An example robotic device includes a mobile base and a base linkage. The base linkage has a first end and a second end where the first end is connected to the mobile base. The robotic device also includes a first end effector connected to the second end of the base linkage. The first end effector includes a shovel tool. The robotic device additionally includes an actuated control arm having a first end and a second end. The first end of the actuated control arm is connected to the second end of the base linkage. The robotic device further includes a second end effector connected to the second end of the actuated control arm. The second end effector includes a sweeping tool. The actuated control arm is configured to move the sweeping tool to engage with the shovel tool to sweep one or more objects onto the shovel tool.

A robot for transferring a wafer is disclosed. A blade of the robot includes a first sensor on an upper surface of the blade and the second sensor on a back surface of the blade. The first sensor is operable to align the blade with a wafer. The second sensor is operable to align the blade with a holder that holds the wafer.

A block transfer apparatus for transferring a block between an upstream and downstream clamps of a block delivery system. The apparatus includes: a frame pivotally mounted to a support; a clamping assembly mounted to the frame and linearly extendable relative thereto, and including a pair of gripper jaws for clamping opposing sides of the block. The apparatus receives a block in the gripper jaws in an approximate position; rotates to a drop position and releases the block allowing it to self-datum onto first and second orthogonal datum surfaces. The apparatus re-clamps the block after the drop by applying a clamping force to opposing sides of the block to register the block against a third datum surface to thereby datum the position of the block with respect to the clamping assembly; and presents the block clamped in the datumed position for transfer to the downstream clamp.

A method for retrieving an inventory item based on a handling robot, where the handling robot includes: a storage frame; and a material handling device installed on the storage frame, and including a telescopic arm and a manipulator installed to the telescopic arm; and the method for retrieving an inventory item includes: driving, by the telescopic arm, the manipulator to extend to a preset position of warehouse shelf along a preset horizontal reference line; loading, by the manipulator that is remained on the reference line, the inventory item located in the preset position; driving, by the telescopic arm, the manipulator loaded with the inventory item to move to the storage frame along the reference line; and unloading, by the manipulator that is remained on the reference line, the inventory item to the storage frame.

Automated, environmentally monitored and controlled storage units and systems for storing, monitoring, and maintaining a supply of products, particularly temperature sensitive pharmaceutical and/or other high-value products, be they temperature sensitive or not. Such automated storage units contain an array of independently addressable holding locations for containers with product in one or more environmentally monitored (e.g., for temperature, humidity, etc.) and controlled zones fitted with appropriate environmental sensors. In preferred embodiments, the automated storage units also include a reader to track product information and status. Product loading, retrieval, and movement within such automated storage units is performed by a computer-controlled robot. A user interface device, preferably in communication with an application service provider to provide remotely managed inventory management and other services, provides users with inventory- and product-specific information.

A system and associated method for palletizing fluid filled flexible packages. The system includes a platform, a distance sensor, a robotic arm palletizer and a controller. The platform is configured and arranged with a support surface for supporting a fluid filled flexible package. The distance sensor is disposed above the support surface of the platform and faces downward towards the support surface for taking distance readings. The robotic arm palletizer is operable for palletizing fluid filled flexible packages according to a preprogrammed stacking protocol that includes a drop-off height dimension. The controller is in electrical communication with the distance sensor and the robotic arm for establishing or adjusting the drop-off height dimension based upon distance readings from the distance sensor.

Provided is a die lift system comprising an end effector capable of lifting and manipulating a die, creating a safe and efficient way to do so free off all physical exertion by the worker associated with the lifting and maneuvering of the die; the end effector having the ability to engage a die; the end effector having at least one series of tines capable of grasping the die; the end effector having the ability to be securely coupled to the die; and the end effector having the ability to disengage from the die.

Manufacturing cell based vehicle manufacturing systems and methods for a wide variety of vehicles are disclosed. In one aspect, a manufacturing cell configured for assembling a frame of a vehicle is disclosed. The manufacturing cell includes a positioner, a robot carrier and a robot. The positioner is configured to receive a fixture table configured to hold the frame. The robot carrier includes a vertical lift. The robot is configured to assemble the frame. The positioner is configured to support the frame in a vertical position during an assembling process. In another aspect of the disclosure, a system for manufacturing a vehicle based on a manufacturing cell is disclosed. In another aspect of the disclosure, a method for manufacturing a vehicle based on a manufacturing cell is disclosed.

Disclosed are systems and methods for aseptically filling pharmaceutical containers with a pharmaceutical substance and then lyophilizing it. In one general aspect, the system and method can employ a lyophilizer loader subsystem having an interior chamber in communication with an interior chamber of a lyophilizer subsystem via a portal with a sealable door, with the collective interior being aseptically sealable. An articulated robotic arm can be employed to batch transfer to the lyophilizer subsystem container nests bearing the pharmaceutical containers. In one embodiment, the nests may be transferred serially to the loader subsystem, with the articulated robotic arm being configured to transfer the nests of containers in batches to the lyophilizer subsystem. The articulated robotic arm can also be configured to be used to move batches of nests within the lyophilizer subsystem. One implementation includes two articulated arms and a joint rotary wrist driven by two rotary shoulders.

A robot includes first and second arms to rotate and convey an object; a first rotary body to support the first arm and having a first fluid passage and at least one second fluid passage communicating with the first fluid passage; a base-end-side arm formed with an internal space and a hole part into which a part of the first rotary body is inserted; a second rotary body to support the second arm and having a third fluid passage communicating at one end thereof with the second fluid passage and communicating at the other end thereof with the internal space; a supplying device disposed in the internal space and connected to an upstream-end side of the first fluid passage, and to supply fluid to the first fluid passage; a first motor to rotate the first rotary body; and a second motor to rotate the second rotary body.