Disclosed are mechanical interfaces of an end-of-arm-tool (EOAT) and part-gripping devices. The EOAT mechanical interface is for operatively coupling a gripper actuator to the part-gripping device. The part-gripping device mechanical interface is matable to the EOAT mechanical interface for operatively coupling the EOAT to the part-gripping device. Among other improvements, also disclosed are improved gripper fingers.

A robot hand includes a motor with a rotary shaft, an accommodating member accommodating a distal end of the rotary shaft, a plurality of swing members swinging with respect to the accommodating member due to rotation of the rotary shaft, and a plurality of claw members swinging with the plurality of swing members.

A robot hand for gripping and operating a pipette, the robot hand including: an electric gripper; a pair of first finger members opened and closed by the electric gripper; a pair of second finger members provided on the first finger member and having a pipette gripping surface; and an operating mechanism installed on the first finger member to operate an operation target of the pipette.

Exemplary embodiments relate to improvements in robotic systems to reduce biological or chemical harborage points on the systems. For example, in exemplary embodiments, robotic actuators, hubs, or entire robotic systems may be configured to allow crevices along joints or near fasteners to be reduced or eliminated, hard corners to be replaced with rounded edges, certain components or harborage points to be eliminated, shapes to be reconfigured to be smoother or flat, and/or or surfaces to be reconfigurable for simpler cleaning.

A gripping apparatus which has a base body (5) and a plurality of gripping arms (18) arranged on the base body (5) so as to be distributed about a center axis (4). The gripping arms (18) can be driven to carry out a gripping arm pivoting movement (22) in order to grip or release an object. All of the gripping arms (18) are integrated into a gripping unit (11) which is separate from the base body (5) and which has a fastening sleeve (15) to which the gripping arms (18) are fastened and which is axially placed on the base body (5) by means of a sleeve-shaped fastening portion (62), assuming a usage position. The gripping unit (11) is detachably fixed in the usage position by means of a securing device (78).

A gripping device for gripping a workpiece includes: at least one gripping element configured for contacting the workpiece, the at least one gripping element including a shaft; at least one articulating finger jaw; a mounting block connecting the shaft to the at least one articulating finger jaw, the mounting block including an articulation stop having a first stopping surface and a second stopping surface; and a stopping member connected to the shaft, the stopping member being configured for contacting one of the first stopping surface and the second stopping surface to limit a rotation of the shaft relative to the mounting block, the stopping member being in the form of a fastener which is inelastic.

A gripping device for gripping a workpiece. The gripping device includes at least one gripping element configured for contacting the workpiece, at least one articulating finger jaw, and a mounting block connecting the shaft of the at least one gripping element to the at least one articulating finger jaw. The mounting block includes an articulation stop having a first stopping surface and a second stopping surface. The gripping device further includes a stopping member connected to the shaft. The stopping member is configured for contacting one of the first stopping surface and the second stopping surface to limit a rotation of the shaft relative to the mounting block. The stopping member is in the form of one of a pin and a fastener.

Toolable modules, each having a set of functions and capabilities which are configurable to function cooperatively, to create a set of Robotic arms. Each finger of the module enables a specific task to be accomplished, providing multiple degrees of movements, enabling the Robotic arms to be deployed in highly precise applications and capable of responding to complex tasks. In coordination with an imaging system and a control system the functionality of the Robotic arms are programmable, scalable and configurable in addition to being able to communicate with the external interfaces in a predetermined protocol, thereby providing “Plug and Play” functionality.

Provided are a system, method(s), and apparatus for automatically harvesting mushrooms from a mushroom bed. The system, in one implementation, may be referred to herein as an “automated harvester”, having at least an apparatus/frame/body/structure for supporting and positioning the harvester on a mushroom bed, a vision system for scanning and identifying mushrooms in the mushroom bed, a picking system for harvesting the mushrooms from the bed, and a control system for directing the picking system according to data acquired by the vision system. Various other components, sub-systems, and connected systems may also be integrated into or coupled to the automated harvester.

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.