A robot gripper includes a main gripper body that has a connection flange designed to secure the rotational gripper to a tool flange of a robotic arm; a base element that is mounted on the main gripper body such that it can rotate about a first rotational axis by a first rotational joint able to be adjusted automatically by a first drive motor; a first gripper finger mounted such that it can rotate about a second rotational axis aligned parallel to the first rotational axis, relative to the base element, by a second rotational joint which can be adjusted automatically by a second drive motor; and at least one additional gripper finger. The second rotational joint is configured to adjust the first gripper finger individually, using the second drive motor, independently of the at least one additional gripper finger.

A gripper assembly for gripping a portion of a container may include a spindle configured to rotate about a vertical axis. The assembly may also include an actuating plate disposed on or about the spindle. The actuating plate may be configured to actuate toward a central shaft in response to a force applied to a first cam follower. The assembly may also include a gripper configured to at least one of open and close in response to the actuating plate being actuated toward the central shaft and a locking cam configured to contact the first cam follower and in at least one position to limit movement of the actuating plate toward the central shaft.

Provided is a gripping portion structure of a gravure plate-making robot in which the accurate gripping of an unprocessed plate-making roll and the positioning accuracy during transfer of the unprocessed plate-making roll to each processing device can be improved by causing a gravure plate-making robot to exhibit a high gripping force when gripping the unprocessed plate-making roll. The gripping portion structure of a gravure plate-making robot to be used in a fully automatic gravure plate-making processing system for manufacturing a gravure plate-making roll by gripping and transferring an unprocessed plate-making roll to each processing device includes: a pair of gripping plates to be mounted on an arm distal end of the gravure plate-making robot, the pair of gripping plates being freely spaced widely or narrowly from each other, and being configured to grip both end portions of the unprocessed plate-making roll; and a gripping surface forming member provided on each of the pair of gripping plates, the gripping surface forming member having a gripping surface that is curved so as to be recessed toward a center of the end portion of the unprocessed plate-making roll to be gripped and having a non-slip function.

A multi-zone end effector assembly is described in the present disclosure. As a non-limiting example, the multi-zone end effector assembly comprises a manifold that comprises a first interior chamber and a second interior chamber. A first port connects to the first interior chamber, and a second port connects to the second interior chamber. A first compression cup region can be connected to the first interior chamber. The first compression cup region is in air connection with the first port. The first compression cup region is configured to be independently activated in order to create a first vacuum zone. A second compression cup region is connected to the second interior chamber. The second compression region cup is in air connection with the second port. The second compression cup region is configured to be independently activated in order to create a second vacuum zone.

A gripping mechanism includes a holder, a gripping roller, and a downward pushing section. The holder houses the gripping roller. The downward pushing section pushes downward on an object gripped between the holder and the gripping roller. Preferably, the downward pushing section has a first downward pushing mechanism, a second downward pushing mechanism, and a third downward pushing mechanism. The first downward pushing mechanism protrudes from a ceiling surface among inner surfaces of the holder. The second downward pushing mechanism and the third downward pushing mechanism protrude from respective surfaces opposite to the object among outer surfaces of the holder.

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

A picking device for storing bottles and a corresponding method are provided. The picking device includes a plurality of storage locations for bottles, an operating device having a gripper, at least one storing device, at least one identification device and an unloading device. The storage locations have storage location receptacles and the storing device has at least one storing receptacle for bottles, wherein the storage location receptacles and the storing receptacle are configured such that the bottles are held therein in such a way that they are protected against rolling. The gripper includes a gripping member configured such that the bottles are movable from the storing receptacles and storage location receptacles by being lifted by the gripping member or by being pulled to a holding area of the gripper.

In accordance with an embodiment, the invention provides an end effector for use with a programmable motion device. The end effector includes a pair of mutually opposing surfaces, at least one of the pair of mutually opposing surfaces being movable with respect to an end effector support structure for supporting the at least one of the pair of mutually opposing surfaces.

A device for automatically hand-swaying beverage cups is disclosed, comprising a robotic arm and a cover, wherein the robotic arm has a plurality of movable arms and a plurality of joints that pivotally connect each of the movable arms to each other, and at the extreme end of such movable arms there install a pair of symmetrical clamping components and a clamping controller, and also includes a host computer electrically connected to each of the movable arms, each of the joints and the clamping controller, respectively; in addition, the cover respectively has a conical surface on the outside, an inner hole is openly configured on the bottom surface of the cover, and each of the clamping components can collectively clamp the cover and the cup thus facilitating the hand-swaying operations of the cup by means of the robotic arm.

An artificial epidermis structure capable of using a gel substance to adjust a frictional property with high precision is provided. When a front surface of a lid member comes into contact with a target object and pressure acts on the lid member, a part of the gel substance can escape into a space that is formed by concave portions on a front surface of a gel substance. Therefore, reduction in a repulsion force of the gel substance is achieved. Accordingly, the pressure can be appropriately transmitted to the gel substance via the lid member, and convex portions of the gel substance can be caused to easily bulge out over the front surface of the lid member via holes of the lid member.