Abstract: A system for transporting articles. The transport system includes a conveyor system which includes a transport carrier for carrying one or more articles between workstations and a drive rail and a support rail for supporting the transport carrier. The drive rail includes a drive system for propelling the transport carrier between workstations. At least one shoe carried by the transport carrier rides on the support rail for movably supporting the transport carrier on the support rail. The transport system may also includes a protective container including a housing having an interior compartment for supporting one or more articles. The bottom surface of the housing is configured to engage the drive system such that actuation of the drive system propels the housing along the drive and support rails. At least one shoe carried by the housing is configured to ride on the support rail of the conveyor system to movably support the housing on the support rail.

Abstract: An apparatus for preventing improper engagement of a pod door and a pod. Specifically, misalignment of at least one latch finger connected t the pod door with latch engagement slots in the pod prevents a pod door from mechanically engaging a pod.

Abstract: A wafer transport mechanism is disclosed capable of transferring workpiece cassettes between lot boxes and SMIF pods. The transport mechanism includes a frame having a first support platform on a first side of the frame for supporting a SMIF pod, and a second support platform on a second side of the frame for supporting a lot box. The frame further includes a carrier transfer mechanism which resides completely within the frame when in a home position. The transfer mechanism includes an arm and a gripper pivotally mounted to the arm. Once a SMIF pod and lot box are seated on their respective support platforms, the transfer mechanism transfers a cassette between the two containers.

Abstract: A SMIF pod capable of supporting a cassette at points in the pod located directly over or near a kinematic coupling between the pod and a surface on which the pod is supported. Even if the pod shell warps or otherwise deforms, the three points of contact between the pod and the support surface at the kinematic couplings will always remain at a fixed, controllable and repeatable position. The present invention makes use of this fact by supporting the cassette at or near the three kinematic coupling points. Moreover, the support structure is not affixed to the top or sides of the pod shell. Thus, the position of the cassette, and wafers supported therein, will similarly remain at a fixed, controllable and repeatable position, substantially unaffected by any pod shell deformation which may occur.

Abstract: A reticle transfer system is disclosed for transferring reticles between a reticle-carrying SMIF container and a process tool. The reticle transfer system according to the present invention includes an arm assembly having a transfer arm and a gripping mechanism affixed to the end of the transfer arm. Once the container carrying the reticle has been opened, the gripping mechanism is rotated and translated to a position adjacent the reticle so that it may access the reticle and transfer it into the minienvironment through an access port in the minienvironment. In order to precisely, easily and repeatedly position the gripping mechanism in the desired location to grip and transfer the reticle, the gripping mechanism includes four downwardly extending posts spaced apart from each other so as to contact an outer rim of the container door as the gripping mechanism is lowered into position to grip and transfer the reticle.

Abstract: A SMIF pod capable of supporting a cassette at points in the pod located directly over or near a kinematic coupling between the pod and a surface on which the pod is supported. Even if the pod shell warps or otherwise deforms, the three points of contact between the pod and the support surface at the kinematic couplings will always remain at a fixed, controllable and repeatable position. The present invention makes use of this fact by supporting the cassette at or near the three kinematic coupling points. Moreover, the support structure is not affixed to the top or sides of the pod shell. Thus, the position of the cassette, and wafers supported therein, will similarly remain at a fixed, controllable and repeatable position, substantially unaffected by any pod shell deformation which may occur.

Abstract: An ergonomic loading assembly for an I/O port onto which a bare cassette may be easily loaded and unloaded. The loading assembly further provides isolation between the operator and the I/O port after loading of a cassette to minimize safety risks and to minimize the amount of particulates and contaminants around the workpieces while on the port. In a preferred embodiment, the loading assembly includes a cover assembly having a stationary cover section around the port plate, and two pivoting cover sections which open and close like jaws to allow a cassette to positioned within the cover assembly when opened and which enclose the cassette within the cover assembly when closed. The loading assembly further includes a pivoting deck onto which the cassette is loaded when the pivoting cover sections are open. The deck receives the cassette with the workpieces oriented at or near vertical.

Abstract: A director assembly for selectively directing a transport carrier from one conveyor path portion to another. The director assembly having a pair of spaced director rails positioned below and in between drive and support rails of the conveyor. The pair of spaced director rails can be selectively raised and rotated and then lowered to direct the carrier to the new path portion.

Abstract: A system for positioning an end effector of a wafer handling robot with respect to a wafer to be extracted from a cassette, and for thereafter reading an indicial mark on the wafer. The system includes a pair of sensor units fixedly mounted on the end effector, which sensor units are capable of detecting the wafer edge upon approach of the end effector toward the wafer. Based on the positions of the end effector when the first and then the second sensor units detect the edge of the wafer, a computer may determine the orientation of the end effector with respect to the wafer, and adjust a position of the end effector to a center of the wafer. Thereafter, the indicial mark on the wafer may be read by a camera by withdrawing the wafer from the cassette on the end effector, positioning the center of the wafer over the central axis of rotation of the wafer handling robot, and rotating the robot until the indicial mark is located under the camera.

Abstract: A system for transporting articles. The transport system includes a conveyor system which includes a transport device for carrying articles between workstations and a drive rail and a support rail for supporting the transport device. The drive rail includes a drive system for propelling the transport device between workstations. At least one shoe carried by the transport device rides on the support rail for movably supporting the transport device on the support rail. The transport system also includes a protective container including a housing having an interior compartment for supporting a plurality of articles. The bottom surface of the housing is configured to engage the drive system such that actuation of the drive system propels the housing along the drive and support rails. At least one shoe carried by the housing is configured to ride on the support rail of the conveyor system to movably support the housing on the support rail.

Abstract: A system for transporting articles. The transport system includes a conveyor system which includes a transport device for carrying articles between workstations and a drive rail and a support rail for supporting the transport device. The drive rail includes a drive system for propelling the transport device between workstations. At least one shoe carried by the transport device rides on the support rail for movably supporting the transport device on the support rail. The transport system also includes a protective container including a housing having an interior compartment for supporting a plurality of articles. The bottom surface of the housing is configured to engage the drive system such that actuation of the drive system propels the housing along the drive and support rails. At least one shoe carried by the housing is configured to ride on the support rail of the conveyor system to movably support the housing on the support rail.

Abstract: A system is described herein including a load port which allows various pod sizes, including 200 mm and 300 mm, add various configurations, including front opening and bottom opening, to operate with a BOLTS interface, or simply with a vertical port on the front end of a process tool in configurations not including the BOLTS interface.

Abstract: A wafer mapping system is disclosed mounted to the port door of a process tool. As the port door is lowered away from the access port of the process tool in order to allow wafer transfer through the port, the wafer mapping system according to the present invention detects the presence and position of the various wafers in the pod shell, which information may then be stored in memory for later use. As such, wafer mapping according to this system occurs without additional processing steps or time. The port door is lowered by a servo drive which allows the precise position of the port door to be identified at any given time. As such, the position of a wafer within the pod shell may be precisely identified by the wafer mapping system mounted on the port door as the door is lowered.

Abstract: A tilt and go assembly included as part of a load port interface assembly is disclosed for providing quick and easy attachment and adjustment of the load port interface assembly to a BOLTS interface. When a load port interface assembly according to the present invention is positioned adjacent to a BOLTS interface, the assembly is tilted away from the BOLTS interface, so that a socket in the load port interface assembly may raise upward slightly and be seated on the ball joint. Thereafter, the upper portions of the load port interface assembly may be tilted upward so that the assembly is roughly parallel and adjacent to the BOLTS interface. Once the load port interface assembly is seated on the ball joint of the BOLTS interface, the vertical and lateral positions of the load port interface assembly may be adjusted as desired with respect to the BOLTS interface.

Abstract: A universal interface and transfer apparatus is disclosed which may be configured either as an indexer or a load port opener. In each configuration, the universal interface and transfer apparatus includes a port plate having a central opening, and a port door fitting within and sealing the central opening when no pod is present on the apparatus. The apparatus further includes a base and a frame mounted on and extending up from a front of the base. A modular drive assembly is mounted within an exterior side of the frame, which drive assembly includes a linear drive screw, and a motor and torque transmission mechanism for rotating the linear drive screw. A carriage is mounted on the linear drive screw such that rotation of the linear drive screw results in vertical translation of the carriage.

Abstract: A system for providing uniform, controlled and efficient purge gas flow rates and gas flow patterns for removing contaminants and/or particulates from wafers within a pod. The purge system includes seals at the interfaces between the gas inlet and removal lines to substantially prevent leakage at the interfaces. The system may establish seals at the inlet and outlet without having to use conventional fluid flow pins extending above the support surface. The negative pressure applied at the outlet controls the flow rate through the pod, and the rate at which gas leaves the pod will limit the rate at which gas may enter the pod. In a preferred embodiment, the inlet flow is approximately equal to the outlet flow. With substantially equal inlet and outlet pressures, the purging gas flows through the upper and lower portions of the pod in a substantially uniform flow pattern so that contaminants and particulates are removed evenly from wafers throughout the pod.

Abstract: A rotating and translating support assembly for receiving a front-opening pod according to applicable SEMI standards, and thereafter rotating the pod to a desired orientation. In this way, a number of pods may be received at interface ports of a minienvironment, and each of the pods and ports may be angled toward and aligned with a single, 2-arm pick and place robot. In a preferred embodiment of the present invention, the rotating and translating support assembly comprises a plate rotationally and translationally mounted on a shelf extending from the minienvironment adjacent to a front-opening interface port. In one embodiment, the support plate may be mounted on a shaft attached to a rotating assembly, such as for example a worm and drive gear. The rotating assembly may in turn be mounted on a translating assembly, such as for example a carriage riding on a lead screw.

Abstract: A method and apparatus for removing a semiconductor wafer cassette from a SMIF pod and for transferring the cassette along a vertical axis to a platform of a wafer processing station. The apparatus is comprised of a transfer device that includes a pair of gripping arms for gripping the wafer cassette from the sides of the cassette. Once gripped, the cassette moves with the transfer device upward along a vertical axis to make room for the platform to be extended from within the processing station to a position under the cassette. Thereafter, the direction of motion of the transfer device is reversed and the cassette is lowered onto the platform. Once seated on the platform, the gripping arms retract from the cassette, and the cassette is carried on the platform into the processing station.

Abstract: A transportable container for storing and carrying articles such as semiconductor wafers or flat panel display substrates which is adapted for horizontal loading and unloading. The container includes a box and a box door. The box door can be sealably attached to the box to isolate the interior of the box from ambient atmospheric conditions. The container is adapted to mate with a port of a canopy which encloses a semiconductor processing apparatus.

Abstract: A method and apparatus for dry cleaning a semiconductor wafer storage and transport pod. After the pod is located with respect to the cleaning chamber and opened to expose the interior surfaces of the pod to the cleaning chamber, the pod is conditioned in preparation for the cleaning process. The conditioning of the pod includes purging the pod and cleaning chamber with an ionized nitrogen gas to rid the pod and cleaning chamber of airborne contaminants and to neutralize static electrical charges on the pod surfaces. The conditioning process further includes heating the pod surfaces to prevent condensation of moisture and organic contaminants thereon. After the conditioning process, the pod is cleaned with a dry aerosol sprayed onto the pod surfaces. The aerosol spray is comprised of an ionized carbon dioxide/nitrogen (CO.sub.2 /N.sub.2) gas and fine particles of CO.sub.2.