The disclosure provides a method for manufacturing a heat insulated PVB film, in which insulated nanoparticles with a particle diameter of 1-800 nm are added in the manufacturing process of PVB film to allow production of a PVB film with high insulation and transmittance. The disclosure also provides a method for manufacturing heat insulated blast-resistant glass, in which two panes of glass are laminated and bound by the PVB film to obtain blast-resistant glass with high insulation and high transmittance. The method for manufacturing heat insulated blast-resistant glass needs not applying an additional insulation coating or insulation film on conventional glass products and therefore allows manufacturing process to be simplified and manufacturing costs to be reduced.

A process for preparing a laminated glazing comprises providing a first glass sheet formed into a desired shape with a first thickness by a first procedure and providing a second glass sheet formed into a desired shape with a second thickness by a second procedure with an interlayer located therebetween, and laminating together the first and second glass sheets and the interlayer at a temperature and pressure sufficient to adhere the interlayer material to the glass sheets and in which the process further comprises applying a mould which is shaped substantially the same as the first glass sheet, against the second glass sheet, during laminating to adhere the interlayer material to the two glass sheets such that after lamination, the shape of the second glass sheet is substantially the same as the shape of the first glass sheet.

A method for producing a composite pane includes arranging a first, second and third thermoplastic intermediate layers in full surface contact one above the other, the first, second and third thermoplastic intermediate layers; joining the first, second and third thermoplastic intermediate layers to form a preliminary composite; removing the third thermoplastic intermediate layer from certain regions to form an aperture; forming a layered stack by inserting a functional element into the aperture in the third thermoplastic intermediate layer; arranging the layered stack between a first and second pane; and the joining the first and second panes by lamination via the layered stack. The functional element has a thickness of 50 m. The third thermoplastic intermediate layer has a thickness that substantially corresponds to the thickness of the functional element. The outer dimensions of the aperture substantially correspond to the outer dimensions of the functional element.

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 light modulating device includes a first transparent substrate, a second transparent substrate, a light modulating cell disposed between the first transparent substrate and the second transparent substrate, a first bonding layer disposed between the first transparent substrate and the light modulating cell, and a second bonding layer disposed between the second transparent substrate and the light modulating cell. The first bonding layer and the second bonding layer each are a bonding element containing a non-pressure-sensitive adhesive component. The first bonding layer is an OCR, and the second bonding layer is an OCA.

A composite pane includes an outer pane and an inner pane that are joined to one another via a thermoplastic intermediate layer, wherein the composite pane has at least one functional film that contains at least one metal layer, and the thermoplastic intermediate layer is formed with at least one thermoplastic film that contains refractive-index-reducing agents and these refractive-index-reducing agents reduce the refractive index of the thermoplastic film by at least 0.05 in the optically visible range between 380 nm and 780 nm.

To provide a laminated glass in which color shading of an optical member is reduced, and a method for producing it. A laminated glass comprising a first glass plate, a second glass plate facing the first glass plate, and between the first glass plate and the second glass plate, a light control member to which a power feeder is connected, a bonding portion and a sealing member, wherein the sealing member overlaps with at least a part of the periphery of the first glass plate, in a plan view, the bonding portion is in contact with the first glass plate, the second glass plate, and a first principal surface, a second principal surface and side surfaces of the light control member, and the bonding portion contains a curable transparent resin.

The principles and embodiments of the present disclosure relate generally to complexly curved laminates made from a complexly curved substrate and a flat substrate, such as automotive window glazings, and methods of cold forming complexly-curved glass products from a curved substrate and a flat substrate. In one or more embodiments, the laminate includes first complexly-curved glass substrate with a first surface and a second surface opposite the first surface, a second complexly-curved glass substrate with a third surface and a fourth surface opposite the third surface with a thickness therebetween; and a polymer interlayer affixed to the second convex surface and third surface, wherein the third surface and fourth surface have compressive stress values respectively that differ such that the fourth surface has as compressive stress value that is greater than the compressive stress value of the third surface.

A reinforcement structure includes an adherend, such as a metal plate, and a reinforcement sheet adhering thereto. The reinforcement sheet includes a front layer containing a plurality of fibers, a core material layer, and an adhesive layer. The reinforcement structure is capable of intensively reinforcing a first corner portion of the adherend and obtaining an improvement in strength.

A method includes pressing a stack including a glass sheet and an uncured non glass mat at a pressing pressure and a pressing temperature, whereby the uncured nonglass mat is cured and bonded to the glass sheet to form a glass laminate including the glass sheet bonded to a non glass substrate. Another method includes pressing a stack including a glass sheet and a plurality of uncured polymer impregnated papers at a pressing pressure and a pressing temperature, whereby the plurality of uncured polymer impregnated papers is cured to form a non glass substrate and bonded to the glass sheet to form a glass laminate.