A robotic apparatus including a plurality of rigid body sections that move relative to each other by one or more multi-degree of freedom joints. The robotic apparatus can traverse a fixed frame by attaching its distal ends to the frame and moving the rigid body sections relative to each other.

Approaches presented herein enable maneuvering collaborative robots to rescue persons in a hydrological disaster. A plurality of robots are dispersed in a body of water to spread out and seek victims using cooperative foraging techniques within resource constraints. A location of victims located by a robot using sensing techniques is communicated to other robots. A situational assessment is performed using victim location information to determine a number of robots to deploy to the location. The deployed robots are directed to perform coordinated maneuvers to create a connected floatation unit to support floatation of victims for rescue.

A robotic apparatus including a plurality of rigid body sections that move relative to each other by one or more multi-degree of freedom joints. The robotic apparatus can traverse a fixed frame by attaching its distal ends to the frame and moving the rigid body sections relative to each other.

A system and method for an articulated arm based tool guide includes an elongated body having a guide hole, a first joint attached to a first end of the body, a second joint attached to a second end of the body opposite the first end, a first mounting arm coupled to the body using the first joint, and a second mounting arm coupled to the body using the second joint. The first mounting arm is configured to be attached to a first articulated arm of a computer-assisted medical device. The second mounting arm is configured to be attached to a second articulated arm of the computer-assisted medical device. The guide hole is adapted to receive a medical tool and maintain a working end of the medical tool in alignment with the guide. In some embodiments, the first mounting arm includes identifying information identifying the tool guide as a tool guide.

A geared parallel manipulator of the SCARA type is provided that consists of a pair of motors, each driving in a controlled manner a pinion. The two pinions mesh each with a rack, said two racks being joined together via a revolute, or via a flexure hinge. The proposed parallel manipulator is simple in design and can be fabricated inexpensively of stamped sheet metal or of extruded parts. It can also be fabricated as a microelectromechanical system (MEMS) using thin film technologies.

A pendular handling system for handling parts in a press line may have two articulated robots arranged on opposite sides with respect to the central vertical plane of the press line, each robot having at least four rotational axes in series between a robot base and a robot wrist, and each robot being mounted with the first axis horizontal and perpendicular to the press line flow direction, a first arm of each robot can swing in a vertical plane in the press line flow direction.

A foldable boom for conveying an item, said foldable boom being foldable about at least one folding axis, said foldable boom being locatable in a folded stowed position, and moveable to unfolded extended positions; said foldable boom having a near end arranged for pivotal movement about a first horizontal axis located on a turret, said turret being rotatable about a vertical axis; said foldable boom having first conveying apparatus to convey an item therealong, internally within said foldable boom, to a remote end of the foldable boom; wherein said foldable boom is foldable about a folding axis, and a pivoting shuttle equipped with a clamp to releasably hold an item is provided at said folding axis to transfer said item between said first conveying apparatus in boom elements connected about said folding axis.

A pipe inspection robot includes first and second bodies connected by a connection mechanism, at least two legs connected to the first body, and at least two additional legs connected to the second body, each of the at least two legs and the at least two additional legs including a linkage connected at one end to the first or second body, and a pipe engaging member connected at another end of the linkage; wherein each linkage is configured to operate between a stowed position, in which the pipe engaging member is disposed adjacent the first or second body, and an extended position, in which the linkage is adapted to cause the pipe engaging member to slide against an inner surface of a pipe.

A multiaxial robot includes a first rotation module, a second rotation module, and a connecting member. The first rotation module includes a base and a plurality of arms. The arms are configured to rotate parallel to a first plane relative to the base. The second rotation module includes at least one wrist. The wrist is connected to the farthest arm arranged from the base in the first rotation module and configured to rotate parallel to a second plane relative to the first rotation module. The connecting member is pivotally connected to the base and connected to an adjacent one of the arms, or is connected between adjacent two of the arms and the wrist.

A robotic apparatus including a plurality of rigid body sections that move relative to each other by one or more multi-degree of freedom joints. The robotic apparatus can traverse a fixed frame by attaching its distal ends to the frame and moving the rigid body sections relative to each other.