A cell gripper, includes a housing and a grip assembly mounted in the housing. The grip assembly includes: a cell support in which a cell seating groove having an upper portion into which a cell is introduced to be seated is defined; a pair of pinion gears provided on both side surfaces of the cell support to convert vertical linear movement of the cell support into rotational movement; a pair of gear frames coupled to the pair of pinion gears, respectively, to transmit the rotational movement of the pinion gears; and a pair of cell fixing members provided on end portions of the pair of pinion gears, respectively, to press and fix the cell seated in the cell seating groove from both sides. A cell transfer device including the cell gripper is also provided.

In a finger mechanism and a robot hand having the finger mechanism, the finger mechanism uses a link based mechanism, and performs three degrees of freedom including two degrees of freedom of MCP joint and one degree of freedom of PIP join, via a driving part disposed at a side. The driving part is not disposed at each knuckle of the finger mechanism and additional sensors may be easily equipped, and thus modularized robot hand may be performed using the finger mechanism.

An intelligent garbage sorting robot includes a robot body and a walking base. The robot body is installed on the walking base, and a tool end of the robot body is installed with an executing mechanism. The executing mechanism includes a housing. An electromagnet is slidably disposed in the housing, the electromagnet is connected to a first driving assembly, the first driving assembly is configured to drive the electromagnet to slide, and an end of the housing is fixedly connected to multiple steel needles. Two mechanical claws symmetrically disposed on the walking base, and the two mechanical claws are spaced apart on the walking base. The two mechanical claws are respectively connected to second driving assemblies, and the second driving assemblies are configured to drive the two mechanical claws to move relatively.

Systems and methods of assembling a wrist assembly are provided. The wrist assembly includes a tension member, a first link, and a second link. The second link includes an assembly path, a guide path, and a retention pocket. A first end portion of the tension member is inserted through the assembly path within the second link. The tension member is configured to be rotated to transition the first tension member portion from the assembly path to be within the guide path. The retention member is retained within the retention pocket on a condition that the first tension member portion is rotated to be within the guide path such that movement of the tension member relative to the second link is limited. Movement of the first tension member portion within the second guide path urges the second link to rotate relative to the first link.

The present application provides a device for transferring a hub ground chain tray. An upper slider and a lower slider parallel to each other are arranged at the head end, a cylinder mounting plate is arranged below the upper and lower sliders, a cylinder is arranged below the cylinder mounting plate, a slider is arranged at the end of a piston rod of the cylinder, the left and right sides of the slider are provided with rotating pins, the two ends of the rotating pins can be installed in the strip through holes respectively in a sliding manner, and the two rotating pins are connected with the tail of the clamping jaw; the head of the clamping jaw is provided with jaw fingers, the jaw fingers are provided with the clamping blocks, and a transferrable tray device is arranged between the clamping blocks.

A gripping device with linear actuation for a robotic arm for seizing and gripping Petri dishes and other light items. The gripping device has a support and first and second gripping arms slidably retained relative to the support by guide rods. A motorized drive mechanism actuates the gripping arms through an operating member that acts only on the first gripping arm. Through an interconnection mechanism, movement of the first gripping arm actuates a simultaneous and dependent opposite movement of the second gripping arm so that the gripping arms are movable between a slack position and a clamping position. The operating member acts on the first gripping arm through a resiliently compressible member, the distortion of which is measured to provide a clamping limitation mechanism.

A low-friction medical device is provided having roller-assisted tension members and a friction-reducing curved guide path. The device includes a first link, a second link, and a tension member. A proximal end portion of the first link is coupled to an instrument shaft. A proximal end portion of the second link is rotatably coupled to a distal end portion of first link about a first axis. The second link defines a curved guide path and a cable extends from the first link through the curved guide path to a distal end of the second link and couples with a tool member. A roller having a roller surface is coupled to the second link such that the roller surface is aligned with a portion of the curved path and contacts the cable therein. The curved guide surface has a small fleet angle.

The present invention relates to an elastic corrugated pipe single-acting cylinder-driven mechanical gripper with a series-connection loose-leaf hinge framework. The mechanical gripper consists of a palm and two flexible fingers or a palm and three flexible fingers. The flexible fingers are identical in structure, and each one of the flexible fingers consists of an elastic corrugated pipe single-acting cylinder and a series-connection loose-leaf hinge. Each one of the series-connection loose-leaf hinges has a hinge mandrel equipped with a torsion spring, and the characteristic parameters and pre-tightening angle of the torsion spring are optimally designed according to the features of a grasped object. The mechanical gripper is driven by the elastic corrugated pipe single-acting cylinder to generate a grasping force. The mechanical gripper applies to the grasping of fragile brittle objects, or grasping of objects with varying shapes and dimensions.

Systems and methods are provided for facilitating the operations of an end effector that grasps objects such as baggage. One exemplary embodiment is a system that includes a finger of an end effector of a robot. The finger includes a finger base, a body that extends from the finger base, a first continuous friction belt having an exposed portion along a first side of the body, and a second continuous friction belt having an exposed portion along a second side of the body.

Disclosed is an elastic corrugated pipe single-acting cylinder-driven mechanical gripper with a series-connection flexible hinge framework. The mechanical gripper consists of a palm and two flexible fingers or a palm and three flexible fingers. Each of the flexible fingers is identical in structure, and essentially consists of an elastic corrugated pipe single-acting cylinder (8) and a series-connection flexible hinge (4); configuration of the series-connection flexible hinge (4) is designed according to features of grasping objects; the mechanical gripper generates a grasping force by the elastic corrugated pipe single-acting cylinder (8). The mechanical gripper applies to the grasping of fragile, brittle objects or oddly-shaped objects varying with shapes and dimensions, belonging to the technical field of robots and mechatronics application; when coupled to a robot body, the mechanical gripper is especially suitable for the production and logistic fields for grasping, sorting and packing of foods, agriculture products and light industrial products.