A mechanical arm designed to provide automated garbage collection with smooth, constant movement (i.e. movement that has minimal jerk/shock) thereby resulting in limited shock stress on the components and leading to high durability. The mechanical arm including a horizontal displacement system having a plurality of sections rollingly engaged to one another and a motor mounted to an immobile section for drivingly extending section in a generally horizontal orientation, a vertical displacement system having a plurality of masts rollingly engaged to one another and a motor mounted to a first mast for drivingly extending a second mast in a generally vertical orientation, and/or a grabber system having a plurality of fingers mounted to a frame and operated by a single motor.

Anthropomorphic hand comprising: a palm; a metacarpus; a thumb; four aligned fingers constrained to said palm, each comprising a proximal phalanx, a middle phalanx and a distal phalanx; a motor; a plurality of differential stages which transmit motion from said motor to said aligned fingers and to said thumb: a first stage whose planet carrier is moved by said motor and whose sun gears move planet carriers of a second and a fifth stage, sun gears of the second and fifth stages being integral to the planet carriers of a third and a fourth stage, whose sun gears move four gears having axes coincident with the axes of rotation between the aligned fingers and the palm; sun gears of the fifth stage being configured to rotate said metacarpus and a gear having axis coincident with the axis of rotation between the proximal phalanx of the thumb and the metacarpus.

A robot hand includes a motor with a rotary shaft, an accommodating member accommodating a distal end of the rotary shaft, a plurality of swing members swinging with respect to the accommodating member due to rotation of the rotary shaft, and a plurality of claw members swinging with the plurality of swing members.

A robot includes elbows connecting forearms rotatably to upper arms with two rotational degrees of freedom. The elbow includes: an elbow joint connecting the forearm and the upper arm with two rotational degrees of freedom; an elbow drive main link; an elbow drive auxiliary link; a forearm-side main link attaching unit attached with one end of the elbow drive main link with two rotational degrees of freedom, and provided in the forearm; an elbow-drive-main-link-side auxiliary link attaching unit attached with one end of the elbow drive auxiliary link with two rotational degrees of freedom, and provided on the elbow drive main link; and two linear actuators for moving two upper-arm-side link attaching units each attached with the other end of either the elbow drive main link or the elbow drive auxiliary link with two rotational degrees of freedom, and provided so as to be movable along the upper arm.

A refuse vehicle includes a chassis, multiple tractive elements, a reach assembly, and a lift assembly. The multiple tractive elements are coupled with the chassis and configured to support the refuse vehicle. The reach assembly is coupled with the refuse vehicle. The lift assembly is coupled with the reach assembly. The lift assembly includes a track and a fully-electric grabber assembly. The track includes a straight portion and a curved portion. The fully-electric grabber assembly can ascend or descend the track and includes a carriage, a first grabber arm, a second grabber arm, and an electric motor. The carriage is configured to movably couple with the track. The first grabber arm and the second grabber arm are pivotally coupled with the carriage at opposite ends of the carriage. The electric motor is configured to drive the first grabber arm and the second grabber arm to rotate relative to the carriage.

Various embodiments of a bio-inspired robot operable for detecting crack and corrosion defects in tubular structures are disclosed herein.

A gripper includes a finger module coupled to one side of a palm module, the palm module including a first power unit including a first rotary shaft and configured to rotate the first rotary shaft, a screw member configured to rotate in conjunction with a rotation of the first rotary shaft, a nut member coupled to the screw member, a first member coupled to the nut member and movable in a vertical direction in conjunction with a vertical motion of the nut member, the first member having a groove extending in one direction and having a recessed shape, and a connection member having a first side coupled to the finger module and a second side inserted into the groove, wherein the connection member is movable away from or toward the screw member by restriction between the connection member and an inner surface of the groove.

A robotic storage assembly includes a safe that may a plurality of items. A drawer is slidably coupled to the safe. A control is coupled to the safe and the control may be manipulated. A storage unit is positioned within the safe to contain the plurality of items. The storage unit includes a plurality of trays. A spacing unit is positioned within the safe and the spacing unit engages the plurality of trays. The spacing unit selectively spaces the trays apart from each other. A retrieval unit is positioned within the safe. The retrieval unit is selectively positioned between the trays when the trays are spaced apart. Thus, the retrieval unit retrieves the items in the storage unit. The retrieval unit is selectively aligned with the drawer to deposit the items in the drawer. Thus, the items may be removed from the safe.

A robotic gripping device is provided. The device includes a finger having a worm gear coupled to its base end. The device also includes an actuator having a motor and a shaft, wherein the shaft is configured to rotate a worm coupled to the worm gear, and the actuator is mounted on a carriage such that the actuator is configured to slide along an axis. The device also includes a spring having first and second ends, wherein the first end is coupled to the motor and the second end is fixed. Further, the actuator is configured to (i) rotate the shaft relative to the motor by a first amount to move the finger toward an object, and (ii) when the finger is in contact with the object and is prevented from further movement, further rotate the shaft relative to the motor to slide the actuator along the axis.

A surgical tool having a compact design is disclosed. The tool has a first set of prongs disposed along a first axis, a second set of prongs disposed along a second axis different from the first, and an asymmetric gear set. The gear set includes a rotatable first drive gear disposed on one of the first set of prongs and a rotatable first actuator gear disposed on one of the second set of prongs. The first drive gear is configured to drive the first actuator gear, forming a first gear pair. The gear set also includes a rotatable second drive gear disposed on one of the first set of prongs and a rotatable second actuator gear disposed on one of the second set of prongs. The second drive gear is configured to drive the second actuator gear, forming a second gear pair. The first gear pair and the second gear pair have different diameters.