Abstract: A substrate transport apparatus including a frame, an upper arm rotatably mounted to the frame about a shoulder axis, a forearm rotatably mounted to the upper arm about an elbow axis where the forearm includes stacked forearm sections dependent from the upper arm through a common joint, and independent stacked end effectors rotatably mounted to the forearm, the forearm being common to the independent stacked end effectors, wherein at least one end effector is mounted to the stacked forearm sections at a wrist axis, where the forearm is configured such that spacing between the independent stacked end effectors mounted to the stacked forearm sections is decoupled from a height build up between end effectors accommodating pass through instrumentation.

Abstract: A substrate aligner providing minimal substrate transporter extend and retract motions to quickly align substrate without back side damage while increasing the throughput of substrate processing. In one embodiment, the aligner having an inverted chuck connected to a frame with a substrate transfer system capable of transferring substrate from chuck to transporter without rotationally repositioning substrate. The inverted chuck eliminates aligner obstruction of substrate fiducials and along with the transfer system, allows transporter to remain within the frame during alignment. In another embodiment, the aligner has a rotatable sensor head connected to a frame and a substrate support with transparent rest pads for supporting the substrate during alignment so transporter can remain within the frame during alignment. Substrate alignment is performed independent of fiducial placement on support pads.

Abstract: A substrate processing apparatus having a station for loading and unloading substrates from the apparatus is provided. The station has a loading and unloading aperture, a magazine door drive for opening a substrate magazine by removing a door of a substrate magazine through the loading and unloading aperture, and a substrate magazine transport having a magazine support, the substrate magazine transport being configured to move the substrate magazine horizontally between a first position and a second position. When in the first position the substrate magazine is seated on the magazine support and communicates with the aperture and when moved to the second position the substrate magazine is offset from the first position, where the substrate magazine remains seated on the magazine support during horizontal transfer between the first and second positions and another substrate magazine is capable of being located at the first position in communication with the aperture.

Abstract: A robotic transport apparatus including a drive system including at least one harmonic motor assembly, at least one drive shaft coupled to the at least one harmonic motor assembly, at least one robotic arm mounted to the at least one drive shaft, where the robotic arm is located inside a sealed environment, and at least one atmospheric isolation seal seated on an output surface of the drive system and forming an atmospheric barrier disposed so that the at least one drive shaft extends through the atmospheric barrier into the sealed environment and the at least one harmonic motor assembly is located outside the sealed environment, wherein the robotic transport apparatus is a high capacity payload transport apparatus.

Abstract: A substrate aligner providing minimal substrate transporter extend and retract motions to quickly align substrate without back side damage while increasing the throughput of substrate processing. In one embodiment, the aligner having an inverted chuck connected to a frame with a substrate transfer system capable of transferring substrate from chuck to transporter without rotationally repositioning substrate. The inverted chuck eliminates aligner obstruction of substrate fiducials and along with the transfer system, allows transporter to remain within the frame during alignment. In another embodiment, the aligner has a rotatable sensor head connected to a frame and a substrate support with transparent rest pads for supporting the substrate during alignment so transporter can remain within the frame during alignment. Substrate alignment is performed independent of fiducial placement on support pads.

Abstract: A substrate transport apparatus including a frame, an upper arm rotatably mounted to the frame about a shoulder axis, a forearm rotatably mounted to the upper arm about an elbow axis where the forearm includes stacked forearm sections dependent from the upper arm through a common joint, and independent stacked end effectors rotatably mounted to the forearm, the forearm being common to the independent stacked end effectors, wherein at least one end effector is mounted to the stacked forearm sections at a wrist axis, where the forearm is configured such that spacing between the independent stacked end effectors mounted to the stacked forearm sections is decoupled from a height build up between end effectors accommodating pass through instrumentation.

Abstract: A transfer apparatus for transporting substrates in a transfer chamber having a first and second ends and two sides extending between the ends. The transfer apparatus includes a drive section, at least one base arm fixed at one end with respect to the transfer chamber and including at least one arm link rotatably coupled to the drive section and at least one transfer arm rotatably coupled to a common end of the base arm, the at least one transfer arm has two end effectors. The drive section has motors with three independent axes of rotation defining three degrees of freedom. One degree of freedom moves the at least one base arm horizontally for transporting the at least one transfer arm and two degrees of freedom drives the at least one transfer arm to extend and retract the at least one transfer arm and swap the two end effectors.

Abstract: In accordance with one or more aspects of the disclosed embodiment a semiconductor processing apparatus is provided. The semiconductor processing apparatus includes a frame forming a sealable chamber having a longitudinal axis and lateral sides astride the longitudinal axis, the sealable chamber being configured to hold a sealed environment therein, at least one transport module mounted to the sealable chamber and having a telescoping carriage being configured so that the telescoping carriage is linearly movable relative to another portion of the transport module where the telescoping carriage and the other portion define a telescoping motion along the longitudinal axis, and at least one transfer robot mounted to the carriage, each of the at least one transfer robot having at least one transfer arm configured for holding a substrate thereon.

Abstract: A substrate transport apparatus comprising a drive section, a controller, an upper arm, forearm and substrate holder. A proximate end of the upper arm being rotatably mounted to the drive section at a shoulder joint. A proximate end of the forearm being rotatably mounted to a distal end of the upper arm at an elbow joint. The substrate holder being rotatably mounted to a distal end of the forearm at a wrist joint. The upper arm and the forearm being unequal in length from joint center to joint center. The substrate transport arm is adapted to transport substrate to and from at least two substrate holding areas with the drive section of the transport apparatus remaining in a fixed position relative to the holding areas. Each of the upper arm, forearm and substrate holder being independently rotatable with respect to each other.

Abstract: A substrate processing system including a load port module configured to hold at least one substrate container for storing and transporting substrates, a substrate processing chamber, an isolatable transfer chamber capable of holding an isolated atmosphere therein configured to couple the substrate processing chamber and the load port module, and a substrate transport mounted at least partially within the transfer chamber having a drive section fixed to the transfer chamber and having a SCARA arm configured to support at least one substrate, the SCARA arm being configured to transport the at least one substrate between the at least one substrate container and the processing chamber with but one touch of the at least one substrate, wherein the SCARA arm comprises a first arm link, a second arm link, and at least one end effector serially pivotally coupled to each other, where the first and second arm links have unequal lengths.

Abstract: A substrate processing apparatus is provided. The apparatus has a casing, a low port interface and a carrier holding station. The casing has processing devices within for processing substrates. The load port interface is connected to the casing for loading substrates into the processing device. The carrier holding station is connected to the casing. The carrier holding station is adapted for holding at least one substrate transport carrier so the at least one substrate transport carrier is capable of being coupled to the load port interface without lifting the at least one substrate transport carrier off the carrier holding station. The carrier holding station is arranged to provide a substantially simultaneous swap section for substantially simultaneous replacement of the substrate transport carrier from the carrier holding station.

Abstract: A transport apparatus including a housing, a drive mounted to the housing, and at least one transport arm connected to the drive, where the drive includes at least one rotor having at least one salient pole of magnetic permeable material and disposed in an isolated environment, at least one stator having at least one salient pole with corresponding coil units and disposed outside the isolated environment where the at least one salient pole of the at least one stator and the at least one salient pole of the rotor form a closed magnetic flux circuit between the at least one rotor and the at least one stator, at least one seal partition configured to isolate the isolated environment, and at least one sensor including a magnetic sensor member connected to the housing, at least one sensor track connected to the at least one rotor where the at least one seal partition is disposed between and separates the magnetic sensor member and the at least one sensor track so that the at least one sensor track is disposed in t

Abstract: A substrate processing apparatus including a frame, a first SCARA arm connected to the frame, including an end effector, configured to extend and retract along a first radial axis; a second SCARA arm connected to the frame, including an end effector, configured to extend and retract along a second radial axis, the SCARA arms having a common shoulder axis of rotation; and a drive section coupled to the SCARA arms is configured to independently extend each SCARA arm along a respective radial axis and rotate each SCARA arm about the common shoulder axis of rotation where the first radial axis is angled relative to the second radial axis and the end effector of a respective arm is aligned with a respective radial axis, wherein each end effector is configured to hold at least one substrate and the end effectors are located on a common transfer plane.

Abstract: In accordance with an exemplary embodiment a semiconductor workpiece processing system having at least one processing tool for processing semiconductor workpieces, a container for holding at least one semiconductor workpiece therein for transport to and from the at least one processing tool and a first transport section elongated and defining a travel direction. The first transport section has parts, that interface the container, supporting and transporting the container along the travel direction to and from the at least one processing tool. The container is in substantially continuous transport at a substantially constant rate in the travel direction, when supported by the first transport section. A second transport section is connected to the at least one process tool for transporting the container to and from the at least one processing tool.

Abstract: A substrate transport apparatus comprising a drive section, a controller, an upper arm, forearm and substrate holder. A proximate end of the upper arm being rotatably mounted to the drive section at a shoulder joint. A proximate end of the forearm being rotatably mounted to a distal end of the upper arm at an elbow joint. The substrate holder being rotatably mounted to a distal end of the forearm at a wrist joint. The upper arm and the forearm being unequal in length from joint center to joint center. The substrate transport arm is adapted to transport substrate to and from at least two substrate holding areas with the drive section of the transport apparatus remaining in a fixed position relative to the holding areas. Each of the upper arm, forearm and substrate holder being independently rotatable with respect to each other.

Abstract: A substrate transport apparatus having a drive section and a scara arm operably connected to the drive section to move the scara arm. The scara arm has an upper arm and at least one forearm. The forearm is movably mounted to the upper arm and capable of holding a substrate thereon. The upper arm is substantially rigid and is adjustable for changing a predetermined dimension of the upper arm.

Abstract: A substrate processing apparatus including a frame, a first SCARA arm connected to the frame, including an end effector, configured to extend and retract along a first radial axis; a second SCARA arm connected to the frame, including an end effector, configured to extend and retract along a second radial axis, the SCARA arms having a common shoulder axis of rotation; and a drive section coupled to the SCARA arms is configured to independently extend each SCARA arm along a respective radial axis and rotate each SCARA arm about the common shoulder axis of rotation where the first radial axis is angled relative to the second radial axis and the end effector of a respective arm is aligned with a respective radial axis, wherein each end effector is configured to hold at least one substrate and the end effectors are located on a common transfer plane.

Abstract: In accordance with an exemplary embodiment a semiconductor workpiece processing system having at least one processing tool for processing semiconductor workpieces, a container for holding at least one semiconductor workpiece therein for transport to and from the at least one processing tool and a first transport section elongated and defining a travel direction. The first transport section has parts, that interface the container, supporting and transporting the container along the travel direction to and from the at least one processing tool. The container is in substantially continuous transport at a substantially constant rate in the travel direction, when supported by the first transport section. A second transport section is connected to the at least one process tool for transporting the container to and from the at least one processing tool.

Abstract: A substrate transport apparatus having a drive section and a scara arm operably connected to the drive section to move the scara arm. The scara arm has an upper arm and at least one forearm. The forearm is movably mounted to the upper arm and capable of holding a substrate thereon. The upper arm is substantially rigid and is adjustable for changing a predetermined dimension of the upper arm.

Abstract: A transfer apparatus including a frame, multiple arms connected to the frame, each arm having an end effector and an independent drive axis for extension and retraction of the respective arm with respect to other ones of the multiple arms, a linear rail defining a degree of freedom for the independent drive axis for extension and retraction of at least one arm, and a common drive axis shared by each arm and configured to pivot the multiple arms about a common pivot axis, wherein at least one of the multiple arms having another drive axis defining an independent degree of freedom with respect to other ones of the multiple arms.