A gripper tooling includes: a gripper having a gripper body and an angular jaw; a rotor fixedly connected to the angular jaw; and a tooling member for gripping a workpiece, the tooling member including: a base pivotally connected to the rotor; a middle segment pivotally connected to the base; a distal segment pivotally connected to the middle segment; an adducting tendon having a proximal end attached to the rotor and a distal end attached to the distal segment, the rotor for rotating relative to the base and thereby for tensioning the adducting tendon; and an abducting tendon having a proximal end attached to the base and a distal end attached to the distal segment such that the tooling member can autonomously grip the workpiece as the angular jaw rotates toward the workpiece and the tooling member autonomously returns to an ungripped position as the angular jaw rotates away from workpiece.

A soft gripper including tentacles, each tentacle includes lower and upper members connected by a connector. Each member includes guide discs, and each guide disc includes a ring with passthrough holes, and a spacer located in a donut hole of the ring with passthrough holes, the passthrough holes collectively define cable pathways. The connector includes a center thru-hole and transfer channels. Cables have proximal ends attached to actuators and extend through apertures of a baseplate located at a proximal end of the lower member. A set of lower cables extend through the lower ring passthrough holes to couple to a distal lower guide disc. A set of upper cables extend through the lower spacer passthrough holes, through the transfer channels to the upper ring passthrough holes to couple to a distal upper guide ring, and an end cap is attached to the distal end of the upper member.

A soft gripper including tentacles, each tentacle includes lower and upper members connected by a connector. Each member includes guide discs, and each guide disc includes a ring with passthrough holes, and a spacer located in a donut hole of the ring with passthrough holes, the passthrough holes collectively define cable pathways. The connector includes a center thru-hole and transfer channels. Cables have proximal ends attached to actuators and extend through apertures of a baseplate located at a proximal end of the lower member. A set of lower cables extend through the lower ring passthrough holes to couple to a distal lower guide disc. A set of upper cables extend through the lower spacer passthrough holes, through the transfer channels to the upper ring passthrough holes to couple to a distal upper guide ring, and an end cap is attached to the distal end of the upper member.

A gripping tool (2), a system, a clamping unit (35) and a method of handling objects (6), where the gripping tool (2) comprises a transmission mechanism arranged in a housing (7), wherein the transmission mechanism is coupled to a plurality of arms (11) located outside the housing (7). The arms (11) extend in a radial plane from a first end (15) to a second end (16), where one or more gripping fingers (12) are arranged on each arm (11). The gripping fingers (12) may be repositioned on the arm (11), or multiple gripping fingers (12) may be arranged on the same arm (11). The arm (11) preferably has a bent or curved profile where the bending line or curvature is facing a central longitudinal axis (A) of the housing (7).

A gripping tool (2), a system, a clamping unit (35) and a method of handling objects (6), where the gripping tool (2) comprises a transmission mechanism arranged in a housing (7), wherein the transmission mechanism is coupled to a plurality of arms (11) located outside the housing (7). The arms (11) extend in a radial plane from a first end (15) to a second end (16), where one or more gripping fingers (12) are arranged on each arm (11). The gripping fingers (12) may be repositioned on the arm (11), or multiple gripping fingers (12) may be arranged on the same arm (11). The arm (11) preferably has a bent or curved profile where the bending line or curvature is facing a central longitudinal axis (A) of the housing (7).

A robot tendon system having a robot arm having an exterior surface, and further rigid elements, each of which is moveably attached to the robot arm or to another of the further rigid elements. Further, a tendon retaining element defines a set of closed channels, and has a major exterior surface that is attached to the major surface of the robot arm. Finally, tendons extend through the closed channels and are attached to the rigid elements.

A robot tendon system having a robot arm having an exterior surface, and further rigid elements, each of which is moveably attached to the robot arm or to another of the further rigid elements. Further, a tendon retaining element defines a set of closed channels, and has a major exterior surface that is attached to the major surface of the robot arm. Finally, tendons extend through the closed channels and are attached to the rigid elements.

A robot hand apparatus includes a base, three finger mechanisms, a thumb mechanism, and three motors for the three finger mechanisms. The base corresponds to a part of the hand of a human, i.e. a palm and dorsum of a human. Each of three finger mechanisms is elongated in almost the same direction from the end of the base and is adapted to be actuated by the motor. The thumb mechanism is elongated from the different portion from the base. The thumb mechanism and the finger mechanism close to the thumb mechanism are configured to define a U-shape space.

An automatic removal system for a reservoir cap is provided. The system includes a removal robot including a polyarticular robot arm, a finger that is installed at an end of the robot arm to move forwards and backwards through a cylinder and grips or releases the reservoir cap, a rotary motor that rotates the finger, and a gripping mechanism equipped with a detection sensor that monitors a front; and a controller recognizing the reservoir cap installed in a reservoir inlet or a reservoir through a detection sensor, controlling the robot arm to move the gripping mechanism to a recognition point, and controlling the cylinder, the finger, and the rotary motor to attach or detach the reservoir cap to or from the reservoir inlet.

An automatic removal system for a reservoir cap is provided. The system includes a removal robot including a polyarticular robot arm, a finger that is installed at an end of the robot arm to move forwards and backwards through a cylinder and grips or releases the reservoir cap, a rotary motor that rotates the finger, and a gripping mechanism equipped with a detection sensor that monitors a front; and a controller recognizing the reservoir cap installed in a reservoir inlet or a reservoir through a detection sensor, controlling the robot arm to move the gripping mechanism to a recognition point, and controlling the cylinder, the finger, and the rotary motor to attach or detach the reservoir cap to or from the reservoir inlet.