Abstract: A system and method of transporting substrates includes a loadport system including a frame, an articulating arm, a mini environment and a tower substantially centered in the frame. The tower includes multiple motors, a first motor mechanically coupled to the mini environment for moving the mini environment vertically. A second motors mechanically coupled to the articulating arm for moving the articulating arm vertically. A tower enclosure is also included. The tower enclosure enclosing the motors separate from the mini environment.

Abstract: A workpiece container storage and handling system includes a base, a number of wheels connected to the base, and a container handling system connected to the base. The wheels provide for movement of the base. The container handling system is defined to hold at least two containers in a vertically overlying orientation relative to each other. The container handling system is defined to provide for controlled vertical travel of the at least two containers in unison relative to the base. Also, the container handling system is defined to provide for controlled and independent horizontal travel of each of the at least two containers relative to the base.

Abstract: A spiral cam has a tubular shaped portion defined by an interior cavity and an exterior surface that includes a cam contour. A linear slide assembly having a length defined along a rotational axis is defined to slide lengthwise into the interior cavity of the spiral cam. The linear slide assembly allows for movement of the spiral cam along the rotational axis and prevents rotation of the spiral cam relative to the linear slide assembly. A cam roller is fixed at a position proximate to the exterior surface of the spiral cam. The cam roller is disposed separate from the linear slide assembly and within the cam contour of the spiral cam. The cam roller engages the cam contour to move of the spiral cam along the rotational axis when the linear slide assembly and spiral cam are rotated in unison about the rotational axis relative to the cam roller.

Abstract: The present invention is a wafer transfer system that transports individual wafers between chambers within an isolated environment. In one embodiment, a wafer is transported by a wafer shuttle that travel within a transport enclosure. The interior of the transport enclosure is isolated from the atmospheric conditions of the surrounding wafer fabrication facility. Thus, an individual wafer may be transported throughout the wafer fabrication facility without having to maintain a clean room environment for the entire facility. The wafer shuttle may be propelled by various technologies, such as, but not limited to, magnetic levitation or air bearings. The wafer shuttle may also transport more than one wafer simultaneously. The interior of the transport enclosure may also be under vacuum, gas-filled, or subject to filtered air.

Abstract: An end effector having a first arm and a second arm extending from an end effector support body is provided. The first arm and the second arm each have support extensions for supporting a peripheral region of a substrate on opposing sides of a diameter of the substrate. The height of support contacts on opposing sides of the diameter is different relative to a horizontal datum plane. In one embodiment, the end effector includes additional arms extending from the end effector support body. A system for supporting a substrate is provided also.

Abstract: The present invention comprises a workpiece container for storing at least one workpiece having a bottom surface and a peripheral edge. In one embodiment, a workpiece support structure is located within the container enclosure, which forms multiple vertically stacked storage shelves within the enclosure. Each storage shelf includes, in one embodiment, a first tine and a second tine for supporting the workpiece in a substantially horizontal orientation. The bottom surface and peripheral edge of a workpiece seated on a storage shelf extends beyond the outer edge of both the first tine and the second tine. An end effector according to the present invention may engage these extended portions or “grip zones” of the workpiece.

Abstract: A loadport has a port door and a frame with an opening through which the port door interfaces with a container door of a container for holding semiconductor workpieces. In one embodiment, a movable closure mechanism is connected to the port door and is defined to be movable in a controlled manner relative to both the port door and the frame. In this embodiment, a stationary closure mechanism is disposed on the frame proximate to the opening. In another embodiment, a stationary closure mechanism is connected to the port door, and a movable closure mechanism is disposed on the frame proximate to the opening. In both embodiments, the movable closure mechanism is defined to engage with the stationary closure mechanism such that movement of the movable closure mechanism to engage with the stationary closure mechanism applies a closing force between the port door and the container door.

Abstract: The present invention is a wafer transfer system that transports individual wafers between chambers within an isolated environment. In one embodiment, a wafer is transported by a wafer shuttle that travel within a transport enclosure. The interior of the transport enclosure is isolated from the atmospheric conditions of the surrounding wafer fabrication facility. Thus, an individual wafer may be transported throughout the wafer fabrication facility without having to maintain a clean room environment for the entire facility. The wafer shuttle may be propelled by various technologies, such as, but not limited to, magnetic levitation or air bearings. The wafer shuttle may also transport more than one wafer simultaneously. The interior of the transport enclosure may also be under vacuum, gas-filled, or subject to filtered air.

Abstract: A storage system and methods for operating a storage system are disclosed. The storage system includes a storage system assembly positioned at a height that is greater than a height of a tool used for loading and unloading substrates to be processed. The storage system locally stores one or more containers of substrates. The storage system assembly includes a plurality of storage shelves, and each of the plurality of storage shelves have shelf plates with shelf features for supporting a container. Each of the plurality of storage shelves are coupled to a chain to enable horizontal movement and each is further coupled to a rail to enable guiding to one or more positions. A motor is coupled to a drive sprocket for moving the chain, such that each of the plurality of storage shelves move together along the rail to the one or more positions. The rail has at least some sections that are linear and some sections that are nonlinear and the sections are arranged in a loop.

Abstract: A storage system and methods for operating a storage system are disclosed. The storage system includes a storage system assembly positioned at a height that is greater than a height of a tool used for loading and unloading substrates to be processed. The storage system locally stores one or more containers of substrates. The storage system assembly includes a plurality of storage shelves, and each of the plurality of storage shelves have shelf plates with shelf features for supporting a container. Each of the plurality of storage shelves are coupled to a chain to enable horizontal movement and each is further coupled to a rail to enable guiding to one or more positions. A motor is coupled to a drive sprocket for moving the chain, such that each of the plurality of storage shelves move together along the rail to the one or more positions. The rail has at least some sections that are linear and some sections that are nonlinear and the sections are arranged in a loop.

Abstract: The present invention generally comprises an apparatus for transporting containers between a first transport system and a second transport system. In one embodiment, the first transport system comprises a ceiling-based conveyor and the second transport system comprises a floor-based conveyor. The present invention may further include storage shelves, preferably substantially horizontally aligned about a common vertical plane with a section of one of the transport systems. The transport system may be located either directly above the uppermost storage shelf or beneath the lowermost storage shelf in order to add storage capacity within the fab. A vertical module transports containers between the transport systems and the at least one storage shelf.

Abstract: A conveyor and conveyor system is defined for moving a container used to hold semiconductor wafers. The conveyor includes a first belt having a first support surface for movably supporting the container and a second belt having a second support surface for movably supporting the container. The first belt and the second belt each have a raised guide. The conveyor further includes a drive assembly for moving at least the first belt and causing the container to move over the first and second belts when placed on the first and second support surfaces. Methods for making the conveyor and operating the conveyor are also defined herein.

Abstract: The present invention generally comprises a tool load device for transferring a container between a container transport system and a processing tool. The tool load device may service a single load port or multiple load ports. Regardless, the tool load device is preferably located between the load port of the processing tool and the section of the container transport system passing the processing tool. The tool load device provides an improved method of moving containers between a conventional load port and, for example, a conveyor. In another embodiment, the tool load device is coupled with an x-drive assembly that moves the tool load device along a path that is substantially parallel to the container transport system passing in front of the load port—allowing the tool load device to service multiple load ports.

Abstract: A semiconductor substrate is provided. The substrate includes a first surface and an opposing second surface, wherein the first surface includes a marking in a centroid region of the first surface. The marking indicates a location of a center point on the first surface of the semiconductor substrate or identification data unique to the substrate. A system, methods of transporting and marking, and a device for reading the substrate markings are also provided.

Abstract: A direct load system and conveyor is disclosed. The direct load system includes a load port for moving containers in a vertical orientation between a lower position near the conveyor and up to an upper position proximate to a load port door. The load port includes a single arm that moves a support in a vertical configuration, such that moving the single arm allows for the support to be lowered to the conveyor in a nested location between beams of the conveyor. The conveyor includes a single slot in a beam that allows the single arm to pass, and allows the support to be placed in the nested location, which is below a conveyor path defined by the belts of the conveyor. If a container is to be lifted off of the belts, the single arm raises up from the nested location, to then raise the container up and off of the conveyor and to the load port door.

Abstract: A conveyor and conveyor system is defined for moving a container used to hold semiconductor wafers. The conveyor includes a first belt having a first support surface for movably supporting the container and a second belt having a second support surface for movably supporting the container. The first belt and the second belt each have a raised guide. The conveyor further includes a drive assembly for moving at least the first belt and causing the container to move over the first and second belts when placed on the first and second support surfaces. Methods for making the conveyor and operating the conveyor are also defined herein.

Abstract: The present invention comprises a vacuum end effector having workpiece supports that work in conjunction with distorted workpiece surfaces. In one embodiment, each workpiece support has the ability to gimbal and conform the workpiece surface in contact with an outer edge of the support. Each workpiece support preferably provides a knife-like contact edge to minimize the contact area between the support and the workpiece while still providing an effective vacuum area to hold the wafer securely on the support. In another embodiment, each workpiece support is replaceable without having to remove the end effector from the robot assembly.

Abstract: The present invention generally comprises a transport system for transporting containers throughout a fabrication facility, and more specifically through a tool bay in the fabrication facility. The present invention generally includes a first container transport system for transporting a container from an interbay conveyor towards the first tool bay, a second container transport system for moving a container away from the first tool bay and a tool loading device to move containers between the first and second container transport systems and a load port. A merged return conveyor for transporting a container between the second container transport system and the interbay conveyor may also be included.

Abstract: A port door providing an interface into a processing tool is provided. The port door includes first and second arms pivotably mounted on a top edge of the port door. The first and second arms are configured to extend from a plane of the port door towards a carrier containing substrates for the processing tool. The first arm has an emitter transmitting a beam that is split into a plurality of sub-beams within the first arm. The second arm has a plurality of sensors receiving corresponding sub-beams, wherein one of sub-beams provides information as to a position of an end effector relative to a gap between the substrates in the carrier.

Abstract: The present invention comprises a container transport and loading system. The system generally comprises a load port for presenting articles to a tool and a container transport system. In one embodiment, the load port includes a vertically movable FOUP advance plate assembly that is adapted to load and unload a FOUP from a conveyor that passes by the load port and move the FOUP horizontally. In another embodiment, the load port includes a vertically movable support structure that is adapted to load and unload a container from a shuttle that passes by the load port. The various embodiments of the load port and container transport system are improvements over conventional container transport systems. The present invention also includes a shuttle for simultaneously transporting multiple containers that a load port may load or unload a container from.