The invention relates to a gripping device (10) for gripping, translationally moving, and rotating a laboratory vessel (40) for samples, microorganisms, cell cultures, or the like, comprising a support unit (12), a bearing body (14), and a gripper (16) that is rotatably mounted in the bearing body (14). The gripper (16) has a rotating body (34), in which gripping fingers (36, 38) are arranged, at least one of which is pivotably mounted in the rotating body (34). The rotating body (34) interacts with a rotary drive (30) for the rotational movement relative to the bearing body (14). The bearing body (14) is mounted in the support unit (12) in a translationally movable manner and interacts with a movement drive for the translational movement of the bearing body (14) with the rotating body with respect to the support unit (12). The gripping fingers (36, 38) interact with a gripping finger drive (50, 52, 54) for pivoting at least one gripping finger (36, 38) relative to the rotating body (34) from an open position into a gripping position, and vice versa. At least one first part of the gripping finger drive (50, 52, 54) for pivoting the gripping finger (36, 36) is arranged outside the rotating body (34), and a second part of the gripping finger drive (34a) is arranged in the rotating body (34). Only in the gripping position can the first part of the gripping finger drive (50, 52, 54) be connected to the second part of the gripping finger drive (52), otherwise, the two parts of the gripping finger drive (50, 52, 54) are separated from one another.

A robotic gripping device includes a base part attached to a tip of a wrist of a robot; finger parts, at least one of which is movably supported on the base part so that the finger parts can move toward and away from each other; and a driving mechanism that drives the finger parts. In at least one of the finger parts, flexibility of at least a gripping surface is switchable.

An automatic pick-up equipment adapted to pick up components having different shapes includes a base mounted on a manipulator of a robot, a first pick-up device mounted on the base and including a pair of first gripping mechanisms opposite to each other, and a second pick-up device mounted on the base and including a pair of second gripping mechanisms opposite to each other and a rotation mechanism. The first gripping mechanisms are configured to linearly reciprocate relative to each other to grip a first component. The second gripping mechanisms are configured to pivotally reciprocate relative to each other to grip a second component. The rotation mechanism is configured to drive the second gripping mechanisms to rotate relative to the base to change a posture of the second component.

A robotic surgical tool includes a drive housing having a lead screw extending from a first end of the drive housing, a carriage movably mounted to the lead screw at a carriage nut secured to the carriage, and an elongate shaft extending from the carriage and penetrating the first end, the shaft having an end effector arranged at a distal end thereof and comprising a proximal shaft portion releasably coupled to a distal shaft portion at a releasable interface. Proximal and distal portions of one or more mechanisms of the surgical tool extend from the carriage to the end effector within the proximal and distal shaft portions, respectively, and the one or more mechanisms are operable to operate or articulate the end effector.

A robotic surgical tool includes a drive housing having opposing first and second ends, a carriage arranged within the drive housing, a shaft extending from the carriage, a firing rod extending within the shaft and defining external threads, an end effector arranged at an end of the shaft and including a knife coupled to the firing rod such that movement of the firing rod moves the knife, and an activating mechanism coupled to the carriage. The activating mechanism including a motor mounted to the carriage and operable to rotate a drive gear, and a driven gear engageable with the drive gear such that rotation of the drive gear rotates the driven gear and actuates the activating mechanism. The driven gear defines internal threads and is rotatably mounted to the firing rod at the external threads such that rotation of the driven gear longitudinally moves the firing rod and the knife.

The present disclosure relates to a gripping apparatus mounted to a robot arm for controllably placing an object on a surface. A gripper assembly supports a pair of gripping clamps which are configured to grip and release the object. The gripper assembly is mounted to the robot arm via a connector body. A sensor is configured to either measure a relative movement between the gripper assembly and the connector body, or to measure a force between the gripper assembly and the connector body. A controller is configured to stop the robot arm when the sensor indicates the measured relative movement or measured force exceeds a predefined threshold.

A gripper for a transport system of a picking device having horizontal storage surfaces for storing and dispensing small piece goods of different shapes and/or surface properties is provided. The gripper comprises a drop table extending in first and a second horizontal directions and having a storage and dispensing end face. Two elongated gripping jaws are arranged above the drop table extending in the first horizontal direction, and are fastened to a gripping jaw guide arrangement. At least one of the gripping jaws is movable in the second horizontal direction and at least one of the gripping jaws has a gripper coupler in its end portion facing away from the gripping jaw guide arrangement, and at least one transport attachment with an attachment coupler. The gripper and attachment couplers interact so that a transport attachment is releasably fixed at an end portion of a gripping jaw.

A hand includes a pair of finger members disposed separated by an interval and relatively movable in an interval direction, a finger drive unit that moves at least one of the finger members in the interval direction, a pair of holding pads that are provided on the respective finger members, and are supported to face each other and to be rotatable around an axis extending in the interval direction, and a pressing member that is provided to be movable in a direction intersecting a radial direction, at a position separated from the axis in the radial direction, and presses a surface of a workpiece held between the holding pads.

A telescoping extendable boom and a foldable telescoping extendable boom for transporting an item, are disclosed. The foldable telescoping extendable boom having tubular elements (12) and (14) and (15, 17, 18, 19) and (20) each arranged with a longitudinally extending track (25, 29) inside the tubular element. Each longitudinally extending track (25, 29) supports a single shuttle (26) and (30) respectively, internally inside its tubular element (17) and (15), respectively, for movement therealong. Each shuttle (26) and (30) is equipped with a clamp (27) and (30) to selectively clamp the item (298). The longitudinally extending tracks (25, 29) of immediately connecting telescoping tubular elements (17) and (15) are located opposite each other. The inner tubular elements inside said telescoping extendable boom are arranged at their near ends to allow their shuttles to access shuttles of outer tubular elements to enable the clamps (27) and (31) thereof to transfer a said item (298) therebetween.

A gripping device includes a rotating member having a pinion and rotating about a center axis of the pinion, a drive piezoelectric unit having a vibrating portion that vibrates with expansion and contraction of a piezoelectric material, and a convex portion provided in the vibrating portion, being in contact with the rotating member, and transmitting vibration of the vibrating portion to the rotating member, a rack meshing with the pinion and moving with rotation of the pinion, and a gripping part coupled to the rack, wherein a contact portion in which the convex portion and the rotating member are in contact is located outside of an outer circumference of the pinion in a plan view from a direction of a rotation axis of the rotating member.