A disclosed laminated glazing comprises a first glass sheet, a first interlayer, a holographic film, a second interlayer having a light transmission of at least 70% at a light wavelength in the range of 250 nm to 400 nm, a second glass sheet, and an ultraviolet light absorbing coating and a method of making such a laminated glazing.

A laminated glazing with at least one step-shaped functional portion comprising two stack of components, the main stack of components in which the alteration of its properties is not desirable, and a second stack of components comprising a functional layer.

The present invention relates to a specific multilayer composite which is suitable as a constituent of liquid-crystal devices and which contains two specific polycarbonate layers inter alia. The invention further relates to a method of producing the multilayer composite. The invention further relates to a liquid-crystal device comprising a multilayer composite according to the present invention, to a method of production thereof, and to the use thereof as structural glazing, in automotive glass, as floodlight cover, in optical filters, in shutters, in flat visual display screens, in glazed advertising devices, in dividing walls of trains, and in point-of-interest devices.

A laminated glazing includes two transparent substrates which are separated by a lamination interlayer, and intended for fitting out buildings or vehicles. One of the transparent substrates is coated with a functional coating capable of acting on solar radiation and/or infrared radiation, and a low emissivity (so-called “low E”) coating is provided on one of the faces of the second substrate.

Various embodiments of the disclosure are directed towards fenestration assemblies having a first pane; a second pane, the second pane spaced from the first pane; and a third pane configured in spaced relation between the first pane and the second pane, where the third pane is a laminate. In one aspect, the total thickness of the third pane laminate is not greater than 3 mm. In one aspect, the laminate comprises a first glass layer not greater than 1 mm thick and a second glass layer not greater than 1 mm thick, and an interlayer between first and second layers.

A facade element includes a coloring transparent or semi-transparent first pane and a mechanically supporting transparent second pane firmly connected to one another by an intermediate layer. The first pane has a front surface arranged on the light incidence side and an opposite back surface, at least one surface of the front and back surfaces has at least one structured region, and at least one optical interference layer is arranged on the at least one surface for reflecting light within a predetermined wavelength range. The structured region has the following features: perpendicular to the plane of the first pane, a height profile comprising peaks and valleys, wherein an average height difference between the peaks and valleys is at least 2 μm, at least 50% of the structured region is composed of segments which are inclined with respect to the plane of the first pane (2).

A laminated glass comprises first and second glass sheets and a ply of interlayer material disposed therebetween, a conductive strip disposed on the ply of interlayer material, a connector arranged at an edge of the second glass sheet, a ceramic ink layer on a surface of the second glass sheet not facing the ply of interlayer material and partly obscuring the conductive strip, a gap in the ceramic ink layer configured so that the conductive strip is in contact with the connector in the gap. Also, there is a method for manufacturing the laminated glass and use of the laminated glazing.

A system and method includes a display device comprising a spatial light modulator arranged to output spatially modulated light to form an image. The system further includes a waveguide pupil expander configured to receive spatially modulated light from the display device at an input port thereof and to expand the viewing window of the system. The system further comprises a controller. In examples, the controller is configured to control the spatially modulated light output by the display device, such as to control (e.g., turn off) a light source of the display device, in response to a signal indicating detection of the breakage of glass. The signal indicating detection of the breakage of glass may be generated in response to the detection of stray laser light of the holographic system by an eye-tracking system.

The present invention relates to a luminous vehicle sunroof that includes a first glazing with first and second main faces, a light-emitting element such as an OLED or QLED and a collimating optical system with one or more optical films.

A laminated vacuum insulating assembly extending along a plane, P, defined by a longitudinal axis, X, and a vertical axis, Z, including: a first glass pane with thickness Z1, an inner pane face and an outer pane face and a second glass pane with thickness, Z2, an inner pane face and an outer pane face; wherein the thicknesses are measured in the direction normal to the plane, with a set of discrete spacers positioned between the first and second glass panes, a hermetically bonding seal sealing the distance between the first and second glass panes over a perimeter thereof; and an internal volume, V, defined by the first and second glass panes and the set of discrete spacers and closed by the hermetically bonding seal and where there is an absolute vacuum of pressure of less than 0.1 mbar; and where the inner pane faces face the internal volume, V.