There is provided a technique that includes: receiving type information corresponding to substrate processing; reading the type information and processing time information corresponding to the type information from a memory; calculating a ratio of a processing time of a predetermined process to a total time of the processing time information; selecting one or more reactors according to the ratio; setting the one or more reactors to be capable of performing the predetermined process; transferring a substrate corresponding to the type information to the one or more reactors; and performing the predetermined process corresponding to the type information in the one or more reactors.

An integrated robotic mechanism is disclosed for improving transport equipment, integrating an object movement with other functionalities such as alignment or identification. The disclosed integrated robot assembly can comprise a multiple end effector for moving a plurality of workpieces, a single end effector for moving a single workpiece, a rotation chuck incorporated on the robot body to provide alignment capability, and an optional identification subsystem for identify the object during transport. The present invention robot assembly can be used in a sorter or stocker equipment, in processing equipment, and a transfer system.

A glass sheet semiconductor deposition system (20) for coating semiconductor material on glass sheets is performed by conveying the glass sheets vertically suspended at upper extremities thereof by a pair of conveyors (38) through a housing (22) including a vacuum chamber (24). The glass sheets are conveyed on shuttles (42) through an entry load station (26) into the housing vacuum chamber (24), through a heating station (30) and at least one semiconductor deposition station (32, 34) in the housing (22), and to a cooling station (36) prior to exiting of the system through an exit load lock station (28). The semiconductor deposition station construction includes a deposition module (102) and a radiant heater (104) between which the vertical glass sheets are conveyed for the semiconductor deposition.

In a vacuum processing apparatus, a load lock module includes a housing and substrate holding sections, the housing having first substrate transfer ports formed on one of right and left sides thereof and a second substrate transfer port formed on a rear side thereof, and each substrate holding section being configured to hold a substrate on a right or left side in the housing. Further, a normal pressure transfer chamber extends over or under the housing from one of the right and left sides of the housing to the other one thereof so that each first substrate transfer port is opened. The normal pressure transfer chamber includes a stacked transfer region that is a region overlapping the housing. Further, a normal pressure transfer mechanism transfers the substrate between each substrate holding section and a transfer container carried into each of loading/unloading ports via the stacked transfer region.

A substrate processing system, which includes a transfer device configured to simultaneously transfer a plurality of substrates and suitably corrects positions of the substrate, and a method of controlling the substrate processing system are provided. The substrate processing system includes: a process chamber in which a plurality of substrates is processed; a vacuum transfer chamber connected to the process chamber; a transfer device provided in the vacuum transfer chamber and configured to simultaneously transfer a plurality of substrates; a module connected to the vacuum transfer chamber and having a plurality of stages on which substrates are placed; and a controller. The controller is configured to measure an amount of change of an arm of the transfer device that has transferred processed substrates, and to correct positions of the stages based on the amount of change of the arm of the transfer device.

Electronic device manufacturing systems, robot apparatus and associated methods are described. The systems, apparatus and methods are configured to efficiently retrieve and place substrates from N substrate supports (where N>2). The robot apparatus includes at least N end effectors plus one end effector (N+1) or plus two end effectors (N+2) enabling the robot to sequentially retrieve and place substrates within one or more process chambers during a single cycle (e.g., without having to return to a load lock or other location to place proceed substrates and retrieve unprocessed substrates).

A storage module includes a substrate support, a sensor, a rotating unit, a storage unit and an elevating unit. The substrate support has a consumable member thereon. The sensor detects an orientation of the consumable member. The rotating unit rotates the consumable member in a predetermined direction based on the orientation of the consumable member detected by the sensor. The storage unit is disposed below the substrate support to store the consumable member. The elevating unit vertically moves the storage unit.

Methods, systems, and apparatus for a substrate transfer method, including positioning a tray handler device in a first position with i) cutouts of an aperture of the first tray in superimposition with respective pedestals of a pedestal platform and ii) a distal end of the pedestals extending away from a top surface of the first tray; increasing a distance between the top surface of the first tray and a top surface of the pedestal platform to transfer a first substrate from the pedestals to the tabs defined by the aperture of the first tray, while concurrently engaging the second tray handler with the second tray; and increasing a distance between the top surface of the second tray and the bottom surface of a chuck to transfer a second substrate from the chuck to the tabs defined by the second tray.

Dual load lock chambers for use in a multi-chamber processing system are disclosed herein. In some embodiments, a dual load lock chamber, includes a first load lock chamber having a first interior volume and a first substrate support, wherein the first substrate support includes a first plurality of support surfaces vertically spaced apart by a first predetermined distance; at least one heat transfer device disposed within the first substrate support to heat or cool the first plurality of substrates; and a second load lock chamber disposed adjacent to the first load lock chamber and having a second interior volume and a second substrate support, wherein the second substrate support includes a second plurality of support surfaces vertically spaced apart by a second predetermined distance that less than the first predetermined distance.

A substrate transport apparatus including a transport chamber, a drive section, a robot arm having an end effector at a distal end configured to support a substrate and being connected to the drive section generating at least arm motion in a radial direction extending and retracting the arm, an imaging system with a camera mounted in a predetermined location to image at least part of the robot arm, and a controller connected to the imaging system to image the arm moving to a predetermined repeatable position, the controller effecting capture of a first image of the robot arm proximate to the repeatable position decoupled from encoder data of the drive axis, wherein the controller calculates a positional variance of the robot arm from comparison of the first image with a calibration image, and from the positional variance determines a motion compensation factor changing the extended position of the robot arm.