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.

Provided are methods of forming graphene laminate compositions and architectures. The method comprises: (i) contacting a graphene structure comprising one or more planar graphene sheets with a first interlayer material; (ii) depositing of a conductive material, where in the conductive material is deposited along an edge of the graphene and one end of the first interlayer; and (iii) contacting the graphene structure with a second interlayer material. Also provided are graphene laminates structures comprising doped graphene films having improved mechanical strength, electrical mobility and optical transparency.

A ballistic glass assembly including a first glass layer and a second layer including a polyethylene terephthalate (PET) adhesive film. The ballistic glass assembly may also include an intermediate layer comprising a substantially transparent impact resistant material positioned between the first layer and the second layer. Methods of forming the ballistic glass assembly where the second layer and the intermediate layer match the contour of the first glass layer.

To provide a glass plate with resin frame and a method for producing a glass plate with resin frame, by which high gloss of a design surface with a color expressed by a decorative molding can be achieved. A glass plate 10 with resin frame, which comprises a glass plate 12, a resin frame 14 provided on a peripheral portion of the glass plate 12, and a decorative molding 16 disposed on the resin frame 14, the resin frame 14 being formed integrally with the glass plate 12 and the decorative molding 16, wherein the decorative molding 16 is a transparent design film, and when the glass plate 10 with resin frame is attached to a vehicle, the decorative molding 16 is disposed on the vehicle exterior side.

A ballistic glass assembly may include a first layer of a poly ethylene terephthalate (PET) adhesive film. The ballistic glass assembly may further include a second layer of glass. The ballistic glass assembly may also include a substantially transparent impact resistant material positioned on an opposite side of the second layer from the first layer.

An improved layered composite, as can be used, for example, as a multi-pane safety composite glass, and a method for the most bubble-free possible production thereof are described. The layered composite comprises a substrate, a cover layer, and a polymer layer arranged therebetween, wherein the polymer layer is bonded by means of adhesive layers to the substrate and the cover layer. The cover layer has a light transmittance according to DIN EN ISO 410 of 50%. The polymer layer has a tensile strength according to DIN EN ISO 527 of 30 MPa and the adhesive layers are layers of a cured reactive adhesive and/or radiation-curing adhesive.

Described is a telehandler having a cab (1) equipped with a roof (10) defined by a transparent or semi-transparent protective cover (11) which comprises one or more materials designed to withstand the falling of hazardous material for the safety of an operator onboard the cab (1). The cover includes a plurality of layers of which at least one layer made of glass and a layer made of polymeric material.

An automotive glazing that provides a portal (32) for receiving infrared radiation and an automotive glazing (40, 50) that defines an open pathway for infrared radiation between an infrared camera on one side of the glazing and a camera field of view on the other side of the glazing.

A glazing unit includes a stack of layers between a lower substrate and a transparent upper substrate. The stack of layers includes two dielectric layers, a lower layer and an upper layer, the lower layer including a first layer made of an adhesive material, referred to as first adhesive layer, an intermediate layer made of a polymer material, in contact with the first adhesive layer, and having a refractive index that is substantially identical to that of the upper layer, a central layer in contact, in a textured interface, with each of the intermediate and upper layers, the central layer being configured so that the glazing has diffuse reflection properties.

An automotive glazing that provides a portal (32) for receiving infrared radiation and an automotive glazing (40, 50) that defines an open pathway for infrared radiation between an infrared camera on one side of the glazing and a camera field of view on the other side of the glazing.