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 picking device for storing bottles and a corresponding method are provided. The picking device includes a storage locations for bottles, a control device and an operating device having a gripper with two prongs, the operating device displaceable adjacent the storage location in first and second directions. The control device causes the operating device to lift a bottle from the storage location and move the bottle in a third direction away from the storage location by one of a frictional connection and a positive connection between the bottle and the two prongs or move a bottle in a third direction towards the storage location and lower the bottle to rest in the storage location by one of a frictional connection and a positive connection between the bottle and the two prongs. A method for retrieving bottles and an operating device for use with a picking device are also provided.

A conveying device includes a first drive body, a second drive body and a lifting body for receiving a payload. The drive bodies can be activated independently of each other along a conveying axis or on a conveying plane. A first lifting link is pivotably articulated to the first drive body and a second lifting link is pivotably articulated to the second drive body. The lifting links are functionally connected to the lifting body so that a relative movement of the drive bodies can be converted into a movement of the lifting body along a lifting axis A first guide link is pivotably articulated to the first drive body, a second guide link is pivotably articulated to the second drive body, the guide links are connected to a first guide element, the lifting body has a second guide element, and the guide elements form a linear guide with a guide axis that coincides with the lifting axis.

A wire gripper (1) includes a second link arm (7B), a connection member (27), a stationary-side wire gripping portion (9), and a moveable-side wire gripping portion (11). The second link arm (7B) is rotatably connected by a main body (5). The connection member (27) is connected to the second link arm (7B). The moveable-side wire gripping portion (11) is movable in a direction approaching or being spaced from the stationary-side wire gripping portion (9) in conjunction with movement of the connection member (27). The wire gripper (1) includes a ratchet mechanism (47) that blocks rotation of the operation lever (41) in conjunction with rotation of the second link arm (7B) in one direction and allows reverse rotation in the other direction. The ratchet mechanism (47) blocks rotation, so that movement of the moveable-side wire gripping portion (11) in a direction being spaced from the stationary-side wire gripping portion (9).

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.

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, and 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.

An automatic CD processing facility includes a mechanical gripper used for clamping a CD, storage cabinets located on side faces of the mechanical gripper and used for storing CDs, and a CD driver array cabinet located in front of or/and behind the mechanical gripper and used for processing the CDs. the CDs are placed in the storage cabinets and then are transferred by the mechanical gripper into the CD driver array cabinet to be processed, and after being processed, the CDs are taken out of the CD driver array cabinet to be placed back into the storage cabinets by the mechanical gripper. The automatic CD processing facility is high in automation degree, replaces traditional manual operation to take and place CDs, and improves processing efficiency.

Various example embodiments described herein relate to an item manipulation system including a control system and a robotic arm coupled to the control system. The item manipulation system includes an end effector communicatively coupled to the control system and defines a first end and a second end. The first end of the end effector is rotatably engaged to the robotic arm. The item manipulation system also includes a gripper unit attached to the second end of the end effector. The gripper unit is configured to grip the item. The gripper unit includes at least one flexible suction cup and at least one rigid gripper. Each of the flexible suction cup and the at least one rigid gripper engage a surface of the item based on vacuum suction force generated through the at least one flexible suction cup or the at least one rigid gripper.

A substrate transfer hand is configured to sandwich a substrate between a plurality of receiving members and a gripping member and to fix the substrate by moving the gripping member with an actuator. The plurality of receiving members each have a flat plate-shaped support portion mounted on the main hand body, a substrate outer periphery holding portion supported on the support portion and configured to hold an outer periphery of the substrate, and a substrate lower surface holding portion supported on the support portion and configured to hold a lower surface of the substrate. The substrate outer periphery holding portion has a portion provided vertically from the support portion and configured to hold the substrate in contact with the outer periphery of the substrate. The substrate lower surface holding portion has a portion inclined from an outer peripheral side toward an inner side of the substrate to be held. The substrate outer periphery holding portion and the substrate lower surface holding portion are spaced from each other by a gap or a groove.

A cutting device includes a base plate, a motor attached to the base plate, a driving cord including a first end and a second end, the first end being attached to the motor, and a cutting assembly. The cutting assembly includes a fixed blade that is fixed to the base plate, and a driven blade that moves with respect to the fixed blade. The second end of the driving cord is attached to the driven blade to move the driven blade with respect to the fixed blade when the motor rotates.