A laminated includes two bent glass substrates, a polymer interlayer between the glass substrates, and a notch or orifice cut in an entire thickness of the glazing. The glazing includes a border of compressive edge stresses obtained by general controlled cooling of the substrates in a paired state so that compressive stresses are generated at the border, and a local compression zone, different from the border, and obtained by local controlled cooling of a local area of a main surface of the glazing so that compressive stresses are generated in theid local compression zone. The notch or orifice is located in the local compression zone and made in the substrates in a paired state after forming the local compression zone so that cut contours of the substrates in the notch or orifice have a perfect superposition. The compressive edge stresses of the cut contours are greater than 4 MPa.

Resin layers and interlayers exhibiting enhanced adhesion to inorganic surfaces, such as glass, are provided. In some cases, the layers and interlayers may comprise at least one adhesion stabilizing agent for improving adhesion to various surfaces, even in the presence of moisture. Such layers and interlayers may be useful, for example, in multiple layer panels, such as, for example, safety glass used in automotive and architectural applications.

Disclosed herein are methods for making asymmetric laminate structures and methods for reducing bow in asymmetric laminate structures, the methods comprising differentially heating the laminate structures during lamination or differentially cooling the laminate structures after lamination. Also disclosed herein are methods for reducing bow in asymmetric laminate structures, the methods comprising subjecting at least one substrate in the laminate structure to asymmetric tempering or annealing prior to lamination. Further disclosed herein are laminate structures made according to such methods.

Resin layers and interlayers exhibiting enhanced adhesion to inorganic surfaces, such as glass, are provided. In some cases, the layers and interlayers may comprise at least one adhesion stabilizing agent for improving adhesion to various surfaces, even in the presence of moisture. Such layers and interlayers may be useful, for example, in multiple layer panels, such as, for example, safety glass used in automotive and architectural applications.

A method for manufacturing a laminated glass panel, which includes at least two glass substrates and at least one intermediate layer made of a polymeric material arranged between the substrates, the method including in the following order: the bending of the substrates; the controlled cooling of the substrates; and the formation of a laminated assembly that includes the substrates and the intermediate layer; the cutting of the laminated assembly straight through the entire thickness thereof along a line on one of the main surfaces thereof, the controlled cooling including general controlled cooling and local controlled cooling of an area that includes the cutting line, the local controlled cooling being faster than the general controlled cooling.

A method includes providing a first ply having a No. 1 surface and No. 2 surface. The method further includes heating the first ply, bending the first ply into a predetermined shape, providing a second ply having a No. 3 surface and No. 4 surface, and painting at least a portion of the No. 2 surface, No. 3 surface, or No. 4 surface to yield a painted portion. The method further includes applying a burn-off temporary layer over at least a portion of the painted portion, heating the second ply, bending the second ply into the predetermined shape, burning-off the burn-off temporary layer, providing an interlayer in between the first ply and second ply, heating and squeezing the first ply, second ply and interlayer together under a vacuum to remove any air trapped between the first ply and the second ply thereby forming the article, and cooling the article.

Certain example embodiments relate to techniques for creating flat laminated mirrors, e.g., for use in concentrating solar power (CSP) applications. In certain example embodiments, the first substrate is a low iron glass substrate. A reflective coating is provided between the first and second substrates. The first and second substrates are laminated together via a radiation curable laminating adhesive with the reflective coating between the substrates. In certain example embodiments the radiation curable laminating adhesive is cured via UV radiation in order to form a laminated reflective article.

A reinforced safety glass and its manufacturing procedure are presented. The invention uses a vehicle's original glass, which is generally tempered, eliminating need for a new specific glass. The invention utilizes films of diverse reinforcing materials to increase the final resistance of the product and therefore reinforcing the original glass. During its manufacturing process, an autoclave is used for applying pressure and temperature to bond the reinforcing films to the original glass and between each other. The invention comprises the original glass to which at least one PU film and one C-PET film are orderly applied, ate least to the interior face of the glass.

Certain example embodiments relate to techniques for creating flat laminated mirrors, e.g., for use in concentrating solar power (CSP) applications. In certain example embodiments, the first substrate is a low iron glass substrate. A reflective coating is provided between the first and second substrates. The first and second substrates are laminated together via a radiation curable laminating adhesive with the reflective coating between the substrates. In certain example embodiments the radiation curable laminating adhesive is cured via UV radiation in order to form a laminated reflective article.

Provided herein are projectile resistant glass treatment assemblies. The assemblies provide resistance to penetration of a glass pane by projectiles moving in a direction from the exterior to the interior of the glass pane.