Abstract: In some examples, a processing machine for processing a substrate includes at least one shaping unit. The at least one shaping unit includes at least one forme cylinder and at least one impression cylinder. A processing point for processing a substrate is arranged between the at least one forme cylinder and the at least one impression cylinder. The processing machine includes a control unit for correcting a processing length of the substrate, and which controls a speed of at least one of the at least one forme cylinder or the at least one impression cylinder. The at least one forme cylinder and the at least one impression cylinder have a speed ratio with respect to one another that is changeable at the processing point as a function of the processing length of the substrate, and the speed ratio differs at least once within a full cylinder revolution.

Abstract: In some examples, a processing machine for processing a substrate includes at least one shaping unit and/or at least one application unit. The at least one application unit and/or the at least one shaping unit in each case includes at least one forme cylinder and at least one impression cylinder. The at least one forme cylinder of the application unit includes at least one application forme including at least one application surface and/or the at least one shaping unit includes at least one shaping tool including at least one working surface. The application surface and/or the working surface are arranged to cover at least a portion of the outer cylindrical surface of the at least one forme cylinder. A speed of the at least one forme cylinder and a speed of the at least one impression cylinder have a speed ratio with respect to one another.

Abstract: A method (100) of cooling a deposition source (200) is described. The method includes stopping (110) depositing material from the deposition source, the deposition source being arranged in a deposition chamber (250), and introducing (120) a cooling gas into the deposition chamber (250), the cooling gas comprising a thermal conductivity ? of ??0.05 [W/(m*K)]. Further, a chamber for cooling a deposition source is described. The chamber includes a deposition source being arranged in the chamber. Further, the chamber includes a cooling gas supply system configured for providing a cooling gas into the chamber, the cooling gas comprising a thermal conductivity ? of ??0.05 [W/(m*K)].

Abstract: A processing system for processing a flexible substrate is described. The processing system includes a vacuum chamber having a wall with an opening for the flexible substrate, a substrate support for supporting the flexible substrate during transportation of the flexible substrate through the opening, and a measurement assembly for measuring at least one of a property of the flexible substrate and a property of one or more coatings on the flexible substrate. The measurement assembly and the substrate support are attached to the wall.

Abstract: Methods and apparatuses for processing lithium batteries with a laser source having a wide process window, high efficiency, and low cost are provided. The laser source is adapted to achieve high average power and a high frequency of picosecond pulses. The laser source can produce a line-shaped beam either in a fixed position or in scanning mode. The system can be operated in a dry room or vacuum environment. The system can include a debris removal mechanism, for example, inert gas flow, to the processing site to remove debris produced during the patterning process.

Abstract: A method of coating a flexible substrate in a roll-to-roll deposition system is described. The method includes unwinding the flexible substrate from an unwinding roll, the flexible substrate having a first coating on a first main side thereof; measuring a lateral positioning of the first coating while guiding the flexible substrate to a coating drum; adjusting a lateral position of the flexible substrate on the coating drum depending on the measured lateral positioning of the first coating; and depositing a second coating on the flexible substrate, particularly on a second main side of the flexible substrate opposite the first main side. Further described is a vacuum deposition apparatus for conducting the methods described herein.

Abstract: A roller for transporting a flexible substrate is described. The roller includes a first coolant supply for cooling a first part of the roller and a second coolant supply for cooling a second part and a third part of the roller. The first part is provided between the second part and the third part. Additionally, a vacuum processing apparatus including a roller and a method of cooling a roller are described.

Abstract: A roller for transporting a flexible substrate is described. The roller includes a main body having a plurality of gas supply slits provided in an outer surface of the main body. The plurality of gas supply slits extends in a direction of a central rotation axis of the roller. Further, the roller includes a sleeve provided circumferentially around and in contact with the main body. The sleeve has a plurality of gas outlets being provided above the plurality of gas supply slits. Further, the sleeve includes a metal layer embedded within isolating material.

Abstract: A roller for transporting a flexible substrate is described. The roller includes a main body having a plurality of gas supply slits provided in an outer surface of the main body. The plurality of gas supply slits extends in a direction of a central rotation axis of the roller. Further, the roller includes a sleeve provided circumferentially around and in contact with the main body. The sleeve has a plurality of gas outlets extending in a radial direction (R) and being provided above the plurality of gas supply slits.

Abstract: A vapor deposition apparatus is provided. The vapor deposition apparatus includes a tank for providing a liquefied material, a first unit having an alterable first volume, the first unit including a first actuator and including a first line to be in fluid communication with the tank. Further, the vapor deposition apparatus includes a second unit having an alterable second volume, the second unit including a second actuator and including a second line to be in fluid communication with the tank. The vapor deposition apparatus includes an evaporation arrangement, the evaporation arrangement being in fluid communication with the first unit and the second unit. The first actuator and the second actuator are configured to alternatingly provide a force to the alterable first volume and the alterable second volume for providing the liquefied material to the evaporation arrangement.

Abstract: A processing system for processing a flexible substrate is described. The processing system includes a vacuum chamber having a wall with an opening for the flexible substrate, a substrate support for supporting the flexible substrate during transportation of the flexible substrate through the opening, and a measurement assembly for measuring at least one of a property of the flexible substrate and a property of one or more coatings on the flexible substrate. The measurement assembly and the substrate support are attached to the wall.

Abstract: A method of coating a flexible substrate in a roll-to-roll deposition system is described. The method includes unwinding the flexible substrate from an unwinding roll, the flexible substrate having a first coating on a first main side thereof; measuring a lateral positioning of the first coating while guiding the flexible substrate to a coating drum; adjusting a lateral position of the flexible substrate on the coating drum depending on the measured lateral positioning of the first coating; and depositing a second coating on the flexible substrate, particularly on a second main side of the flexible substrate opposite the first main side. Further described is a vacuum deposition apparatus for conducting the methods described herein.

Abstract: An evaporation source for depositing an evaporated material on a substrate is described. The evaporation source includes an evaporation crucible for evaporating a material; a vapor distributor with a plurality of nozzles for directing the evaporated material toward the substrate; a vapor conduit extending in a conduit length direction (A) from the evaporation crucible to the vapor distributor and providing a fluid connection between the evaporation crucible and the vapor distributor, wherein at least one nozzle of the plurality of nozzles has a nozzle axis extending in, or essentially parallel to, the conduit length direction (A); and a baffle arrangement in the vapor conduit. Further described are a vapor deposition apparatus including such an evaporation source and methods of coating a substrate in a vacuum chamber.

Abstract: A deposition apparatus for coating a flexible substrate is described. The deposition apparatus comprises a first spool chamber housing a storage spool for providing the flexible substrate, a deposition chamber arranged downstream from the first spool chamber, and a second spool chamber arranged downstream from the deposition chamber and housing a wind-up spool for winding the flexible substrate thereon after deposition. The deposition chamber comprises a coating drum for guiding the flexible substrate past a plurality of deposition units including at least one deposition unit having a graphite target. The coating drum is connected to a device for applying an electrical potential to the coating drum.

Abstract: A method (100) of cooling a deposition source (200) is described. The method includes stopping (110) depositing material from the deposition source, the deposition source being arranged in a deposition chamber (250), and introducing (120) a cooling gas into the deposition chamber (250), the cooling gas comprising a thermal conductivity ? of ??0.05 [W/(m*K)]. Further, a chamber for cooling a deposition source is described. The chamber includes a deposition source being arranged in the chamber. Further, the chamber includes a cooling gas supply system configured for providing a cooling gas into the chamber, the cooling gas comprising a thermal conductivity ? of ??0.05 [W/(m*K)].

Abstract: A deposition apparatus for coating a flexible substrate is described. The deposition apparatus includes a first spool chamber housing a storage spool for providing the flexible substrate, a deposition chamber arranged downstream from the first spool chamber, and a second spool chamber arranged downstream from the deposition chamber and housing a wind-up spool for winding the flexible substrate thereon after deposition. The deposition chamber includes a coating drum for guiding the flexible substrate past a plurality of deposition units including at least one deposition unit having a graphite target. Further, the deposition chamber includes a coating treatment device configured to densify a layer deposited on the flexible substrate.

Abstract: A method for controlling a gas supply to a process chamber is provided. The method includes: measuring a gas parameter by each of two or more sensors provided in the process chamber; determining a combined gas parameter from the measured gas parameters; and controlling the gas supply to the process chamber based on the determined combined gas parameter.

Abstract: According to the present disclosure, a flexible substrate coating apparatus is provided. The flexible substrate coating apparatus includes a vacuum process chamber for processing a flexible substrate. The vacuum process chamber includes one or more deposition units and a cleaning unit positioned directly downstream of the one or more deposition units. In another aspect, a method for depositing a thin-film on a flexible substrate is provided. The method for depositing a thin-film on a flexible substrate includes vacuum coating of the flexible substrate, thereby depositing one or more layers on the flexible substrate, and cleaning the flexible substrate directly downstream of the coating.

Abstract: A method for controlling a gas supply to a process chamber is provided. The method includes: measuring a gas parameter by each of two or more sensors provided in the process chamber; determining a combined gas parameter from the measured gas parameters; and controlling the gas supply to the process chamber based on the determined combined gas parameter.

Abstract: A process for manufacturing a transparent body for a touch screen panel is described. The process includes: depositing a first transparent layer stack over a flexible transparent substrate, wherein said first transparent layer stack includes at least a first dielectric film with a first refractive index, and a second dielectric film with a second refractive index different from the first refractive index; providing a transparent conductive film over the first transparent layer stack; depositing a layer of a conductive material over the transparent conductive film; providing a polymer layer over the layer of a conductive material; imprinting a pattern, e.g. a 3D pattern, on the polymer layer; etching the layer of the conductive material based upon the pattern to form conductive paths for the touch screen panel; and etching the transparent conductive film based upon the pattern to form a structured transparent conductive pattern for touch detection.