The present invention relates to an electric gripper driven by a motor, and more particularly to a detachable and detachable modular gripper for universal use enhanced in universality and increased in easiness of maintenance and repair by forming a gripper in a plurality of modules. the gripper including a housing mounted with a gripping unit for gripping a work, and a front module attachable and detachable to the housing as a separate part, wherein the front module includes at least one of a robot server interface inputting a first signal to or outputting the first signal from an external device,

a driving module controller inputting a second signal or an electric power to, or outputting the second signal or the electric power from a driving module, and a sensor interface part inputting or outputting a third signal of a sensor detecting an operation state of the gripping unit, and the gripper further including a gripping unit, a housing mounted with a gripping unit, wherein the gripping unit includes a gripping module gripping the work, and a driving module providing a driving force to the gripping module, and one of the gripping module and the driving module is attachably and detachably provided on the housing.

A gripper structure is disclosed and includes a screw-rod main body, a first rotatory nut, a second rotatory nut, a first driving module, a second driving module, a first clamping element and a second clamping element. The first rotatory nut and the second rotatory nut are disposed on two sides of the screw-rod main extended along a first direction body, respectively, and bilaterally symmetrical to each other. The first driving module and the second driving module are configured to drive the first rotatory nut and the second rotatory nut to rotate, respectively. The first rotatory nut and the second rotatory nut are allowed to pass through a midline of the screw-rod main body. When the first driving module drives the first rotatory nut or/and the second driving module drives the second rotatory nut, the first clamping element and the second clamping element are relatively displaced in the first direction to achieve a clamping operation.

The present disclosure relates to a gripper and a robot. The gripper according to the present disclosure includes at least three guiding rails arranged head to tail in sequence, at least three gripping fingers respectively disposed on the at least three guiding rails and a driving mechanism. A first end of each of the gripping fingers is slidably connected to the corresponding guiding rail and a second end of each of the gripping fingers is for contacting the object to be gripped. The driving mechanism drives each of the gripping fingers to move along the corresponding guiding rail, so that the second end of each of the gripping fingers moves toward or away from a gripping center of the gripper.

A vehicle wheel positioning device, including a frame, a jacking cylinder and two sliding sleeves fixed on a bottom plate, the outputting end of the jacking cylinder is connected with a top plate, and a belt pulley connected to a servo motor via a shaft. A vehicle wheel may be positioned via the top plate during a vehicle wheel finish turning automation processing, without switching programs for automation production of the wheel with different wheel widths and different offset distances.

A surgical tool includes a tool shaft, and end effector and a wrist that couples the end effector to the tool shaft. The tool includes a drive mechanism configured to effect movement of one or both of the wrist and the end effector in yaw and pitch via independent actuation of four independent cable ends of two or more independent cables that extend between the drive mechanism and the wrist.

An integrated multiaxial wrist and grasper system for use in a robotic tool can yaw, pitch and grasp via actuation of four independent cable ends of four cables. The tool includes a drive mechanism that effects movement of the multiaxial wrist and grasper via actuation of the cables that extend between the drive mechanism and the wrist.

The gripper assembly includes a base, a guide situated on the base, and first and second jaws members. First and second ball bearing slides are associated with the jaw members for mounting the jaw members for movement along a guide track between proximate and remote positions. First and second low friction pneumatic actuators are provided. A mechanical linkage connects the actuators to at least one of the jaw members. A pulley and wire rope assembly connects the first and second jaw members for simultaneous movement in opposite directions. Valves are provided for actuating one actuator at a time. Actuation of the first actuator causes simultaneous movement of the jaw members in one direction. Actuation of the second actuator causes simultaneous movement of the jaw members in opposite directions.

Embodiments of the present disclosure generally relate to a fixture, a robotic fixture including the same, and a method for clamping the turnover box. A fixture comprising: an corner fixture assembly configured to support the turnover box at the top corner of the turnover box; a drive mechanism including a first drive rail and a second drive rail; a first side fixture assembly movable along the first drive rail and a second side fixture assembly movable along the second drive rail, the first side fixture assembly and the second side fixture assembly configured to support the turnover box at a side wall of the turnover box adjacent the top corner, respectively. Embodiments of the present disclosure provide a fixture with an asymmetric clamp combination with structural simplicity, self-indication capability, and clamp stability.