Disclosed is a screen printing plate (5) for manufacturing a crystalline silicon solar cell, a positive electrode of the crystalline silicon solar cell comprising a positive electrode busbar (1), a positive electrode grid (2) and a break-proof grid structure (3), wherein the screen printing plate (5) is used at least for integrally printing and forming the positive electrode grid (2) and the break-proof grid structure (3). The screen printing plate (5) is provided with a blocking portion for blocking the passage of a paste, the blocking portion is a photosensitive emulsion (6) or a non-photosensitive emulsion, and the blocking portion corresponds to the break-proof grid structure (3) of the positive electrode and is used for forming a hollow-out groove (4) in the break-proof grid structure (3) when the positive electrode is printed. The blocking portion is positioned such that the hollow-out groove (4) is formed in a portion of the break-proof grid structure (3) between the positive electrode busbar (1) and the positive electrode grid (2).

To provide a mesh member such that a static charge can be suppressed. Provided is a mesh member including a mesh woven fabric and a coating layer that is formed on the surface of the mesh woven fabric and contains a carbon nanotube and/or graphene.

Disclosed herein are a system and method for producing paint templates for painting a design on a target surface. The system includes a processor configured to generate a geo-file of paint template designs. The processor includes a design module configured to parse the design into a set of paint sub-designs and a template design module configured to generate the geo-file of paint template designs based on the set of paint sub-designs. The generated geo-file of paint template designs includes a paint template design that corresponds to a paint sub-design. The system further includes a plotter configured to produce a set of paint templates based on the geo-file of paint template designs. Each paint template design includes a set of alignment marks and each paint template is produced with a set of alignment apertures corresponding to the set of alignment marks.

Disclosed herein are a system and method for producing paint templates for painting a design on a target surface. The system includes a processor configured to generate a geo-file of paint template designs. The processor includes a design module configured to parse the design into a set of paint sub-designs and a template design module configured to generate the geo-file of paint template designs based on the set of paint sub-designs. The generated geo-file of paint template designs includes a paint template design that corresponds to a paint sub-design. The system further includes a plotter configured to produce a set of paint templates based on the geo-file of paint template designs. Each paint template design includes a set of alignment marks and each paint template is produced with a set of alignment apertures corresponding to the set of alignment marks.

A method for forming a semiconductor device is provided. The method includes providing a substrate, placing a first stencil having a first openwork pattern on the substrate, applying a first material onto the substrate through the first stencil, and removing the first stencil from the substrate. The first material includes a transparent material. The method also includes placing a second stencil having a second openwork pattern on the substrate, applying a second material onto the substrate through the second stencil, and removing the second stencil from the substrate. The second material includes a light-shielding material, and the second openwork pattern is different from the first openwork pattern.

A method for forming a semiconductor device is provided. The method includes providing a substrate, placing a first stencil having a first openwork pattern on the substrate, applying a first material onto the substrate through the first stencil, and removing the first stencil from the substrate. The first material includes a transparent material. The method also includes placing a second stencil having a second openwork pattern on the substrate, applying a second material onto the substrate through the second stencil, and removing the second stencil from the substrate. The second material includes a light-shielding material, and the second openwork pattern is different from the first openwork pattern.

An adhesive containing at least one selected from the group consisting of a urethane prepolymer and a polyol, a polyisocyanate, a polymerizable (meth)acrylate compound, and a photopolymerization initiator is disclosed. A heat-sensitive screen master and a method for producing a heat-sensitive screen master are also disclosed.

A screen-printing screen for printing electrically conductive patterns on glass sheets, includes a main mask, the aperture size of the main mask being larger in a lateral portion than in the central portion, the screen furthermore including, in at least one double-mask zone, located in the central portion, at least one secondary mask fastened to a face of the main mask, the aperture size of the or each secondary mask being larger than the aperture size of the main mask in the central portion, and the mesh of the or each secondary mask making, with the mesh of the main mask, an angle α comprised between 1 and 89°.

Embodiments of the invention include a breast nipple areola complex tattoo stencil comprising first, second and third stencil sections. The first stencil section defines an areola area. The second stencil section defines a nipple area and tubercle areas. One or more registration elements on the first and/or second stencil sections enable registration of the second stencil section to the first stencil section. The third stencil section defines one or both of a nipple shading area and a nipple highlight area. One or more registration elements on the third and/or second stencil sections enable registration of the third stencil section to the second stencil section.

Embodiments of the invention include a breast nipple areola complex tattoo stencil comprising first, second and third stencil sections. The first stencil section defines an areola area. The second stencil section defines a nipple area and tubercle areas. One or more registration elements on the first and/or second stencil sections enable registration of the second stencil section to the first stencil section. The third stencil section defines one or both of a nipple shading area and a nipple highlight area. One or more registration elements on the third and/or second stencil sections enable registration of the third stencil section to the second stencil section.