A mechanical arm includes a first link connectable to a surface, a second link, a third link, a fourth link, and a fifth link that are coupled to one another in series, and an end effector connectable to the fifth link. The end effector is rotatable about an axis of rotation same as an axis of rotation of the fourth link, and rotatable about an axis of rotation orthogonal to the axis of rotation of the fourth link. The first link, the second link, the third link, the fourth link, and the fifth link are collectively structured and configured to rotate such that the end effector is actuatable to a workspace under the surface.

An end-effector assembly comprising a master boom, a crossbar coupled to the master boom, at least one branch rail, and a swing arm is provided. The at least one branch rail is movably coupled to the crossbar by a branch lock. The at least one branch rail has a driving groove formed longitudinally therealong for telescopic movement relative to the crossbar. The branch lock comprises a crossbar clamp and a branch rail clamp. The crossbar clamp is slidably and pivotally disposed about the crossbar for slidable and pivotal movement therealong. The branch rail clamp comprises a body having a primary telescoping lock including a receiving bore formed therethrough and a wedging collet disposed in the receiving bore. The body further comprises a secondary telescoping lock having a ball and a plunger disposed in a ball-plunger cavity of the body.

A mechanical joint configured for providing dissipation of heat generated is provided. The mechanical joint includes a housing containing a motor assembly configured to drive a gear assembly for driving the mechanical joint, the motor assembly configured to be controlled by a control assembly for controlling rotation of a rotor of the motor assembly; wherein a brake disk of the control assembly is configured to increase air flow within the housing. A robot and a robotic system are also disclosed.

An actuator module includes a drive unit for generating a rotational force, a deceleration unit connected to the drive unit to receive the rotational force therefrom for reducing a rotational speed transmitted thereto to increase the rotational force, a flexible unit connected to the deceleration unit to receive the rotational force therefrom and having a plurality of elastic members in a stacked form, the elastic members being variable by an external force, and an output unit connected to the flexible unit to receive the rotational force therefrom for outputting the transmitted rotational force to the outside, wherein the elastic members have the same elastic force or different elastic forces, and are selectively varied depending on the magnitude of the external force applied to the output unit.

A power supply system for at least one system for transporting and/or machining workpieces having a plurality of electric drive units is disclosed. The supply grid of the drive units is supplied via at least one recuperating energy storage device, which is electrically connected to a charging device that is fed from an alternating- or three-phase low-voltage grid. The power supply system for a transport and/or machining system draws maximally 50 percent more power from the power supply grid compared to the regular nominal supply current regardless of the occurrence of current peaks.

The present invention relates to a brake control device and a robot including same. A robot according to an embodiment of the present invention comprises: a normal power- supplying unit for supplying electric energy required to move and operate the robot; a brake module for braking or unbraking a motor that moves the robot; an emergency power- supplying unit which receives and stores electric energy from the normal power-supplying unit, and supplies the stored electric energy to the brake module when the supply of the electric energy from the normal power-supplying unit is cut off; and a control processor which applies, to the brake module, a signal for controlling the supply of the electric energy, and controls the movement and operation of the robot.

A refuse vehicle includes a chassis, tractive elements, a lift apparatus, and a reach assembly. The tractive elements couple with the chassis and support the refuse vehicle. The lift apparatus includes a track and a grabber assembly. The track includes a straight portion and a curved portion. The grabber assembly releasably grasps a refuse container and ascends or descends the track to lift and empty refuse into a body of the refuse vehicle. The reach assembly includes an outer member, a first extendable member, and a second extendable member. The first extendable member is received within an inner volume of the outer member and translates relative to the outer member. The second extendable member is received within an inner volume of the first extendable member and translates relative to the first extendable member. The lift apparatus is fixedly coupled at an outer end of the second extendable member.

A collaborative robot operation apparatus includes an operation unit that is operated by an operator in direct teaching of a robot including a cylindrical outer surface at least in a part, a communication unit that communicates operation information to the operation unit, to a control apparatus of the robot, and an attachment portion that detachably attaches the operation unit on the outer surface of the robot. The operation unit includes a rotation stopping portion between the outer surface of the robot and the operation unit.

A surgical manipulator device for positioning a surgical instrument has a frame, a first mount, a second mount, a first suspension arm arrangement supported on the frame and connecting the frame to the first mount in an articulated manner, and a second suspension arm arrangement supported on the frame and connecting the frame to the second mount in an articulated manner. The first and the second suspension arm arrangements are each displaceable relative to the frame in first and second motion planes parallel to each other and spaced apart, so that the first mount is displaceable in the first motion plane and the second mount is displaceable in the second motion plane.

An automated transforming tooling system apparatus and method for shuttling a workpiece to and from an industrial operation. The system includes a workstation for complementarily engaging and securing the workpiece, and at least one holder removably secures at least on end effector tool to the workstation. At least one transfer bar is movably positioned with respect to the workstation. At least one automated transforming tooling assembly is connected to the transfer bar and has a plurality of links adjustably connected by motorized joints to automatically position the automated transforming tooling assembly. An automated tool changer is connected to the automated transforming tooling assembly and releasably engages the end effector tool between a disengaged position, wherein the end effector tool is disengaged from the automated tool changer, and an engaged position, wherein the end effector tool is engaged by the automated tool changer.