A package sort cell includes a robot with an end of arm tool for transporting packages from an in-feed conveyor to a selected one of a plurality of out-feed conveyors or bins, the robot receiving instruction from the package reader as to which of the plurality of conveyors or bins to hand-off the package. An end of arm tool may be in the configuration of a conveyor which may be aligned with the out-feed conveyor on a bottom up movement. The end of arm tool may also be in the configuration of a hanging carriage frame suspending a conveyor in a top down movement. A worker platform may be provided which may be movable between in-use and out-of-use positions whereby upon robot downtime, the platform may move into the in-use position for a worker to temporarily takeover the transfer functions of the robot. A plurality of sort cells may be arranged in side by side relation adjacent a like plurality of package delivery points (e.g., truck bays) and include diverter conveyors to allow diversion of a selected quantity of packages from one cell to an adjacent cell when the adjacent cell has no associated package delivery occurring at that time.

An automated manufacturing system that is flexible and scalable based on the needs of a manufacturing facility is provided. The manufacturing system includes one or more modular manufacturing units that are connected in series via a transport system. The modular manufacturing unit includes a base frame including a plurality of support members that are coupled to one or more feet; a main frame mounted on the base frame; a pair of opposed gantry support arms mounted on the main frame in a transverse direction, each gantry support arm including a rail; at least one gantry assembly slidably mounted across the rails of the gantry support arms in a longitudinal direction, each gantry assembly configured for performing a selected function or operation; and a transport system for conveying a device part through the modular manufacturing unit along the longitudinal direction for processing.

The present disclosure reduces deviation in the position and inclination of a stage due to the deformation of a processing container. A vacuum processing apparatus includes a processing container configured to be capable of maintaining an inside thereof in a vacuum atmosphere, a stage provided in the processing container such that a substrate is placed thereon, a support member passing through a hole in the bottom of the processing container to support the stage from the bottom side, a base member engaged with an end portion of the support member located outside the processing container to be movable integrally with the stage, and a plurality of actuators provided in parallel with each other between the bottom of the processing container and the base member and configured to adjust a position and an inclination of the stage by moving the base member relative to the bottom of the processing container.

The present disclosure reduces deviation in the position and inclination of a stage due to the deformation of a processing container. A vacuum processing apparatus includes a processing container configured to be capable of maintaining an inside thereof in a vacuum atmosphere, a stage provided in the processing container such that a substrate is placed thereon, a support member passing through a hole in the bottom of the processing container to support the stage from the bottom side, a base member engaged with an end portion of the support member located outside the processing container to be movable integrally with the stage, and a plurality of actuators provided in parallel with each other between the bottom of the processing container and the base member and configured to adjust a position and an inclination of the stage by moving the base member relative to the bottom of the processing container.

Provided is a robot system. The robot system includes a manipulator configured to perform a preset operation on a plurality of objects, a transparent cover configured to define a chamber in which the plurality of objects and the manipulator are accommodated, the transparent cover being provided with a touch panel, a camera installed to face an internal region of the chamber, a projector configured to emit light to one area within the chamber, and a controller configured to control the projector so that the projector emits the light to a target area corresponding to a touch point of the touch panel, recognize a target object disposed in the target area based on image information of the camera, and control the manipulator so that an operation is performed on the target object.

A next generation painting robot with advanced fluid delivery system, enhanced kinematics and a service airlock compartment. The painting robot includes a fluid delivery system which places color changing valves and pumping hardware on the back side of the robot's mounting pedestal, where it can be serviced without a technician having to enter the spray booth. The fluid delivery system also allows smaller and lighter robot arms, and is designed to minimize paint waste and wait time during color changes. The robot also features kinematics providing redundant inner arm rotation. The arm kinematics, along with the smaller arms, a paint supply line routed through the center of first and third arm joints, and optimized motor conductor routing, dramatically improve near reach flexibility. The improved near reach flexibility in turn allows a smaller spray booth than possible with previous robot architectures.

A next generation painting robot with advanced fluid delivery system, enhanced kinematics and a service airlock compartment. The painting robot includes a fluid delivery system which places color changing valves and pumping hardware on the back side of the robot's mounting pedestal, where it can be serviced without a technician having to enter the spray booth. The fluid delivery system also allows smaller and lighter robot arms, and is designed to minimize paint waste and wait time during color changes. The robot also features kinematics providing redundant inner arm rotation. The arm kinematics, along with the smaller arms, a paint supply line routed through the center of first and third arm joints, and optimized motor conductor routing, dramatically improve near reach flexibility. The improved near reach flexibility in turn allows a smaller spray booth than possible with previous robot architectures.

A containerized robotic system is disclosed. The containerized robotic system includes a base having a first attachment area configured to securely mount a robot and a second attachment area configured to securely mount a compressor, the base further including a set of one or more channels to provide an electrical connection to supply power to the robot and the compressor, respectively, and to provide compressed air from the compressor to the robot, a detachable superstructure configured to be removably connected to the base to define an enclosed space of sufficient size to accommodate at least the robot and the compressor, and a power distribution unit secured to the base and coupled to receive electrical power as input and to provide electrical power to the robot and the compressor via the set of one or more channels.

A containerized robotic system is disclosed. The containerized robotic system includes a base having a first attachment area configured to securely mount a robot and a second attachment area configured to securely mount a compressor, the base further including a set of one or more channels to provide an electrical connection to supply power to the robot and the compressor, respectively, and to provide compressed air from the compressor to the robot, a detachable superstructure configured to be removably connected to the base to define an enclosed space of sufficient size to accommodate at least the robot and the compressor, and a power distribution unit secured to the base and coupled to receive electrical power as input and to provide electrical power to the robot and the compressor via the set of one or more channels.

The present invention relates to a compact cell Z having a protective enclosure 3 for welding operations by means of welding robots 15, having a protective enclosure 3 consisting of a roof 1, side walls 2, a front side 4A and a rear side 4B, said protective enclosure 3 being movable from a first position into a second and back again by a guide rail 23 supported on a pneumatically actuable guide device 24, and as a result being able to enclose a front working area A1 in the first position and a rear working area A2 in the second position, respectively. The front side 4A and rear side 4B of the protective enclosure 3 furthermore comprise at least in each case one roller shutter device (22A; 22B) which can open and close roller shutters (5A; 5B) that close the entire side or modularly combinable roller shutters (18; 20) on respective roller shutter mounts (V1; V2; V3) integrated in the roof 1.