A laminated pane, includes an outer pane, an inner pane, and at least two intermediate layers, wherein at least two separate functional elements with electrically controllable optical properties are arranged in a plane between the two intermediate layers, wherein on two opposite sides of each functional element, an inner bus bar is connected in each case to the respective functional element and at least one of the two opposite sides of each functional element is sealed by two PET barrier films, which are partly arranged between an intermediate layer and the functional element, wherein attached on one of the PET barrier films is at least one outer bus bar that is connected via an electrically conducting connection to the inner bus bar of a functional element, in order to electrically control the functional element separately from the other functional element or elements.

A display cover is provided. The display cover includes a first glass and a second glass; a carbon material layer disposed between the first glass and the second glass, wherein the carbon material layer is formed by simultaneously applying a heat treatment process to an organic adhesive layer, the first glass, and the second glass to carbonize the organic adhesive layer. The structural strength of display cover can be strengthened by placing a carbon material layer between two glass layers to achieve a strong chemical bond between the thin carbon material layer disposed between the two glass layers and the two glass layers.

A method for manufacturing a laminated glass whereby, in a laminated glass comprising a liquid crystal film sandwiched therein and having a three-dimensionally curved surface shape, the formation of wrinkles in the liquid crystal film can be suppressed; and a laminated glass which has a three-dimensionally curved surface shape and in which wrinkles in a liquid crystal film sandwiched therein are suppressed. The method for manufacturing the laminated glass comprises: a heat molding step for heating the liquid crystal film to a temperature higher than the glass transition point of the first base material layer and the second base material layer; and a bonding step for, after completing the heat molding step, heating the laminate, wherein the liquid crystal film is sandwiched between the first glass sheet and the second glass sheet, at a temperature lower than the glass transition point and bonding the same by applying a preset pressure.

An object of the present disclosure is to provide a laminate panel in which a transparent colored layer is formed with a decorative sheet on a base substrate such as a resin plate or glass; and a display panel using the laminate panel and to provide a method of manufacturing the display panel.

The laminate panel includes a base substrate formed of a resin plate or glass plate, an adhesive layer formed on the base substrate, a transparent colored layer formed on the adhesive layer, and a surface protection layer formed on the transparent colored layer. The display panel is applied, for example, as an in-vehicle display panel.

A method for producing a composite pane with a functional element having electrically controllable optical properties, includes providing a first pre-composite including a first thermoplastic laminating film and a first barrier film as well as a second pre-composite including a second thermoplastic laminating film and a second barrier layer trimming and the pre-composites substantially to the dimensions of the composite pane, forming a circumferential back cut in the barrier films, arranging the first pane, the first pre-composite, a functional element, the second pre-composite, and a second pane one over another in this order, the barrier films being arranged sheet-wise directly adjacent the functional element, surrounding the circumferential edge of the functional element, and touching one another sheet-wise at least in sections in an overhang u protruding beyond the functional element, and bonding the layer stack.

A laminated glazing for a vehicle provided with an inscription includes an interior glass sheet and an exterior glass sheet, each including an inner face and an outer face, and including, between the inner faces of the two glass sheets, an interlayer including at least two outer layers in a material selected from polyvinyl butyral (PVB), polyethylene vinyl acetate (EVA) and polyurethane (PU) and mixtures thereof, the outer layers being joined by a functional element (4) of liquid crystals dispersed in a polymer matrix. The functional element includes a liquid crystal active layer between two electrically conductive layers, themselves disposed between two carrier films. The inscription is a semi-transparent reflective layer and the inscription is printed on the exterior glass sheet on the outer face.

The present disclosure provides an electrochromic sunroof encapsulating a pre-assembled all solid-state flexible thin film ECDs and methods to fabricate the disclosed electrochromic sunroof. The electrochromic sunroof of the present disclosure provides great flexibility and can be adapted to virtually any curvature or shape without leaking concerns.

A laminate glass structure comprising a first glass sheet and a second glass sheet bonded together is provided. The first glass sheet of the laminate glass structure may include tuned light imaging detection and ranging sensor optical transmission characteristics and the second glass sheet may include a void area disposed in a portion thereof. The laminate glass structure can correspond to a laminate vehicle windshield that separates an interior cabin of the vehicle from an exterior of the vehicle. The laminate glass structure allows a light detection and ranging sensor to be mounted inside the interior cabin of the vehicle behind the void area providing a field of view of the sensor that is unobstructed by the second glass sheet. Light emitted and received by the sensor may only pass through the first glass sheet and not the second glass sheet.

An anti-fogging laminate including: a substrate; and an anti-fogging layer on the substrate where a surface of the anti-fogging layer is flat, wherein the anti-fogging layer includes a hydrophilic molecular structure; and wherein the anti-fogging layer has an elastic recovery of 90% or more, a coefficient of dynamic friction of 0.40 or less, and an average thickness of 4 m or more.

The present invention relates to a double glazed window of a polycarbonate layer and, specifically, to a double glazed window of a polycarbonate layer, comprising an outer glass layer and an inner polycarbonate layer so as to have improved heat insulation and earthquake resistance. The double glazed window of a polycarbonate layer comprises: a glass layer forming an outer layer; a polycarbonate layer forming an inner layer; a vacuum layer (VL) formed between the glass layer and the polycarbonate layer; and sealing means for sealing the VL while coupling the glass layer and the polycarbonate layer.