A stencil for use in stenciling complex symbols incorporates a stencil substrate employing a flexible material, having a plurality of symbols arranged thereon. A plurality of folding stiffeners are incorporated in the substrate, each stiffener being positioned to split symbols having stencil cutouts forming isolated elements within an interior of the symbol. The stiffeners are foldable about a vertex, to collapse into a raised position and bring together the split symbol, with the stiffeners supporting the isolated elements created by the cutouts and portions of the stencil cutouts forming the symbols that extend into coincident channels in the folding stiffeners, to bridge adjoining portions of said split characters.

A kit for creating stencils is provided, including a polymeric shell, multiple linear polymeric frames, multiple thermoplastic rubber polymeric alphanumeric stencil elements, a rolling ball marker, and a roll of markable web. The polymeric shell has a tray and a hingedly joined sealing top. The tray is generally rectangular with a peripheral sidewall and has a storage compartment each for the web roll, the stencil elements, the frames, and the marker. The sidewall adjacent the web roll compartment has an opening therethrough. The frames have an elongate central planar portion and a pair of parallel upraised crenellated sidewalls with stencil retention elements defined in the crenels. The frames also have mateable elements defined at each end to join the frames together. The stencil elements fit between the frame sidewalls and have elongate projections with stencil retention elements adapted to mate with the stencil retention elements defined in the frame crenels.

Screen-printing system comprising a metal stencil (12), and a cloth (15) fixed to the entire periphery of said metal stencil (12) to form a trampoline assembly, characterized in that the cloth (15) fixed to the metal stencil (12) has at least one free end, in order to decrease or prevent deformation under the effect of a doctor blade (20).

A printing screen, comprising a sheet, at least sections of at least one pair of opposite edges of which are folded such as to define attachment elements, and a printing screen unit including at least one pair of interface members attachable to the attachment elements at the at least one pair of opposite edges of the sheet.

Provided is a printing plate, containing: a screen plate having an opening pattern; and, a frame body to which the screen plate is fixed, in which the screen plate includes at least one curved part and is relatively movably fixed to the frame body.

A printing screen and a sealant printing method are provided. The printing screen includes a frame, a mesh/screen fixed on the frame, and a film formed on the mesh. The portion of the mesh that is not covered by the film forms a feeding port in a rectangular ring shape. The rectangular ring includes two opposite first sides and two opposite second sides. The width of an upper opening of the cross section across the first sides is less than or equal to that of an upper opening of the cross section across the second sides. At a first height, the area of the cross section across the first sides is greater than that of the cross section across the second sides, the first height being less than the thickness of the film. The printing screen and the sealant printing method solve the problem of poor height uniformity of sealants.

A selective stencil mask and a stencil printing method are provided. The stencil mask is for printing a fluid material onto a substrate, and comprises: a stencil member comprising: at least one printing region each having an array of apertures that allow the fluid material to flow therethrough and deposit onto the substrate; and a blocking region configured to prevent the fluid material from flowing therethrough; and a supporting member attached to the stencil member and configured to, when the stencil mask is placed on the substrate, contact the substrate and create a gap between the stencil member and the substrate.

An alignment method for screen printing process includes: attaching a transparent film on a to-be-printed substrate in such a manner that the transparent film covers at least a to-be-printed region of the to-be-printed substrate, forming a printed pattern including an alignment mark on the transparent film by using a screen printing plate to imprint printed material onto the transparent film, and comparing whether the alignment mark on the transparent film is aligned with an alignment mark on the to-be-printed substrate. When the alignment mark on the transparent film is aligned with the alignment mark on the to-be-printed substrate, it is determined that current positions of the screen printing plate and the to-be-printed substrate are final alignment positions. When the alignment mark on the transparent film is not aligned with the alignment mark on the to-be-printed substrate, the current position of the screen printing plate or the to-be-printed substrate is adjusted.

A dual function tooling tray having a movable center section includes a perimeter frame having four sides, a first frame member spaced from a first side of the perimeter frame, and a second frame member spaced from a second side of the perimeter frame. The first side and the second side of the perimeter frame are parallel with one another. The tooling tray further includes a third frame member extending between and secured to the first frame member and the second frame member. The third frame member is configured to support at least one squeegee blade. The third frame member is configured be to be moved from a first position from the first frame member and the second frame member and installed in a second position on the first frame member and the second frame member, with the second position being spaced from the first position.

A printing screen for and method of printing elongate structures on substrates (S), the printing screen comprising first and second layers (3, 5) of different material, the first layer (3) providing a surface over which a printing element is in use traversed and including a plurality of elongate first printing apertures (7) across which extend a plurality of bridges (9) at spaced intervals, and the second layer (5) in use overlying the substrate (S) and including a plurality of elongate second printing apertures (15) through which printing medium is in use printed onto the underlying substrate (S), each of the second printing (15) apertures being located in registration with respective ones of the first printing apertures (7) in the first layer (3).