A multi-pane glass unit includes a first outer glass pane and a second outer glass pane facing each other, a first inner glass pane between the first outer glass pane and the second outer glass pane, a first spacer located between the first outer glass pane and the first inner glass pane, and a second spacer located between the second outer glass pane and the first inner glass pane.

The invention provides a glazing comprising first glass sheet comprising a printed layer on a portion of a surface of the glass sheet and a conductive coating on the surface of the first glass sheet. The conductive coating extends over at least a portion of the printed layer to form a coated print portion and extends over a portion of the surface of the glass sheet to form a coated glass portion. The coated print portion has a Developed Interfacial Area Ratio Sdr less than 27.45%. A method for producing the glazing and use of the glazing in a vehicle is also disclosed.

The present invention provides an automobile window glass on which a device that acquires electromagnetic waves is disposable. The automobile window glass includes an outer glass plate, an inner glass plate, an intermediate film disposed between the outer glass plate and the inner glass plate, and a blocking layer that is disposed on at least one of a surface on the vehicle interior side of the outer glass plate and a surface on the vehicle interior side of the inner glass plate. The intermediate film includes a functional layer having a transmission region that allows transmission so as not to affect reception of the electromagnetic waves, and an adhesion layer that is disposed on at least one surface of the functional layer and does not affect reception of the electromagnetic waves. The blocking layer has at least one opening at a position corresponding to the transmission region.

The present invention aims to provide an interlayer film for a laminated glass that enables production of a laminated glass having high visible light transmittance even when deaeration for preliminary pressure bonding and heating for final pressure bonding are performed in parallel in a vacuum deaeration method. The present invention also aims to provide a method for producing the interlayer film for a laminated glass, and a laminated glass including the interlayer film for a laminated glass. Provided is an interlayer film for a laminated glass having a multitude of recesses on at least one surface, the surface with the recesses having a texture aspect ratio Str of 0.04 or lower as measured in conformity with ISO 25178.

An object of the present disclosure is to provide a window glass for vehicle that prevents intensity of light to be used in optical equipment attached to a vehicle from being attenuated, and that is easier to handle while having a component unit. A window glass for vehicle comprises: a laminated glass including a vehicle inner glass plate, a vehicle outer glass plate and an interlayer film; and a component unit. A vehicle inner glass plate is cut-out at a portion of the periphery of the laminated glass, and in the portion, the component unit is arranged. A vehicle inner surface of the laminated glass fits on the flush with a vehicle inner surface of the component unit, at least in a region, on a boundary between the laminated glass and the component unit.

Smart windows, on which the level of visible light transmission can be electrically switched, are produced by laminating a special switchable film between the two layers of a glass laminate The film is made by sandwiching an emulsion containing the switchable variable light transmission active material between a set of electrodes. One of the challenges of producing said laminates is preventing the migration of plasticizers and moisture from the plastic bonding layer of the laminate into the emulsion where it can degrade performance. By applying a sealing member to each electrode layer along the periphery the emulsion is protected and in a manner that facilitates automation of the process.

A light-emitting window element includes a transparent first carrier layer, a transparent second carrier layer, a substrate with a plurality of light-emitting semiconductor chips arranged thereon, and an optical layer having an adjustable transparency. The substrate with the plurality of light-emitting semiconductor chips and the optical layer are arranged between the first and second carrier layers, and the first and second carrier layers, the substrate with the plurality of light-emitting semiconductor chips and the optical layer form a laminate composite.

A glass with a function of regulation in sections includes a glass body and a conductive component. The glass body includes a glass substrate and a functional component attached to the glass substrate and divided into sections capable of being individually regulated. The conductive component is coupled to each section of the functional component. The conductive component includes a flexible printed circuit and a conductive adhesive. The flexible printed circuit includes a conductive trace electrically connected to each section of the functional component via the conductive adhesive to allow an individual regulation of each section of the functional component. The glass with a function of regulation in sections is capable of regulating a function of a target section of the functional component according to a user's instruction and an environmental parameter.

A glass unit for an illuminated vehicle roof including a glass pane, a glass primer layer, and a polyurethane layer. The glass pane is provided, on one side, with the glass primer layer, wherein a polyurethane layer is in turn applied to the glass primer layer.

The present invention pertains to a laminated glass for a vehicle, the laminated glass including a first glass sheet, a second glass sheet and an intermediate film sandwiched between the first glass sheet and the second glass sheet, in which: the total thickness of the first glass sheet, the second glass sheet and the intermediate film is 4.0 mm or more; the first glass sheet is formed of a borosilicate glass containing, in terms of oxide by molar percentage, 1.0% or more of B.sub.2O.sub.3; and when a radio wave (TM wave) with a frequency of 79 [GHz] is made incident at an incident angle of 60° to the first glass sheet, the transmission property S21 is -4.0 [dB] or more.