Abstract: A system of shuttle cars for transporting a vehicle in an automated parking facility. Each shuttle car includes an x-shuttle that supports two z-shuttles. The z-shuttles move from the x-shuttle and under the vehicle for transport. The z-shuttles locate and engage the front and rear tires of a vehicle to lift the vehicle from the floor. Once the z-shuttles have engage the vehicle tires, the z-shuttles return to the x-shuttle so that the x-shuttle can transport the vehicle (and the z-shuttles) to and from the appropriate parking space.

Abstract: A stair climbing system for moving objects either up or down stairs that entails placing a base and roller assembly in a first position on the stairs, rolling the object over the stationary base and roller assembly, and then advancing the base and roller assembly from a trailing position under the object to an advanced position to continue movement of the object up or down stairs. The base and roller assembly base includes first and second side panels supporting a roller, each having surfaces reacting against the stair step and the stair riser to prevent tilting of the base and roller assembly under the load of the object.

Abstract: An automated arrangement for filling a shipping rack structure with water bottles (or any other type of bottle) includes an elevator arrangement and a pusher component, both under the control of a programmed control element (such as a microprocessor), to automatically present a plurality of filled bottles to an open rack “column” and move (push) the bottles from the elevator into the rack. The loader system is pre-programmed with inputs including the array size of the rack being loaded (i.e., how many bottles “deep” along each rail, the number of rows in the rack and the number of columns in the rack). With this information, the elevator will thus lift the proper number of bottles into place to fill a column, and then stop. Once the elevator stops, the pusher component will advance to move the column of bottles into the rack. The pusher then retracts, the elevator is re-started, and the next column of filled bottles is loaded into the elevator.

Abstract: A system for sensing, orienting, and transporting wafers in an automated wafer handling process that reduces the generation of particles and contamination so that the wafer yield is increased. The system includes a robotic arm for moving a wafer from one station to a destination station, and an end-effector connected to an end of the robotic arm for receiving the wafer. The end-effector includes a mechanism for gripping the wafer, a direct drive motor for rotating the wafer gripping mechanism, and at least one sensor for sensing the location and orientation of the wafer. A control processor calculates the location of the center and the notch of the wafer based on measurements by the sensor(s) and generates an alignment signal for rotating the wafer gripping mechanism so that the wafer is oriented at a predetermined position on the end-effector while the robotic arm is moving to another station.

Abstract: A vacuum processing apparatus includes: a plurality of carriers to be mounted with a base member; a circulation path which is kept in a controlled atmosphere and through which the carriers circulate; a plurality of base member loading and unloading chambers which are disposed in the circulation path and which load and unload the base member to and from the carriers; and a plurality of vacuum processing chambers which are disposed between the base member loading and unloading chambers in the circulation path for performing a vacuum process on the base member.

Abstract: A trailer is provided for a helicopter. The trailer includes a chassis, at least two lifters provided on the chassis, at least two drivers provided on the chassis and connected to the lifters, at least two locks for locking the lifters in an upper position and a connector for connecting the chassis to a vehicle.

Abstract: A system and method is disclosed that transfers carrier boards in a handler that supports the testing of electronic devices. A carrier board can be transferred from the transfer start position to one of the mid transfer positions and the transfer final position. Carrier boards, which are spaced apart from each other in a chamber, can be gathered adjacent to each other in the circulation direction of carrier board. The transfer speed and the total circulation speed of the carrier boards can be enhanced. The transfer speed of carrier board can be easily controlled according to the test conditions.

Abstract: In various exemplary embodiments described herein, a system includes a plurality of carrier arms each having concentrically mounted midpoints between opposing ends of the carrier arms with a wafer carrier mounted on each of the opposing ends of the carrier arms. A hub includes a plurality of concentrically mounted drives where each of the plurality of drives is coupled near the midpoint of a respective one of the plurality of carrier arms. Each of the plurality of drives is configured to be controlled independently of the remaining plurality of concentrically mounted drives. A respective motor is coupled to each of the concentrically mounted drives and is configured to move the coupled carrier arm in a rotary manner. A linear wafer transport mechanism moves wafers to or from select ones of the wafer carriers on the plurality of carrier arms to an easy handoff location for a load/unload robot.

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 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: Positional relationship among the first link support shaft (85), the second link support shaft (86), the first arm support shaft (88) and the second arm support shaft (89) is set such that an upper portion of the first lift link (81) comes into substantial agreement with a rear end of the machine body (1), when the upper free end of the first lift link (81) is pivoted maximally rearward in the course of transition of the arm (77) from a lowermost state realized lifting down the arm (77) to an uppermost state realized by lifting up the arm (77).

Abstract: An apparatus for a liquid crystal display device includes: a process chamber for treating a substrate; a load-lock chamber having an interior conveyor; and a transfer chamber connected to the process chamber and the at least one load-lock chamber, the transfer chamber having a substrate-transferring means.

Abstract: The invention provides a robotic arm for transporting a substrate in an ultrahigh vacuum including a carrier module and a drive module. The drive module includes a magnetic coupling, a first transmission module, a second transmission module, and a third transmission module. The magnetic coupling includes an inner shaft and an outer shaft. The first transmission module drives the first active unit of the magnetic coupling to turn a first passive unit of the inner shaft by magnetic force. The second transmission module drives the second active unit of the magnetic coupling to turn a second passive unit of the outer shaft by magnetic force. The third transmission module drives the magnetic coupling and the carrier module to perform vertical movement. The carrier module will achieve rotational motion or extending motion when the inner shaft and the outer shaft are driven by the first transmission module and the second transmission module of the drive module.

Abstract: A ball bearing having external surfaces coated with ceramic materials is provided. The raceways of the ball bearing may advantageously be formed of metal such as stainless steel. The ceramic coating acts as an insulator increasing the resistance of the ball bearing to heat within the ball bearing environment. The balls within the raceway of the ball bearing may advantageously be coated with a lubricant to decrease friction in the ball bearing because the insulating ceramic coating prevents the environmental heat from causing the degradation of the lubricant.

Abstract: An apparatus for transferring and securing a substrate is shown. A pressure source is provided that is adapted to provide positive and negative pressure. A vacuum chuck is provided having a top side with a plurality of vacuum chuck portals formed therein. Each vacuum chuck portal is in fluid communication with the pressure source. The substrate is secured to the top side of the vacuum chuck when the pressure source provides negative pressure to the vacuum chuck portals. An intermediate member that selectively cooperates with the vacuum chuck to support and transfer the substrate between the vacuum chuck and the intermediate member is provided. The intermediate member has a plurality of receiving spaces and a plurality of transfer members. The receiving spaces and transfer members are adjacent to one another in an alternating pattern, and each transfer member has a top side with a plurality of transfer member portals formed therein.

Abstract: A handler includes a device holding portion, which holds an uninspected device and loads the device in a measuring socket on a device tester, having a suction means for sucking the device by a very weak pushing force at the time of sucking the device from an uninspection tray and for loading the device in a measuring socket and also having a clamper capable of outputting a pushing force which can be changed at the time of the measurement contact. The device holding portion includes a position correcting mechanism for making a device position correction executed by an image recognizing and position correcting means.

Abstract: A backhoe loader 10 with a controller 100 that uses angular signals from at least one sensor to calculate a loader tool angle with respect to the vehicle frame 12 or with respect to the earth and to maintain the loader tool angle via controller generated commands to a tool actuator 61 as a function of the angular signals and commands to a boom actuator 50. The controller 100 enables proportional control of the tool angle via a command input device such as an electronic joystick 21. If the electronic joystick 21 is moved to an appropriate detent position, the controller executes a return to carry function. If the boom 31 is at or below the return to carry angle at the time the joystick 21 is moved to the detent position, the controller 100 executes a float function allowing the bucket 36 and the boom 31 to rest on the ground and follow the contours of the earth as the vehicle moves over the earth.

Abstract: A robotic arm is for holding a molding item. The robotic arm includes a mount; a lifting mechanism mounted to the mount; a horizontal driving device; a rotating assembly mounted between the lifting mechanism and the horizontal driving device to rotate the horizontal driving device relative to the lifting mechanism; a holder for holding the molding item, the holder mounted on the horizontal driving device. The lifting mechanism cause the holder to move relative to the mount in a first direction, the horizontal driving device moves the holder relative to the mount and the lifting mechanism in a second direction perpendicular to the first direction.

Abstract: A technology related to a pick-and-place apparatus for electronic device inspection equipment is provided. The pick-and-place apparatus includes the guiding unit that can interact with a loading element and can guide the picker to load the electronic devices at a correct position on the loading element. Therefore, the pick-and-place apparatus can allow the electronic devices, for example, semiconductor devices having a ball type of electrical contact lead (BGA, FBGA, etc.), to electrically contact the tester in a stable manner when the tester inspects the electronic devices.

Abstract: An arrangement for fixing a work piece (14) to an end of a boom (1) in a working machine, like an excavator, in which arrangement the end of the boom comprises at least a tilting device (13) for the work piece (14), the moveable body of said device can be limitedly tilted in relation to the end of the boom (1) and to the moveable body of said device the work piece (14) is fixed either directly or by fitting a device (10), (11) of an other type as a distance piece, said device adjusting position of the work piece (14).