The laminated structure of the present invention includes a sheet-shaped member and first and second transparent sheets provided on both sides, respectively, of the sheet-shaped member, wherein the sheet-shaped member absorbs excitation light and emits light with wavelength conversion, and has a maximum emission wavelength of 500 nm or more, and a reflectance that is measured for the laminated structure at the maximum emission wavelength is 30% or more.

A viscoelastic plastic interlayer intended to be arranged between two glass sheets of a glazing in order to provide it with vibroacoustic damping properties, includes two outer layers of thermoplastic adhesive, an inner layer arranged between the two outer layers, the inner layer having a loss factor tan greater than or equal to 1.6 at 20 C. and for a frequency range of between 2 kHz and 8 kHz, and first and second barrier layers arranged respectively between the outer layers and the inner layer 3, and composed of a viscoelastic plastic material.

Provided are a far infrared reflective film including a support, and a fibrous silver particles-containing layer provided on the support, in which the fibrous silver particles-containing layer includes fibrous silver particles, and a sol-gel hardened material obtained by hydrolysis and polycondensation of a metal coupling agent including a functional group capable of interacting with the fibrous silver particles, and an alkoxide compound, which has excellent heat insulating properties, film hardness, and surface properties; a dispersion for forming a far infrared reflective film; a manufacturing method of a far infrared reflective film; a far infrared reflective glass; and a window.

It is possible to prevent the appearance of laminated glass from deteriorating due to wrinkles formed in a functional layer of an intermediate film disposed between two curved glass plates. Laminated glass for an automobile is provided. Laminated glass according to the present invention includes an outer glass plate, an inner glass plate disposed opposite to the outer glass plate, and an intermediate film disposed between the outer glass plate and the inner glass plate. The outer glass plate and the inner glass plate are curved in a horizontal direction and a vertical direction. The intermediate film includes a functional layer, and a bonding layer for fixing the functional layer between the two glass plates. At least one notch or cut extending from the edge of the functional layer is formed in the functional layer.

An electro-optic window is provided, together with a method of manufacturing the window. The window (3) is made of a material substantially transparent to at least one of infra-red, visible and UV radiation and treated to have reduced RF/MICROWAVE transmission characteristics by the provision of a grid (1) set into at least one surface (2) thereof. The grid (1) is formed of a material selected to be either reflective or absorptive to RF/MICROWAVE radiation.

A laminated glazing of a vehicle includes a first extra clear glass sheet (exterior glazing), a lamination interlayer and a second glass sheet (interior glazing) with two through-holes in this second sheet.

A vehicle pane for a head-up display having, in the installed state, an outer side facing external surroundings and an inner side facing a vehicle interior, includes at least one transparent pane, at least one first masking strip in an edge region of the pane, wherein the at least one first masking strip is arranged on or in a carrier film and, in particular, is printed on the carrier film or embedded in the carrier film, and the carrier film is bonded to the at least one transparent pane, and at least one light-deflecting device for deflecting light into the vehicle interior or at least one image display device for displaying image information, which is arranged in the region of the masking strip, on the vehicle-interior side of the masking strip.

A composite pane having an electrically conductive coating includes an outer pane having an outer-side surface and an interior-side surface and an inner pane having an outer-side surface and an interior-side surface, wherein the interior-side surface of the outer pane and the outer-side surface of the inner pane are connected to one another by a thermoplastic intermediate layer, and wherein, between the interior-side surface of the outer pane and the outer-side surface of the inner pane, at least: the electrically conductive coating and at least one layer of selectively absorbing nanoparticles having an absorption within the wavelength range of 580 nm to 750 nm are arranged.

A laminated glass includes a first glass plate, a second glass plate, and an interlayer disposed between the first glass plate and the second glass plate to bond the first glass plate and the second glass plate; the laminated glass partly having a first area configured to be used by a head-up display; the first glass plate having a 4th surface disposed on an opposite side of the interlayer, and a 3rd surface facing the interlayer; the second glass plate having a 2nd surface facing the interlayer and a 1st surface disposed on an opposite side of the interlayer; the first area having a P-polarized light reflective layer disposed on the 4th surface and a light-absorbing layer disposed at a position closer to the 1st surface than the P-polarized light reflective layer; the laminated glass being configured such that the formula of A?85% is satisfied wherein the total of a visible light transmittance of the P-polarized light reflective layer and a visible light transmittance of the light-absorbing layer is Tv %, the total of a visible light reflectance of the P-polarized light reflective layer and a visible light reflectance of the light absorbing layer is Rv %, and an absorption A is equal to 100?Tv?Rv (%); and the laminated glass being configured such that the formula of Rvp?5% is satisfied wherein the total of a P-polarized light reflectance of the P-polarized light reflective layer and a P-polarized light reflectance of the light-absorbing layer is Rvp % when P-polarized light is incident on the surface of the laminated glass facing the P-polarized light reflective layer at an incident angle of 57 deg.

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.