Abstract: A vacuum coating unit having a pair of side by side transport devices for transporting substrates in a transport direction. Each transport device includes at least one first endless conveyor running in the transport direction and having a conveying element guided around at least two guide rollers or pulleys. The conveying element is located at a distance from a guide device extending in the transport direction parallel to the conveying element in such a way that the ends of the substrates can be introduced into the gap between the conveying element and the guide device of the transport devices and can be moved in the transport direction by the displacement of the conveying elements.

Abstract: An elongate vacuum system for coating one or both sides of a flat substrate which can be displaced by the system, comprises at least one magnetron provided with a magnetron surrounding area and is subdivided into successive compartments in the direction of transportation of the substrate by separating walls having closeable suction openings. The compartments can be evacuated either directly by a vacuum connection provided on the compartment or indirectly via a suction opening in the separating wall. At least one compartment comprises an upper partial compartment which is arranged above the substrate. The partial compartment comprises a closeable upper opening in at least one of the outer walls thereof. The aim is to produce an elongate coating system which is flexible to use according to the requirements of various one and two-sided coating processes and ensures a stable, differential and process-optimized sputter atmosphere.

Abstract: A vacuum coating unit with a transport device for transporting substrates in a transport direction, comprises at least one first endless conveyor running in the transport direction and having a conveyor device guided around at least two deflection rollers. The conveyor device is located at a distance from a guide device extending in the transport direction parallel to the conveyor device of the first endless conveyor in such a way that the substrates can be introduced into the gap between the conveyor device and the guide device and can be moved in the transport direction by the displacement of the conveyor device.

Abstract: An elongate vacuum system for coating one or both sides of a flat substrate which can be displaced by the system, comprises at least one magnetron provided with a magnetron surrounding area and is subdivided into successive compartments in the direction of transportation of the substrate by separating walls having closeable suction openings. The compartments can be evacuated either directly by a vacuum connection provided on the compartment or indirectly via a suction opening in the separating wall. At least one compartment comprises an upper partial compartment which is arranged above the substrate. The partial compartment comprises a closeable upper opening in at least one of the outer walls thereof. The aim is to produce an elongate coating system which is flexible to use according to the requirements of various one and two-sided coating processes and ensures a stable, differential and process-optimized sputter atmosphere.

Abstract: The invention concerns an apparatus for vacuum coating of substrates of various sizes that consists of lock chambers at the entrance and at the exit and several processing chambers arranged one behind the other as well as of a conveying system for the sequential transport of substrates with a certain substrate width through the lock chambers and for their continuous transport through the coating chambers. The lock and processing chambers each have a chamber width that corresponds to the substrate width, and the lock chamber is characterized by a loading area AL having a width b and a length l that indicates the size of substrate that can be accommodated. The object of the apparatus according to the invention is to better utilize the coatable area of each processing chamber so that less coating material is wasted. The object is solved by making the ratio R of width to length R=w/l greater than a minimum ratio Rmin where Rmin =0.95?0.019 AL.

Abstract: A system for coating band-shaped material, where the band-shaped material travels through at least one process chamber in which there is a vacuum, and at least one cooling roller. On the peripheral surface of each cooling roller are at least two magnetron sputter sources that are arranged separate from one another in magnetron chambers, which are formed by separate magnetron chamber walls and allow each chamber to be evacuated, so the pressure in the magnetron chamber can be maintained higher than that in the process chamber. The magnetron chamber walls and the magnetron sputter sources can be mounted on a common carriage, which is displaceable parallel to the cooling roller axis. The result is the reduction in the maintenance costs in cleaning of the magnetron chamber walls and at the same time improvement of the separation of gas between the magnetron chambers and the process chamber.

Abstract: A tube magnetron for a vacuum coating applications such as plasma sputtering is provided with a hollow rotating tube target arrangement and a magnet system. The hollow rotating tube target arrangement has longitudinally extended target plates that are fixed to a target support. The target plates in cross section are arranged adjacent to each other to form a polygon. The magnet system generates a magnetic field which extends through the tube target arrangement. The magnet system is configured so that generated magnet field has in cross section two maxima arranged in the axial longitudinal direction of the tube target arrangement. The tube magnetron is configured for use with sputtering targets that are in the form of target plates. The target plates may be made from ceramics, ceramic-like and/or high-melting point materials. Materials such as ITO, zinc oxide, silicon can be efficiently and uniformly sputter coated on substrates.

Abstract: A system for coating band-shaped material, where the band-shaped material travels through at least one process chamber in which there is a vacuum, and at least one cooling roller. On the peripheral surface of each cooling roller are at least two magnetron sputter sources that are arranged separate from one another in magnetron chambers, which are formed by separate magnetron chamber walls and allow each chamber to be evacuated, so the pressure in the magnetron chamber can be maintained higher than that in the process chamber. The magnetron chamber walls and the magnetron sputter sources can be mounted on a common carriage, which is displaceable parallel to the cooling roller axis. The result is the reduction in the maintenance costs in cleaning of the magnetron chamber walls and at the same time improvement of the separation of gas between the magnetron chambers and the process chamber.

Abstract: A sputtering installation has two longitudinally extended magnetrons disposed next to one another and each has a target on an upper side thereof. Increasing utilization of the targets in the sputtering installation is accomplished by homogenizing the discharge resistance of the magnetrons along the directrix such that a partial discharge resistance of a target point on the directrix has the same magnitude as the partial discharge resistance of a different target point on the directrix.

Abstract: The invention which relates to a device for the generating of electron beams with a vacuum chamber, in which a massive cathode (10) is arranged with a wire cathode (14) arranged above and a aperture anode (17) below the massive cathode (10) and whom below the aperture anode (17) focusing and/or deflecting magnet arrangements are provided which direct an electron beam (23) emitted by the massive cathode (10) and accelerated by the aperture anode (17) to a processing location (22), has the basic task to make the power of such devices variable over a large range using simple mechanical means. According to the invention the task is solved by arranging the aperture anode (17) rigidly and the massive cathode (10) and the wire cathode (14) axially movable within the vacuum chamber (1). For the movements of the massive cathode (10) and the wire cathode (14) contact means are provided which follow their movements and lead to the outside of the vacuum chamber (1).