A transfer robot assembly arranged within an ATV transfer module includes a transfer robot that includes an end effector and one or more arm segments connected between the end effector and a transfer robot platform. A first robot alignment arm is connected to the transfer robot platform. A second robot alignment arm is connected to the first robot alignment arm and to a mounting chassis of the ATV transfer module. The transfer robot assembly is configured to actuate the first robot alignment arm and the second robot alignment arm to raise and lower the transfer robot to adjust a position of the transfer robot in a vertical direction and in a horizontal direction. The transfer robot is configured to fold into a folded configuration having a narrow profile occupying less than 50% of an overall depth of the ATV transfer module.

The present invention provides a method for plasma dicing a substrate. The method comprising providing a process chamber having a wall; providing a plasma source adjacent to the wall of the process chamber; providing a work piece support within the process chamber; placing the substrate onto a support film on a frame to form a work piece work piece; loading the work piece onto the work piece support; providing a cover ring disposed above the work piece; generating a plasma through the plasma source; and etching the work piece through the generated plasma.

Disclosed is a substrate transporting device including a transport mechanism, a transport chamber, a first exhaust fan, and a controller. The transport mechanism is movable in parallel in a given direction. The transport chamber includes a first wall disposed on a first side of the given direction of the transport mechanism, and a plurality of transportation ports each used for moving the substrate between an exterior and an interior of the transport chamber. The first exhaust fan is disposed closer to the first wall than any of the transportation ports, and exhausts gas in the transport chamber outside the transport chamber. The controller performs control such that, when the transport mechanism moves toward the first wall in a first proximal area whose distance from the first wall is of a given value or less, an exhaust amount of the first exhaust fan is larger than that when the transport mechanism moves toward the first wall out of the first proximal area.

The present invention provides a method for plasma dicing a substrate. The method comprising providing a process chamber having a wall; providing a plasma source adjacent to the wall of the process chamber; providing a work piece support within the process chamber; placing the substrate onto a support film on a frame to form a work piece work piece; loading the work piece onto the work piece support; providing a cover ring disposed above the work piece; generating a plasma through the plasma source; and etching the work piece through the generated plasma.

A wafer transfer apparatus is provided. In a minimum transformed state where a robot arm is transformed such that a distance defined from a pivot axis to an arm portion, which is farthest in a radial direction relative to the pivot axis, is minimum, a minimum rotation radius R, is set to exceed of a length B in the forward and backward directions of an interface space, the length B corresponding to a length between the front wall and the rear wall of the interface space forming portion, and is further set to be equal to or less than a subtracted value obtained by subtracting a distance L0 in the forward and backward directions from the rear wall of the interface space forming portion to the pivot axis, from the length B in the forward and backward directions of the interface space (i.e., B/2<RBL0).

Disclosed is a substrate transporting device including a transport mechanism, a transport chamber, a first exhaust fan, and a controller. The transport mechanism is movable in parallel in a given direction. The transport chamber includes a first wall disposed on a first side of the given direction of the transport mechanism, and a plurality of transportation ports each used for moving the substrate between an exterior and an interior of the transport chamber. The first exhaust fan is disposed closer to the first wall than any of the transportation ports, and exhausts gas in the transport chamber outside the transport chamber. The controller performs control such that, when the transport mechanism moves toward the first wall in a first proximal area whose distance from the first wall is of a given value or less, an exhaust amount of the first exhaust fan is larger than that when the transport mechanism moves toward the first wall out of the first proximal area.

Modular wafer transport and handling facilities are combined in a variety of ways deliver greater levels of flexibility, utility, efficiency, and functionality in a vacuum semiconductor processing system. Various processing and other modules may be interconnected with tunnel-and-cart transportation systems to extend the distance and versatility of the vacuum environment. Other improvements such as bypass thermal adjusters, buffering aligners, batch processing, multifunction modules, low particle vents, cluster processing cells, and the like are incorporated to expand functionality and improve processing efficiency.

A substrate transport apparatus is provided. The apparatus has a casing and a door. The casing is adapted to form a controlled environment therein. The casing has supports therein for holding at least one substrate in the casing. The casing defines a substrate transfer opening through which a substrate transport system accesses the substrate in the casing. The door is connected to the casing for closing the substrate transfer opening in the casing. The casing has structure forming a fast swap element allowing replacement of the substrate from the apparatus with another substrate without retraction of the substrate transport system and independent of substrate loading in the casing.

A load lock is provided for a semiconductor substrate processing system having a transport robot mounted therein. The load lock transport supplies substrates directly to a processing chamber without the need for a central transport robot. The load lock transport is a dual element robot designed for minimum clearance and space and operates within a matching load lock chamber of minimum volume.

A wafer transfer apparatus is provided. In a minimum transformed state where a robot arm is transformed such that a distance defined from a pivot axis to an arm portion, which is farthest in a radial direction relative to the pivot axis, is minimum, a minimum rotation radius R, is set to exceed of a length B in the forward and backward directions of an interface space, the length B corresponding to a length between the front wall and the rear wall of the interface space forming portion, and is further set to be equal to or less than a subtracted value obtained by subtracting a distance L0 in the forward and backward directions from the rear wall of the interface space forming portion to the pivot axis, from the length B in the forward and backward directions of the interface space (i.e., B/2<RBL0).