A finger mechanism for a robot, an artificial hand, and the like, wherein a fourth bone member (14) of the bone members of the finger mechanism and corresponding to the distal phalanx comprises: a support portion (15) that is rotatably coupled to a third bone member corresponding to the middle phalanx by a rotational shaft (g5); and a nail portion (16). The nail portion (16) can freely rotate about a shaft (g7) at a right angle or a near right angle to the rotational shaft (g5), and a return mechanism (17) to return the rotated nail portion (16) to a reference position is provided between the support portion (15) and the nail portion (16). In this manner, in response to the amount of force applied to the fourth bone member (14), it is possible for only the nail portion (16) to rotate in a direction to easily grasp an object to be held.

An end effector (400) for a robotic arm, the end effector (400) comprising: two pipe engaging jaws (404), each jaw comprising an inner contour configured for engaging a pipe section, wherein at least one jaw (404) is a fixed jaw; wherein the end effector (400) is configured to restrict radial movement of the pipe section while permitting axial movement.

A system and method for gripping a cylindrical object. The system including: a housing; a plurality of gripping arms in the housing, the gripping arms in pairs each on an opposite side of a centerline plane from another; and a driving wedge in the housing and configured such that movement of the driving wedge moves each pair of gripping arms towards or away from each other while remaining equidistant from the centerline plane. The method including: opening the plurality of gripping arms against a bias by sliding a wedge in a first direction to slide the plurality of gripping arms apart while maintaining an equal predetermined distance from a part alignment position; placing a cylindrical body between the plurality of gripping arms; and closing the plurality of gripping arms by sliding the wedge in an opposite direction to allow the biasing force to close the gripping arms.

A gripper assembly includes a base having a hollow area extending in a first direction, at least three grippers arranged along a circumference of the base, the at least three grippers configured to be rotatable about respective rotational axes extending in the first direction, and a first power transmitter configured to rotate the at least three grippers at the same time in a first rotational direction about the respective rotational axes.

Systems and methods for clearing a top drive from an operational area of the mast such that operations may be performed along the rail without interference from the top drive. Systems and methods of the present disclosure provide for arranging the top drive in a parked configuration outside of, or generally behind, the mast. A guide rail may be arranged within an operational area of a mast and may have a pair of interchangeable rail sections, each of which may be configured for arrangement in either an operating configuration, where the rail section may be positioned within the operational area of the mast to form part of the rail, or a parked configuration, where the rail section may be positioned outside of the operational area. Each interchangeable rail section may be pivotable about an axis and may be arranged on a pivotable gate of the mast.

An apparatus and assembly of a modular bearing device for a pair of gripper arms in a mirror-inverted configuration seated on a support plate for the gripping, holding and guiding of bottle-like containers. The gripper arms are movable from a gripping position into an open position and vice versa by means of a rotatably mounted cam control shaft, each gripper arm having a bearing pin for the pivotal supporting the respective gripping arm and a base plate with a receiving opening running through it for the pivotal supporting of the cam control shaft, wherein the bearing pins are fixed to one side of the base plate, and releasably fastening at least one of the gripper arms on the support plate. With the objective of quick and easy dismantling/assembling, the bearing device is characterized in that the first bearing pin or the second bearing pin is designed as a sleeve for receiving the fastening, the through-hole of which aligns with a receiving opening in the base plate in the axial direction of the sleeve.

A clamping device for holding a container in a container handling device, for example for holding a beverage container by a neck portion, includes a first clamping arm arranged on a support plate pivotably about a first pivot shaft and having a holding portion for contact against the container to be held, and a second clamping arm arranged on the support plate pivotably about a second pivot shaft and having a holding portion for contact against the container to be held. The first pivot shaft and the second pivot shaft respectively have a cylinder pin portion for forming a form closure, radially to the longitudinal direction of the pivot shaft, with a bore in a support of a container handling device.

A gripping device includes carriages or pivot arms carrying gripping elements. The carriages or pivot arms are mounted and guided in a base body and are drivable by at least one cylinder-piston unit. A switching module is mounted on the base body. The switching module includes at least one pressure medium connection and at least one electrical connection. At least one electrically controllable valve, which is switching a pressure medium, and at least one electronic controller for implementing external and internal control signals are arranged in the control module. The internal control signals originate from at least one sensor which detects at least one physical characteristic variable of the carriage(s) and/or the cylinder-piston unit at least in or on the base body. The gripping device can be adapted to at least one machine control system with a minimum interconnection and programming effort.

A gripping system includes a gripping device and a pitch adjustment device. The gripping device has a row of grippers arranged in a first direction and adapted to grip a row of contacts and a support frame on which at least two adjacent grippers of the row of grippers are slidably attached. The pitch adjustment device is adapted to drive the at least two adjacent grippers to slide in the first direction to adjust a pitch between the two adjacent grippers.

A modular gripper has a body with a trident section and cylindrical section. A powering assembly is positioned in the cylindrical section. A pair of oppositing jaws is pivotally secured between a center wall and a pair of side wall, respectively, of the trident section. The clevis cam driver with piston rod moves a cam assembly on the centre wall slot. The cam assembly passes through a body having a trident section and cylindrical section. The trident section comprises a trident structure that includes, at one end, a pair of side walls along with a center wall. The cylindrical section includes a fluid driven powering assembly. A pair of opposing jaw member are pivotally secured to the trident portion about separate pivot pins. A cam assembly is operatively connected to a piston rod of the fluid driven powering assembly. The cam assembly extends laterally outward with respect to a cylinder bore axis to receive a cam bush that engages with a through slot on each of the pair of opposing jaw members. The jaws rotate with respect to one another in response to fluid power in the cylindrical section. A pair of side plate members, each slide plate member has an elongated blind slot that receives an end of the cam assembly, the ends travel in the blind slot. Cam slots in the pair of opposing jaws, via a cam bushing.