A gripper includes at least one movable finger. Each movable finger includes a first motor, a second motor, a first motor link having a first end coupled to a rotor of the first motor, a second motor link having a first end coupled to a rotor of the second motor, a finger link having a first end in pivotal connection with a second end of the second motor link and a gripper pad, and a connecting link having a first end in pivotal connection with a second end of the first motor link and a second end in pivotal connection with the finger link. The gripper further includes at least one controller programmed or configured to actuate the first motor and the second motor of each of the at least one movable finger.

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

A finger assembly of a robot hand includes a main frame, a tip portion rotatably connected to the main frame, and a band portion connected to the tip portion.

A mechanical finger for a mechanical hand, has: a proximal phalanx pivotably mountable to a support of the mechanical hand to pivot relative to the support about a finger pivot axis; a distal phalanx pivotably connected to the proximal phalanx via a first living hinge to pivot relative to the proximal phalanx about a first pivot axis; and a skeleton member pivotably connected at one end to the distal phalanx via a second living hinge to pivot relative to the distal phalanx about a second pivot axis offset from the first pivot axis and at another end operatively connected to an actuator of the mechanical hand to be selectively movable by the actuator to pivot the distal phalanx relative to the proximal phalanx and to pivot the distal phalanx relative to the support when the finger is in use.

A soft robot hand includes a palm, a first fabric-reinforced textile actuator coupled to the palm, and a second fabric-reinforced textile actuator coupled to the palm. The first actuator is moveable relative to the palm between a collapsed position and an inflated position to approximate a joint in a first human finger. The second actuator is spaced apart from the first actuator. The second actuator is moveable relative to the palm between a collapsed position and an inflated position to approximate a joint in a second human finger.

A three-rotational-degree-of-freedom connection mechanism required for a robot that can make motion similar to a human has a simple structure, and there is no restriction on motion within a movable range. The three-rotational-degree-of-freedom connection mechanism includes a joint connecting a second member rotatably to a first member with three rotational degrees of freedom including rotation around a torsion axis, three actuators each including variable length links having a variable length, and power sources for generating force changing the lengths of variable length links and three first-member-side link attaching units provided in first member and the second-member-side link attaching units provided on the second member such that variable length links having a twisted relationship with respect to a torsion axis exist in each state within a movable range of joint.

A device forming a robotic hand, including a base forming a hand palm, at least two articulated structures each forming a robotic finger, each articulated structure being connected to the base by at least one articulation, at least one drive mechanism for each articulation, at least one actuator arranged to actuate the at least one drive mechanism by means of at least one flexible drive link connecting and driving the at least one drive mechanism, structure for measuring the pivoting of the at least one actuator and one or more of the articulations, a glove covering the base and the at least two articulated structures, the glove being closed so as to form, inside the glove, a volume filled with oil between the wall of the glove and the base and the at least two articulated structures. Robotic hands used in aquatic environments at great depths are also disclosed.

A technique for actuating a robotic apparatus is disclosed. In one particular embodiment, the technique may be realized as an apparatus for providing controlled movement of a robotic appendage, comprising a digit, wherein the digit comprises a first joint and a second joint, and an actuator configured to control a degree of freedom of the digit. The actuator causes the first joint to bend at a first rate from a first position to a second position and the second joint to bend at a second rate from a third position to a fourth position. The first rate is faster than the second rate.

A mechanical finger has a base. A proximal phalanx and a distal phalanx is provided with a first epicyclic joint between the base and proximal phalanx, and a second epicyclic joint between the proximal phalanx and the distal phalanx. A distal four-bar mechanism includes the proximal phalanx, the distal four-bar mechanism coupled to the distal phalanx. A nail is optionally provided and has a joint mechanism movably connecting the nail to the distal most one of the phalanges between a stowed position in which a grasping tip of the nail is concealed in the distal most one of the phalanges, and a deployed configuration in which the grasping tip projects out of the distal most one of the phalanges.

A flexible robot end effector includes the end effector including a mounting assembly and a flexible finger, one end of the flexible finger configured to mount at one side of the mounting assembly; the flexible finger including a protective layer and a plurality of holding mechanisms; the flexible finger further including a base, and two opposite sides of the base respectively connected with the holding mechanism and a pneumatic device; the protective layer configured to be sleeved on both outsides of the holding mechanism and the base so that an airtight chamber is formed among the base, the holding mechanism and the protective layer; when the air is blown into the airtight chamber by the pneumatic device, the flexible fingers inflated, and a gap between the two adjacent holding mechanisms gradually increasing.