A reinforced glass composite screen which is relatively lightweight and provides relatively high strength and visibility. The glass composite is comprised of alternating layers of tempered glass, graphene, and/or plastics with an optional laminated layer of plastic in the case of directional specific impact to prevent shattering.

A glass structure for a vehicle includes an outer layer of glass, an inner layer of glass, and an interlayer stack disposed between opposing surfaces of the outer layer of glass and the inner layer of glass. The interlayer stack includes at least two interlayer substrates and at least one of the interlayer substrates includes a decorative treatment. In another example, the interlayer stack includes at least two interlayer substrates and at least one of the interlayer substrates includes a functional component.

A glass-resin composite of the present invention includes a plurality of glass sheets and a resin sheet which are integrally combined with each other via an organic resin intermediate layer, wherein, out of outer glass sheets of the plurality of glass sheets, at least one glass sheet has a crystallinity of 30% or less and a Young's modulus higher than a Young's modulus of its inner adjacent glass sheet by 5 GPa or more.

Lightweight ballistic glasses are provided that provide effective protection from ballistic attack while also being lightweight enough for use in armored vehicles and aircraft. In addition to other embodiments, a multilayered lightweight ballistic glass is provided that meets the CEN 1063 Level BR6 standard, has a weight of no greater than about 75 kilograms per square meter (kg/m.sup.2), and a total thickness less than about 40 mm.

Lightweight ballistic glasses are provided that provide effective protection from ballistic attack while also being lightweight enough for use in armored vehicles and aircraft. In addition to other embodiments, a multilayered lightweight ballistic glass is provided that meets the CEN 1063 Level BR7 standard while having a weight of no greater than about 155 kilograms per square meter (kg/m.sup.2), and a total thickness of less than about 75 mm.

A scratch and ultraviolet resistant film includes a polymer-carbon composite film configured to be applied as a thin film on a substrate. The polymer-carbon composite film includes a resin such as a thermoset resin and/or a thermoplastic resin, and between about 0.25 wt. % and about 5 wt. % graphene disposed in the resin. In addition, the polymer-carbon composite film applied as the thin film on the substrate has a thickness between about 0.2 mm and about 1 mm.

The present invention discloses a composite thermal insulator including a first transparent substrate layer, a second transparent substrate layer, and a near-infrared shielding layer positioned between the first transparent substrate layer and the second transparent substrate layer, and the near-infrared shielding layer is formed by dispersively fixing multiple nanoparticles containing tungsten oxide in polyethylene terephthalate. The composite thermal insulator can't change color under sunlight so that it can be used for light output controlling and thermal isolation.

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).

A method of forming ballistic glass includes heat forming a polycarbonate panel while the polycarbonate panel is sandwiched between a non-planar glass panel and a mold panel such that the polycarbonate panel is formed to a geometry of the glass panel. The polycarbonate panel is positioned adjacent the glass panel such that a volume of space is defined therebetween, and the volume of space is filled with a flowable resin. The resin is cured to form an intermediate polymer layer between the polycarbonate panel and the glass panel. Ballistic glass may be formed using such methods. Vehicles may include such ballistic glass.