An automated gas supply system includes a gas cylinder transfer unit configured to transfer a cradle in which one or more gas cylinders storing a gas therein are stored; a gas cylinder inspection unit configured to check properties of the gas stored in the gas cylinder transferred from the gas cylinder transfer unit and check whether the gas leaks from the gas cylinder; a storage queue configured to receive the gas cylinder from the gas cylinder inspection unit by a mobile robot and configured to classify and store the transferred gas cylinders according to the properties of the gas stored in the gas cylinder; and a gas cabinet configured to receive the gas cylinder from the storage queue by the mobile robot and fasten a gas pipe, which is connected to a semiconductor manufacturing process line, to a gas spray nozzle, which is disposed at one side of the received gas cylinder, to supply the gas stored in the gas cylinder to the semiconductor manufacturing process line, wherein the gas cabinet includes a residual gas detector configured to detect a residual amount of the gas stored in the gas cylinder fastened to the gas pipe, and when the residual amount of the gas detected by the residual gas detector is less than or equal to a set residual amount of gas, the mobile robot recovers the gas cylinder from inside the gas cabinet and transfers a gas cylinder stored in the storage queue to the gas cabinet.

A system for conducting subterranean operations is disclosed and can include a tubular storage area, a well center area, and a robotic arm configured to move tubulars. The robotic arm can be coupled to a rig floor and configured to traverse a distance between the well center area toward the tubular storage area.

An operating device for placing or retrieving bottle-like piece goods onto or from storage places of a picking device is provided. The operating device includes a gripping jaw assembly having two profile-rod shaped gripping jaws with opposite lying inner surfaces extending in a first horizontal direction corresponding to a direction for placing and retrieving piece goods. The gripping jaws are configured so that the distance of the inner surfaces from each other tapers in the downward direction at least in sections and the bottle-like piece goods can be lifted from below. The operating device also includes an actuation unit coupled to the gripping jaw assembly for moving the gripping jaw assembly in the first horizontal direction.

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.

A jaw pivoting about an axis for clamping the shell, a lower end of the jaw receives the shell to allow closure. The notch intended to interfere with a catch of a cam to retain the jaw in the closed position. The cam is rigidly connected to a pivoting lever which allows the catch to be moved from the path of the notch to allow the jaw to open. The lever is to be pivotally activated through the force of an external component. The device includes a first and second spring each acting on the lever in an opposing manner, the second spring being stiffer than the first spring. The effect of the first spring is to lift the lever. The second spring counters the action of the first spring in order to delay the lifting of the lever and the catch when removing the component.

Various examples are directed to a container gripper assembly comprising a first jaw member and a second jaw member. The first jaw member may comprise a first plurality of pivotable inserts and the second jaw member may comprise a second plurality of pivotable inserts. The first jaw member may be movable towards the second jaw member to grip a container between the first plurality of pivotable inserts and the second plurality of pivotable inserts.

A gripper mechanism for gripping a load, the gripper mechanism including a body, a first actuator mechanism attached to the body and configured to linearly move a first gripping device; and a second actuator mechanism attached to the body and configured to rotate a second gripping device. A translation of the first gripping device and a rotation of the second gripping device result in gripping the load.

A robotic vehicle is provided with an extendable arm and a mandible structure. The mandible structure includes a pair of mandibles with toothed portions that cooperatively engage such that the mandibles may be opened and closed by applying a force to only one of the pair of mandibles. The mandible structure hangs freely from the extendable arm and is balanced so that the mandible structure naturally maintains a substantially vertical orientation. In the closed position, the mandible structure defines an interior cavity suitable for securely grasping a ring.

The present disclosure relates to a clamping device and a clamping robot having the same. The clamping device includes a body, a first driving member arranged on the body, and a first gripper assembly and a second gripper assembly which are arranged independently. The first driving member is drive-connected to the first gripper assembly and the second gripper assembly respectively so as to drive the first gripper assembly and the second gripper assembly to clamp an object separately. According to the solution provided in the present disclosure, the overall volume of the clamping device can be reduced and the scope of application of the clamping device can be expanded.

In one embodiment, a robotic end effector configured to mount to a robotic manipulator includes gripping elements configured to grasp objects, a drive mechanism configured to open and close the gripping elements, a central controller configured to control operation of the drive mechanism and the gripper elements, the central controller hosting a control program that enables control of the end effector independent of the robotic manipulator, and at least one of a forward-facing ultrasonic distance sensor configured to measure a distance between the gripping elements and an object to be grasped, and a forward-facing camera mounted between the gripping elements configured to capture video data of an object to be grasped.