Abstract: A multi-chamber system of an etching facility for manufacturing semiconductor devices occupies a minimum amount of floor space in a clean room by installing a plurality of processing chambers in multi-layers and in parallel along a transfer path situated between the processing chambers. The multi-layers number 2 to 5, and the transfer path can be rectangular in shape and need only be slightly wider than the diameter of a wafer. The total width of the multi-chamber system is the sum of the width of one processing chamber plus the width of the transfer path.

Abstract: A substrate treatment apparatus is provided. The substrate treatment apparatus includes a process room, a load port in which a container receiving wafers is disposed, and a wafer transfer module disposed between the load port and the process room to transfer the wafers between the load port and the process room. The wafer transfer module includes a first barrier, a second barrier extending from a first end of the first barrier or from a portion near the first end of the first barrier at a predetermined inclined angle with respect to the first barrier, and a third barrier extending from a second end of the first barrier or from a portion near the second end of the first barrier at a predetermined inclined angle. The load portion is provided along the first barrier. The process room includes a plurality of chambers arranged along the second and third barriers.

Abstract: A semiconductor fabrication apparatus, located in an apparatus installation area, includes a front-opening unified pod (FOUP) index, a plate, a first transfer device, a second transfer device, and an engineering FOUP index and multiple processing chambers. The FOUP index can be located in a line, vertically, horizontally, on top, and on bottom. The engineering FOUP index is used for manually locating the FOUP thereon in case of processing irregular single wafers that are not stored in a lot. As the FOUP index is located in the semiconductor fabrication apparatus installed in the apparatus installation area, dead space between the apparatus and air eddies generated above and below the FOUP index can be eliminated to increase the efficiency of working area and improve the environment in fabrication.

Abstract: A multi-chamber system of an etching facility for manufacturing semiconductor devices occupies a minimum amount of floor space in a cleanroom by installing a plurality of processing chambers in multi-layers and in parallel along a transfer path situated between the processing chambers. The multi-layers number 2 to 5, and the transfer path can be rectangular in shape and need only be slightly wider than the diameter of a wafer. The total width of the multi-chamber system is the sum of the width of one processing chamber plus the width of the transfer path.

Abstract: The present invention relates to a transfer apparatus for a wafer, in which the wafer may be transferred in a narrow space by reducing a transfer device footprint. The transfer device has a base, a lower arm, an upper arm and a hand. The lower arm is configured to be vertically adjustable and rotatable on a vertical axis. The upper arm is pivotably coupled to the lower arm, and the hand is horizontally coupled to the upper arm.

Abstract: A multi-chamber system of an etching facility for manufacturing semiconductor devices occupies a minimum amount of floor space in a cleanroom by installing a plurality of processing chambers in multi-layers and in parallel along a transfer path situated between the processing chambers. The multi-layers number 2 to 5, and the transfer path can be rectangular in shape and need only be slightly wider than the diameter of a wafer. The total width of the multi-chamber system is the sum of the width of one processing chamber plus the width of the transfer path.

Abstract: A robot arm mechanism includes a housing, upper and lower arms rotatably mounted on the housing, a respective substrate-supporting blade connected to each upper arm, and first, second, third and fourth driving units for rotating the housing, the upper and lower arms and the blade independently of one another. Thus, positions of the blades are readily controlled so that the blades and/or the substrates supported by the blades can be prevented from colliding against the inner wall of the chambers into and from which the substrates are transferred by the robot arm mechanism.

Abstract: A substrate manufacturing apparatus comprises a transfer chamber, at least one process chamber disposed adjacent to a lateral face of the transfer chamber, and a substrate transfer module including at least two transfer robots which transfer a substrate to the process chamber, the substrate transfer module being disposed at the transfer chamber. Each of the at least two transfer robots comprises a blade including at least two supporters for supporting a substrate, an arm part connected to the blade to move the blade, and an arm driving part for driving the blade and the arm part.

Abstract: A multi-chamber system of an etching facility for manufacturing semiconductor devices occupies a minimum amount of floor space in a cleanroom by installing a plurality of processing chambers in multi-layers and in parallel along a transfer path situated between the processing chambers. The multi-layers number 2 to 5, and the transfer path can be rectangular in shape and need only be slightly wider than the diameter of a wafer. The total width of the multi-chamber system is the sum of the width of one processing chamber plus the width of the transfer path.

Abstract: A multi-chamber system includes an index station at which one or more substrate cassettes are placed, a transfer passageway having one end adjacent the index station, at least one process chamber disposed alongside the transfer passageway, and at least one substrate transfer robot disposed in the transfer passageway for receiving a substrate from the index station and by which the substrate is transferred to each process chamber. The multi-chamber system has a minimal footprint. Furthermore, the system can be easily expanded. In addition, the substrate transfer robot(s) may have a blade including two substrate supports so that the time required for moving a substrate through the system is minimized.

Abstract: A wafer transfer apparatus can transfer wafers to and from at least one process chamber quickly and in a small amount of space. The wafer transfer includes an arm unit, and a multi-blade connected to said arm unit so as to be rotatable relative to the arm unit. The multi-blade has at least two wafer supports configured to respectively support wafers as all lying in a horizontal plane. The arm unit includes a first arm mounted for rotation in a horizontal plane, and a second arm carried by the first arm and rotatable relative to the first arm in a horizontal plane. The multi-blade is carried by the second arm.

Abstract: A load port of a semiconductor manufacturing apparatus includes a plurality of kinematic coupling pins and a plurality of sensors integrated with the pins. The contacts of the sensors have upper portions that protrude from the pins. Thus, when a cassette is place on the load port, the sensors can reliably sense whether the cassette is resting properly and/or can determine whether the cassette contains wafers. Once such determinations are made in the positive, a command signal is issued that serves to load the wafers into a chamber of the manufacturing apparatus.

Abstract: An apparatus for transferring a container stored with a workpiece (for example, a semiconductor wafer container) between manufacturing stations includes: a manufacturing station that includes a generally horizontal support platform; one or more guides for guiding a vehicle; a vehicle configured to travel on one or more guides to a position below support platform; and a vertical translation unit attached to one of the manufacturing station and the vehicle that vertically translates the container between a lowered position beneath the support platform and a raised position above the support platform. In this configuration, the apparatus can provide a relatively narrow work bay while still allowing sufficient room for a worker. Also, because the vehicle can operate below the level of the manufacturing stations, there is no need for special mounting on the ceiling of the factory.

Abstract: A load port of a semiconductor manufacturing apparatus includes a plurality of kinematic coupling pins and a plurality of sensors integrated with the pins. The contacts of the sensors have upper portions that protrude from the pins. Thus, when a cassette is place on the load port, the sensors can reliably sense whether the cassette is resting properly and/or can determine whether the cassette contains wafers. Once such determinations are made in the positive, a command signal is issued that serves to load the wafers into a chamber of the manufacturing apparatus.

Abstract: A multi-chamber system of an etching facility for manufacturing semiconductor devices occupies a minimum amount of floor space in a cleanroom by installing a plurality of processing chambers in multi-layers and in parallel along a transfer path situated between the processing chambers. The multi-layers number 2 to 5, and the transfer path can be rectangular in shape and need only be slightly wider than the diameter of a wafer. The total width of the multi-chamber system is the sum of the width of one processing chamber plus the width of the transfer path.

Abstract: A multi-chamber system of an etching facility for manufacturing semiconductor devices occupies a minimum amount of floor space in a cleanroom by installing a plurality of processing chambers in multi-layers and in parallel along a transfer path situated between the processing chambers. The multi-layers number 2 to 5, and the transfer path can be rectangular in shape and need only be slightly wider than the diameter of a wafer. The total width of the multi-chamber system is the sum of the width of one processing chamber plus the width of the transfer path.

Abstract: A semiconductor fabrication apparatus, located in an apparatus installation area, includes a front-opening unified pod (FOUP) index, a plate, a first transfer device, a second transfer device, and an engineering FOUP index and multiple processing chambers. The FOUP index can be located in a line, vertically, horizontally, on top, and on bottom. The engineering FOUP index is used for manually locating the FOUP thereon in case of processing irregular single wafers that are not stored in a lot. As the FOUP index is located in the semiconductor fabrication apparatus installed in the apparatus installation area, dead space between the apparatus and air eddies generated above and below the FOUP index can be eliminated to increase the efficiency of working area and improve the environment in fabrication.

Abstract: The present invention relates to a transfer apparatus for a wafer, in which the wafer may be transferred in a narrow space by reducing a transfer device footprint. The transfer device has a base, a lower arm, an upper arm and a hand. The lower arm is configured to be vertically adjustable and rotatable on a vertical axis. The upper arm is pivotably coupled to the lower arm, and the hand is horizontally coupled to the upper arm.

Abstract: A load port of a semiconductor manufacturing apparatus includes a plurality of kinematic coupling pins and a plurality of sensors integrated with the pins. The contacts of the sensors have upper portions that protrude from the pins. Thus, when a cassette is place on the load port, the sensors can reliably sense whether the cassette is resting properly and/or can determine whether the cassette contains wafers. Once such determinations are made in the positive, a command signal is issued that serves to load the wafers into a chamber of the manufacturing apparatus.

Abstract: An apparatus for transferring a container stored with a workpiece (for example, a semiconductor wafer container) between manufacturing stations includes: a manufacturing station that includes a generally horizontal support platform; one or more guides for guiding a vehicle; a vehicle configured to travel on one or more guides to a position below support platform; and a vertical translation unit attached to one of the manufacturing station and the vehicle that vertically translates the container between a lowered position beneath the support platform and a raised position above the support platform. In this configuration, the apparatus can provide a relatively narrow work bay while still allowing sufficient room for a worker. Also, because the vehicle can operate below the level of the manufacturing stations, there is no need for special mounting on the ceiling of the factory.