A transport system and a system for moving permanent-magnet-excited transport bodies by an inductively excited magnetic field includes induction coils, a movably supported first reluctance element, and an actuator. The induction coils are configured for a current to flow through the induction coils in order to drive the transport bodies in a plane without contact. The actuator is configured to bring the first reluctance element from a first position into a second position. The permanent magnetic field of a transport body located over the first reluctance element experiences a lower magnetic resistance in a magnetic circuit through the first reluctance element in the second position than in the first position.

An organic layer deposition apparatus, and a method of manufacturing an organic light-emitting display device using the organic layer deposition apparatus. The organic layer deposition apparatus includes: an electrostatic chuck that fixedly supports a substrate that is a deposition target; a deposition unit including a chamber maintained at a vacuum and an organic layer deposition assembly for depositing an organic layer on the substrate fixedly supported by the electrostatic chuck; and a first conveyor unit for moving the electrostatic chuck fixedly supporting the substrate into the deposition unit, wherein the first conveyor unit passes through inside the chamber, and the first conveyor unit includes a guide unit having a receiving member for supporting the electrostatic chuck to be movable in a direction.

A device for collecting and transferring light emitting elements of microscale size includes a non-magnetic plate, a plurality of magnetic probes, and a magnetic plate. The non-magnetic plate defines through holes. Each of the probes is fixed in one through holes. The magnetic plate is on a surface of the non-magnetic plate and closes one opening of each of the through holes. The magnetic plate generates a magnetic field, so that each of the probes magnetically attracts one light emitting element. A method for making the transfer device and a method for transferring light emitting elements using the transfer device are also disclosed.

A conveying device includes a transport body configured to carry or hold a wafer, and a stator relative to which the conveying device is designed to move the transport body at least two-dimensionally on a conveying surface. The stator includes several movably arranged actuating magnets, each of which is connected to the stator via an actuating element, and the actuating element is configured to change a position and/or an orientation of the connected actuating magnets relative to the stator. The transport body includes at least two stationary magnets which are connected to the transport body such that the stationary magnets are immovable relative to the transport body, and the stator and the transport body are magnetically coupled by the stationary magnets and the actuating magnets. The device conveys the transport body relative to the stator by controlled positioning and/or orientation of the actuating magnets via the actuating elements.

A system for providing vacuum to a moving element of a transport system, the system includes: a vacuum chamber on the moving element for storing vacuum; a vacuum source; a vacuum inlet provided on the vacuum chamber and for connection to the vacuum source; and a vacuum outlet in communication with the vacuum chamber and positioned on the moving element. The vacuum source may be provided on and travel with the moving element or on the transport system and periodically engage with the vacuum chamber. Where the vacuum source is provided on the moving element, a vacuum chamber may not be required. Further, the vacuum source may be driven by electrical energy and/or mechanical energy in various configurations.

A vacuum transfer device configured to transfer a substrate in a vacuum includes: a flat motor including a body, a plurality of electromagnetic coils arrayed in the body, and a current controller that controls a current supplied to the electromagnetic coil; a transfer unit including a substrate holder configured to hold a substrate, and a base having a plurality of magnets arrayed therein and magnetically levitating from a surface of the body by a magnetic field generated by the electromagnetic coil, and move in a magnetically levitating state thereby moving the substrate holder; and a temperature controller configured to adjust temperature of at least a portion of the body. The temperature of the transfer unit is adjusted by stopping the magnetic levitation of the base by controlling the current supplied to the electromagnetic coil, and bringing the base into contact with a temperature-adjusted portion of the body.

In order to provide a transport device that includes a planar motor, which gives greater flexibility in the movement of the transport units, at least two planar motors have opposing transport planes, wherein provided on the transport plane of a first planar motor is at least one first transport unit, which is connected, by a connecting unit, to at least one second transport unit provided on the transport plane of a second planar motor.

An automatic wafer carrying system and a method for transferring a wafer using the system are provided. The system includes: a vacuum chamber, including a plurality of wafer carrying stations; a plurality of first paddles and second paddles, all located inside the vacuum chamber and capable of rotating synchronously separately, where each of the plurality of second paddles and a corresponding first paddle form a pair of paddles to carry a wafer jointly; a double-ferrule magnetofluid, connected to the vacuum chamber in a sealed manner, and connected to the plurality of first paddles and the plurality of second paddles, to drive the first paddles or the second paddles or both the first and second paddles to rotate; a first drive mechanism, connected to the double-ferrule magnetofluid, to drive the plurality of first paddles and the plurality of second paddles through the double-ferrule magnetofluid to rotate synchronously in the same direction; and a second drive mechanism, also connected to the double-ferrule magnetofluid, to implement relative rotation of the plurality of first paddles and the plurality of second paddles through the double-ferrule magnetofluid. The system can reduce movement steps of a wafer during transfer, so as to improve transfer accuracy and stability of the wafer and reduce a position error of the wafer.

Provided is a contactless vertical transfer device using a linear motor. The contactless vertical transfer device using a linear motor includes: a transfer unit for picking up an article; and a linear motor located on a side portion of the transfer unit to move the transfer unit, wherein the linear motor comprises at least one driving unit that is located on a side portion of the transfer unit and provided with a mover which a coil is wound; and a rail unit that is located apart from the mover by a predetermined distance in a lateral direction and provided with a plurality of magnet portions disposed in a transfer direction of the transfer unit. The transfer unit is moved along the rail unit by a thrust force of the mover and the magnet portion.

A method for making an adsorption device includes: providing and etching a substrate to form a plurality of receiving grooves spaced apart from each other; forming a magnetic film in each of the plurality of receiving grooves; and forming a magnet in each of the plurality of receiving grooves. Each receiving groove includes a bottom wall and a side wall coupling the bottom wall. The magnetic film covers the bottom wall and the side wall of each of receiving groove.