A composite window film may include a first window facing substrate, a reflecting stack and an absorbing stack. The reflecting stack may be located between the first window facing substrate and the absorbing stack. The composite window film may have a VLT not greater than about 80%, a TSER of at least about 40%, and an Energetic Absorption (EA) of not greater than about 50%.

The present invention is directed to thermoformed packaging articles comprising a coextruded film having alternating individual layers of glass and plastic. These thermoformed packaging articles may be used for packaging oxygen- and/or moisture sensitive foods and pharmaceutical/medical/dental products.

Peelable polymeric film, in particular, peelable polymeric film which comprises a polymeric substrate layer and a coating layer of adhesive, and which is of particular use in the manufacture of electronic devices is described. The adhesive layer is derived from an aqueous composition which comprises an aliphatic polyurethane and is switchable.

A window assembly for a vehicle includes a plurality of window panels arranged with at least one pair of adjacent window panels, with adjacent edge portions of adjacent ones of the window panels joined by a respective molded joining element. The adjacent edge portions joined by a respective molded joining element are offset or non-coplanar. The molded joining element may comprise an encapsulation that at least partially receives a perimeter edge portion of at least one of the adjacent window panels. The molded joining element may at least partially receive a rear perimeter edge portion of a forward window panel and may not overlap an outer surface of the forward window panel, with the molded joining element at least partially receiving a front perimeter edge portion of a rearward window panel.

The present disclosure relates generally to methods for the integration of electrochromic films onto a substrate, such as a glass window, and the systems/structures formed via such methods.

The invention relates to a panel comprising (i) at least a first (100) outer and a second (200) inner glass sheet, each comprising an inner and an outer face, combined together by a means (220) of maintaining the two glass sheets at a certain distance between the two glass sheets (100, 200) and (ii) at least one electroluminescent mean (302) provided between the at least a first (100) and a second glass sheet (200) and arranged on the surface of the inner face (201) of the second (200) inner glass sheet. According to the invention, at least one recess (310) is provided in the first glass sheet (100) and arranged face to face with one electroluminescent mean provided on the surface of the inner face (201) of the second glass sheet (200) and wherein a gasket (500) comprising light guiding mean is provided on the electroluminescent mean (302) and extends through the at least one recess (310).

There is provided a heat insulating window film disposed on the inside of a window, including at least: a support; and a fibrous conductive particles-containing layer disposed on the support, in which the fibrous conductive particles-containing layer is disposed on a surface of the support on a side opposite to the surface of the window side, and the heat insulating window film contains a near infrared shielding material. The heat insulating window film; a heat insulating window glass; an building material; a window; a building; and a vehicle which are manufactured at low cost, easily manufactured to have a large area, and have excellent visible light transmittance, shielding properties for near infrared light, heat insulating properties, and light resistance are provided.

The present invention provides an interlayer film for laminated glass provided with an up-conversion function so as to be able to display high-contrast images while ensuring safety, and a laminated glass. The present invention relates to an interlayer film for laminated glass, including lanthanoid-containing inorganic fine particles having an up-conversion function and a binder resin.

A laminate structure having a first chemically strengthened glass layer, a second chemically strengthened glass layer, and a polymer interlayer structure intermediate the first and second glass layers. The polymer interlayer structure can include a first polymeric layer adjacent to the first glass layer, a second polymeric layer adjacent to the second glass layer, and a polymeric rigid core intermediate the first and second polymeric layers.

Provided is a laminated glass (10), including: a core material (11) including a resin sheet (12); and a first glass sheet (13a) and a second glass sheet (13b) each being laminated on respective surfaces of the core material (11) via an adhesive layer (15a) or (15b). Each of thicknesses of the first glass sheet (13a) and the second glass sheet (13b) is smaller than a thickness of the core material (11). The first glass sheet (13a) has a cover sheet (14) made of a resin laminated on an outer surface thereof via an adhesive layer (15c). With this, the laminated glass has a light weight, and its partial breakage due to collision with a flying object can be suppressed. Each of the thicknesses of the first glass sheet (13a) and the second glass sheet (13b) is preferably or less of the thickness of the core material (11).