A shadow mask for patterned vapor deposition of an organic light-emitting diode (OLED) material includes a ceramic membrane under tensile stress with a plurality of through-apertures forming an aperture array through which a vaporized deposition material can pass. A multilayer peripheral support is attached to a rear surface with a hollow portion beneath the aperture array. A compressively-stressed interlayer balances the tensile stress of the ceramic membrane. A shadow mask module with multiple shadow masks is also provided and includes a rigid carrier having plural windows with a shadow mask positioned in each window. To make the module, shadow mask blanks are affixed to each carrier window followed by etching of apertures and support layers. In this way extremely flat masks with precise aperture patterns are formed.

A system or machine is disclosed which takes pre-stretched emulsion coated screens, digitally prints thereon and exposes them before further processing and use in a screen printing machine.

A system or machine is disclosed which takes pre-stretched emulsion coated screens, digitally prints thereon and exposes them before further processing and use in a screen printing machine.

A photosensitive resin printing plate precursor includes at least a support and a photosensitive resin layer, wherein the photosensitive resin layer contains at least a polymer (A) having an ethylenic double bond, a compound (B) having an ethylenic double bond, and a photopolymerization initiator (C); wherein the photosensitive resin layer includes at least a first photosensitive resin layer including a printing surface, and a second photosensitive resin layer including the interior of the photosensitive resin layer; and wherein the ethylenic double bond equivalent F1 (g/eq) of component (A) in the first photosensitive resin layer is higher than the ethylenic double bond equivalent F2 (g/eq) of component (A) in the second photosensitive resin layer.

A photosensitive resin printing plate precursor includes at least a support and a photosensitive resin layer, wherein the photosensitive resin layer contains at least a polymer (A) having an ethylenic double bond, a compound (B) having an ethylenic double bond, and a photopolymerization initiator (C); wherein the photosensitive resin layer includes at least a first photosensitive resin layer including a printing surface, and a second photosensitive resin layer including the interior of the photosensitive resin layer; and wherein the ethylenic double bond equivalent F1 (g/eq) of component (A) in the first photosensitive resin layer is higher than the ethylenic double bond equivalent F2 (g/eq) of component (A) in the second photosensitive resin layer.

A method for collimating a beam of material being deposited on a substrate at a deposition area of the substrate is disclosed. The substrate is masked with a stencil mask located at a mask distance from the substrate, the mask distance being the distance between a top face of the substrate and an outer face of the mask facing the substrate. The beam is projected from a source cell located at a source distance from the mask, the source distance being the distance between the source cell and an outer face of the mask facing the source cell. The stencil mask comprises two mask layers separated by a layer separation distance which is great than zero. Each mask layer comprises a slit, the slits of the two layers having a width being aligned in a plane of the substrate.

A method for collimating a beam of material being deposited on a substrate at a deposition area of the substrate is disclosed. The substrate is masked with a stencil mask located at a mask distance from the substrate, the mask distance being the distance between a top face of the substrate and an outer face of the mask facing the substrate. The beam is projected from a source cell located at a source distance from the mask, the source distance being the distance between the source cell and an outer face of the mask facing the source cell. The stencil mask comprises two mask layers separated by a layer separation distance which is great than zero. Each mask layer comprises a slit, the slits of the two layers having a width being aligned in a plane of the substrate.

The present disclosure provides a mask plate and fabrication method thereof. The mask plate includes a substrate, having a first surface and a second surface, and containing a plurality of openings. The mask plate also includes a mask pattern layer, formed on the first surface of the substrate and including a plurality of pattern regions and a shield region surrounding the plurality of pattern regions. Each pattern region includes at least one through hole, and each opening formed in the substrate exposes a pattern region and the at least one through hole in the pattern region. The mask plate further includes a top substrate layer, formed on the mask pattern layer. The top substrate layer contains a plurality of grooves passing through the top substrate layer, and each groove exposes a pattern region in the mask pattern layer and exposes the at least one through hole in the pattern region.

An apparatus for securing a printing screen frame is configured so that, when a piston rod moves backward due to the supply of air pressure, tensile force applied to a support frame of a printing screen unit by a coupling protrusion of a tension member is released and the printing screen unit can be replaced, and, when the piston rod moves forward as an elastic spring extends due to the stop of the supply of the air pressure, the coupling protrusion of the tension member is caught on the support frame of the printing screen unit and applies pressure thereto due to elastic force so as to tension the printing screen, and then reverse pressure can be applied thereto by using air pressure, as needed.

An apparatus for securing a printing screen frame is configured so that, when a piston rod moves backward due to the supply of air pressure, tensile force applied to a support frame of a printing screen unit by a coupling protrusion of a tension member is released and the printing screen unit can be replaced, and, when the piston rod moves forward as an elastic spring extends due to the stop of the supply of the air pressure, the coupling protrusion of the tension member is caught on the support frame of the printing screen unit and applies pressure thereto due to elastic force so as to tension the printing screen, and then reverse pressure can be applied thereto by using air pressure, as needed.