cable from one spool to another.

A system includes an inspection robot comprising a plurality of sensor sleds; a plurality of ultra-sonic (UT) sensors; a couplant chamber mounted to each of the plurality of sleds, each couplant chamber comprising: a cone, the cone comprising a cone tip portion at an inspection surface end of the cone; a sensor mounting end opposite the cone tip portion; a couplant entry fluidly coupled to the cone at a position between the cone tip portion and the sensor mounting end; and wherein each of the UT sensors is mounted to the sensor mounting end of one of the couplant chambers.

A robot includes first and second arms to rotate and convey an object; a first rotary body to support the first arm and having a first fluid passage and at least one second fluid passage communicating with the first fluid passage; a base-end-side arm formed with an internal space and a hole part into which a part of the first rotary body is inserted; a second rotary body to support the second arm and having a third fluid passage communicating at one end thereof with the second fluid passage and communicating at the other end thereof with the internal space; a supplying device disposed in the internal space and connected to an upstream-end side of the first fluid passage, and to supply fluid to the first fluid passage; a first motor to rotate the first rotary body; and a second motor to rotate the second rotary body.

A dress pack manager for use with a robotic arm having an end-of-arm tool supplied with power or working fluid via a dress pack. A pair of rollers are spaced apart such that the dress pack may pass between them, and such that rotation of the rollers applies friction to the dress pack and causes the dress pack to move. An electric motor rotates one of the rollers in both a forward and backward rotation and is torque-controlled to maintain a constant tension applied to the dress pack by the rollers.

A drive system (1) which is designed in particular as a robot (1a) and has a linear drive (2), on the drive unit (7) of which, which can be driven to perform a drive movement (8), a working unit (3) is mounted with an interface module (4) being connected therebetween. The working unit (3) has at least one fluidic actuator (54) and at least one electrical actuator (63). The linear drive (2) is accommodated in a casing body (67) which has a longitudinal slot (74) through which the interface module (4) passes. A flexurally resilient fluid tube arrangement (95) and a likewise flexurally resilient power cable arrangement (97), both of which lead to the interface module (4), extend in a casing-body interior (68) which is enclosed by the casing body (67), wherein a fluidic connection and an electrical connection to the working unit (3) are produced through the interface module (4).