Cracking of a laminated glass assembly having a device encapsulated therein during the manufacturing process is prevented. The laminated glass assembly includes a first and a second glass sheet; a first, a second and a third intermediate film interposed between the first and second glass sheets, in that order; an organic EL panel interposed between the first and second intermediate films and provided with a terminal member; and a first wiring member consisting of a metallic thin strip connected to the terminal member in a thickness-wise direction via a first solder; wherein at least one of the two glass sheets has a thickness of 1.0 mm to 1.6 mm; and at a connecting portion of the terminal member, the first solder and the first wiring member, the first wiring member has a thickness of 0.05 mm to 0.10 mm and a width of 3 mm to 15 mm, and the first solder has a thickness of 0.01 mm to 0.20 mm; and a total thickness of the terminal member, the first solder and the first wiring member is 0.16 mm to 0.40 mm.

An armor system configured to be coupled to a frame surrounding a window in a vehicle or other structure, such as a building. The armor system may be configured to provide any desired ballistics protection rating. The armor system includes a ballistics-grade armor panel and at least one insert embedded in the ballistics-grade armor panel. The insert extends around at least a portion of a periphery of the ballistics-grade armor panel. The one or more inserts may be configured to reduce the parasitic weight of the armor system.

A method of manufacturing a display device includes: providing a glass including an edge region and an inner region; arranging a light source under the glass; setting a center position of the light source to correspond to an inside of the edge region or an inside of the inner region of the glass; directing light into the glass by using the light source; and detecting a defect in the edge region of the glass by receiving light passing through the glass by using a detection camera.

Some embodiments of present disclosure are directed to a micro-perforated glass or glass-ceramics laminate, comprising a first substrate laminated to a second substrate by a first polymer interlayer, wherein the first and the second substrates are independently selected from glass or glass-ceramics, and a plurality of micro-perforations, each of the plurality of micro-perforations extending through the first substrate, the first polymer interlayer, and the second substrate. Some embodiments are directed to methods of forming such micro-perforated glass or glass-ceramics laminates.

To provide a laminated glass excellent in edge foaming resistance and rigidity. Laminated glass 1 in which a pair of glass plates and an intermediate film 4 provided between the pair of glass plates, are laminated, wherein the shear storage modulus of said intermediate film 4 is from 2 to 100 MPa, and the outer peripheral edge of the intermediate film 4 is present inside than the outer peripheral edges of the two glass plates constituting said pair of glass panels, at least at a part of the entire outer periphery of the laminated glass 1.

A wired glazing is disclosed comprising a ply of interlayer material, having a first busbar and an auxiliary busbar and heating wires between them. An adhesive layer is arranged between the first busbar and the ply of interlayer material. An auxiliary adhesive layer is arranged where an edge of the auxiliary busbar extends beyond an edge of the first busbar. The auxiliary adhesive layer bonds the auxiliary busbar to the ply of interlayer material. A corresponding process for manufacturing a wired glazing is disclosed.

An electrical connection member shaped as a foil for feeding power to an electrical functional part arranged between a first platelike body and a second platelike body that form a laminated plate includes a connection portion located between the first platelike body and the second platelike body, and electrically connected to the electrical functional part; a feeding portion that is extended from the connection portion; and a folded portion formed between the connection portion and the feeding portion, and configured to cover at least a part of an edge portion of the first platelike body or the second platelike body. The folded portion includes a portion of increased cross-sectional area.

A laminated pane having at least one integrated electrical attachment part, includes an inner pane having an inner side and an outer side, an outer pane having an inner side and an outer side, a thermoplastic intermediate layer, which joins the inner side of the outer pane and the inner side of the inner pane to one another, and at least one recess in the inner pane and/or the outer pane, wherein the electrical attachment part is inserted into the recess and is situated completely within the laminated pane, the laminated pane is a vehicle laminated pane having a three-dimensional bend, and the recess is introduced into the inner pane and/or the outer pane by laser processes.

It is now possible to economically produce, in series production, automotive glazing that has complex small radii feature lines (30). Such feature lines (30) are desirable as they can improve the stiffness of the glazing as well as contribute to the overall aesthetic and differentiation of the vehicle, allowing body lines to blend into and continue in the glazing. However, traditional automotive laminating methods do not lend themselves well to this type of product. Typically, the offset between the mating surfaces of the laminate must be very uniform. Such uniformity is difficult to achieve when producing small radii features. Rather than bending multiple layers with small radii feature lines that can be nested and subsequently laminated using standard plastic automotive interlayers, the invention makes use of a two part method for laminating, a dry lamination process and a wet lamination process, which requires only that the feature lines (30) be present in the outer glass layer (201).

An interlayer film for laminated glass of the present invention comprises at least an absorption region in which a skin absorption energy rate (X1) of a laminated glass is 25% or less, provided that the laminated glass is produced using two clear glass plates having a solar transmittance of 87.3% based on JIS R 3106.