An attachment module constructed to enable a vehicle charging robot to attach to a vehicle and to thereafter insert its charging connector into the vehicle's charging socket. Once the vehicle is charged and the charging connector is disconnected from the charging socket, the attachment module is further constructed to enable the robot to detach from the vehicle.

An exoskeleton system comprising at least one actuator unit that includes a fluidic actuator; an exoskeleton device including a fluidic system, and electronics; and a first cable extending from the exoskeleton device to the at least one actuator unit.

An exoskeleton system comprising: one or more actuator units that comprise a fluidic actuator; an exoskeleton device; one or more cables, the one or more cables comprising a first cable extending from the exoskeleton device to a first actuator unit of the one or more actuator units; and a retractable cable assembly coupled to the first cable, with the retractable cable assembly configured to pull the first cable to reduce slack in the first cable.

A cable guide device of an articulated robot is disclosed. The disclosed cable guide device can comprise: a base; at least one rotary arm rotatably coupled to the base in an articulated form; at least one cable passing through the base so as to be connected to the rotary arms; a cable guide block coupled to a driving unit within the base; a sliding groove formed on the outer peripheral surface of the cable guide block; and a cable friction reducing device member which is coupled to a portion of the cable accommodated in the base and which rotates along the sliding groove together with the portion of the cable according to the rotation of the rotary arms.

An attachment module constructed to enable a vehicle charging robot to attach to a vehicle and to thereafter insert its charging connector into the vehicle's charging socket. Once the vehicle is charged and the charging connector is disconnected from the charging socket, the attachment module is further constructed to enable the robot to detach from the vehicle.

End effectors and systems including end effectors including embedded batteries and auxiliary components powered by the batteries are described. In an example, the end effector includes a base portion coupleable to a motor carried by an appliance that is separate from the end effector; and a battery disposed in the base portion configured to power an auxiliary component of the end effector.

A labeling device includes: a robot having articulated arms with arm sections that are articulated: together, to a robot base, and to a platform of a label pickup device. The pickup device has a base plate and a plunger. The plunger has a fixed portion mounted to the base plate and is not displaceable relative to the base plate in a longitudinal direction, has a portion that is movable in the fixed portion in the longitudinal direction toward the base plate to a retracted position, and has an end configured to pick up a label. A pressure regulator of the plunger breaks a negative pressure in the plunger. The plunger's fixed portion covers an opening of its movable portion in a gas-tight manner by of the when the movable portion in an extended position and which is not covered when in the retracted position.

A rotary axis module includes an actuator that includes a first member and a second member, the actuator relatively driving the second member so as to rotate about a predetermined axis with respect to the first member, a DC power source, and a switch. The actuator includes a brake that is releasable by supplying a DC voltage. A first brake circuit that is connected to a control device that controls the actuator, and a second brake circuit that is provided in parallel with the first brake circuit and connected to the DC power source via the switch, are connected to the brake.

A linear joint includes a motor assembly includes a rotating shaft for outputting motion; a transmission mechanism including a screw and a nut threadedly connected to the screw, the nut being coaxial with respect to and securely connected to the rotating shaft so as to be rotatable together with the rotating shaft; and a rod connected to a first end of the screw so as to move together with the screw along a lengthwise direction of the screw.

A robot cable-assembly management structure including a first fixing member that fixes, to a turning drum, a cable assembly extending beside the turning drum in a front-rear direction, and a second fixing member that fixes, to a side surface of the arm, the cable assembly extending to a front side of the first fixing member, at a position closer to a distal end of the arm than the second axis, where a movable portion of the cable assembly located between the first fixing member and the second fixing member is provided with a necessary length of allowance and is twisted in one direction, so that the movable portion is bent in a direction away from the side surface of the arm when the arm swings to a rear swing end is displaced toward the side surface of the arm as the arm swings toward a front swing end.