A composite pane with an electrically heatable camera window, which includes, inside the camera window, a first electrically conductive transparent coating for heating the camera window, wherein the first electrically conductive transparent coating is arranged on the first surface of the inner pane inside the camera window and has two busbars provided for connection to a voltage source, which are arranged on two opposite sides of the camera window such that when an electrical voltage is applied to the busbars, a current flows through the first electrically conductive transparent coating.

The present invention is a windshield for an automobile on which an information acquisition device configured to acquire information from the outside of a vehicle by emitting and/or receiving light can be arranged. The windshield includes: a laminated glass including an information acquisition region that is opposite to the information acquisition device and through which the light passes; and an antifog sheet in which at least a sticky layer, a substrate film, and an antifog layer are layered in this order, the sticky layer being attached to at least a surface on a vehicle interior side of the information acquisition region. The laminated glass includes at least one glass plate in which surface concentrations of tin oxide in two principal surfaces are different, and a surface of the glass plate in which the concentration of tin oxide is higher faces the vehicle interior side.

A coated glass article and a method for its production is disclosed. One or more coatings and layers are applied onto or disposed between a pair of glass sheets to produce such coated glass article that enhances an accuracy and reliability of a heads-up-display system and an optical sensor coupled thereto. More particularly, the coated glass article includes an antireflective layer to facilitate a light transmission of at least 80% for a plurality of wavelengths through the coated glass article and a visible light reflective layer to enhance a visible light reflectance of the coated glass article to between 8.0% and 10.0%.

A highly conductive transparent laminated glass article includes two glass plates and an adhesive film. The adhesive film has a material of Poly(Vinyl Butyral) (PVB) resin and is located between the two glass plates. At least one of the two glass plates is a highly conductive transparent glass-based circuit board with a glass substrate. A surface of the glass substrate is not contact with the adhesive film. A conductive paste, printed on the surface of the glass substrate, is baked, heated, and cooled to form a conductive circuit fused with the surface of the glass substrate. The surface of the glass substrate and an upper surface of the conductive circuit are at the same level. The highly conductive transparent laminated glass article has the characteristics of high conductivity and high light transmittance. The highly conductive transparent laminated glass article is suitable for fabrication, manufacture, and use of industrial and smart-home devices.

The present invention is a windshield for an automobile on which an information acquisition device configured to acquire information from the outside of a vehicle by emitting and/or receiving light can be arranged. The windshield includes: a laminated glass including an information acquisition region that is opposite to the information acquisition device and through which the light passes; and an antifog sheet in which at least a sticky layer, a substrate film, and an antifog layer are layered in this order, the sticky layer being attached to at least a surface on a vehicle interior side of the information acquisition region. The laminated glass includes at least one glass plate in which surface concentrations of tin oxide in two principal surfaces are different, and a surface of the glass plate in which the concentration of tin oxide is higher faces the vehicle interior side.

The present invention is a windshield for an automobile on which an information acquisition device configured to acquire information from the outside of a vehicle by emitting and/or receiving light can be arranged. The windshield includes: a laminated glass including an information acquisition region that is opposite to the information acquisition device and through which the light passes; and an antifog sheet in which at least a sticky layer, a substrate film, and an antifog layer are layered in this order, the sticky layer being attached to at least a surface on a vehicle interior side of the information acquisition region. The laminated glass includes at least one glass plate in which surface concentrations of tin oxide in two principal surfaces are different, and a surface of the glass plate in which the concentration of tin oxide is higher faces the vehicle interior side.

A glass laminate structure is disclosed with a first and a second glass ply and a printed polymer ply interposed between the first and second glass plies, the printed polymer ply may be of PVB or PET having nanoparticle-containing ink adhered to at least a portion of a surface. Optionally there may be at least one further polymer ply which may be of PVB, PVA, COP or TPU. The nanoparticle-containing ink may contain electrically conductive nanoparticles, especially silver nanoparticle-containing ink. Also disclosed is a process for producing such a glass laminate structure.

Polymer-based selective radiative cooling structures are provided which include a selectively emissive layer of a polymer or a polymer matrix composite material. Exemplary selective radiative cooling structures are in the form of a sheet, film or coating. Also provided are methods for removing heat from a body by selective thermal radiation using polymer-based selective radiative cooling structures.

A highly conductive transparent laminated glass article includes two glass plates and an adhesive film. The adhesive film has a material of Poly(Vinyl Butyral) (PVB) resin and is located between the two glass plates. At least one of the two glass plates is a highly conductive transparent glass-based circuit board with a glass substrate. A surface of the glass substrate is not contact with the adhesive film. A conductive paste, printed on the surface of the glass substrate, is baked, heated, and cooled to form a conductive circuit fused with the surface of the glass substrate. The surface of the glass substrate and an upper surface of the conductive circuit are at the same level. The highly conductive transparent laminated glass article has the characteristics of high conductivity and high light transmittance. The highly conductive transparent laminated glass article is suitable for fabrication, manufacture, and use of industrial and smart-home devices.

A colored photovoltaic (PV) module or roof tile including a layer of highly stable nanoparticles provides uniform, angle-independent viewer color. The nanoparticles can comprise a metal oxide such as zinc oxide, titanium dioxide, or iron oxide. The nanoparticles can have composition and/or size tuned to absorb wavelengths of light reflected from PV cells, effectively concealing their appearance, and tuned to scatter wavelengths in a desired color range. The disclosed embodiments can provide better color uniformity and better efficiency, and be more cost-effective, than existing approaches for manufacturing colored PV modules. During the manufacturing process, a coating system, which may include one or more nozzles, can spray an inside surface of a glass cover with nanoparticles, which can be suspended in a solvent (such as water or isopropyl alcohol). The nanoparticle layer can then be encapsulated directly inside an encapsulant layer.