A composite film may include a first transparent substrate, a dielectric layer and at least two infra-red reflection stacks. The dielectric layer may be located between the at least two infra-red reflection stacks and each of the infra-red reflection stacks may include two titanium blocker layers and a functional layer. The functional layer in each infra-red reflection stack may include silver and may be located between the two blocker layers.

A composite pane includes an outer pane having an exterior-side surface and an interior-side surface, an inner pane having an exterior-side surface and an interior-side surface, and a thermoplastic intermediate layer joining the interior-side surface of the outer pane to the exterior-side surface of the inner pane. The composite pane has a sun shading coating between the outer and inner panes. the sun shading coating includes, starting from the outer pane toward the inner pane, a layer sequence first dielectric module M1, first silver layer Ag1, second dielectric module M2, second silver layer Ag2, third dielectric module M3, third silver layer Ag3, fourth dielectric module M4, wherein the silver layers have, relative to one another, a geometrical layer thickness of 0.4<Ag1/Ag3<1.7, and Ag3 or Ag2 is the thickest silver layer, and wherein the dielectric modules have, relative to one another, an optical layer thickness of M2/M1≥1.9, M2/M3≥0.8, and M2/M4≥1.6.

A projection assembly for a head-up display (HUD), includes a composite pane with an electrically conductive coating, and a projector. The radiation of the projector is predominantly p-polarized. The electrically conductive coating has a first surface region within a HUD region and a second surface region outside the HUD region. The electrically conductive coating has at least one sub-region within the first surface region. The electrically conductive coating in the first surface section within the HUD region can be obtained from the electrically conductive coating in the second surface section using a subtractive method.

A laminated glazing is formed of several rigid transparent substrates adhesively bonded in pairs by an interlayer adhesive layer, at least one of these transparent substrates being coated with an electrically conductive layer, a zone of this transparent substrate exhibiting four opposite edges in pairs, a first and a second busbar being positioned along two opposite edges, the electrically conductive layer exhibiting flow lines for guiding the electric current between the busbars, the set of flow lines being of variable width.

A laminated glazing with an optically transparent area including at least one inner and one outer glass sheet, each having an internal and an external face, and being high level of near infrared radiation transmission glass sheets, at least one thermoplastic interlayer to laminate the at least the inner and the outer glass sheets, including at least a first zone and a second zone, the second zone being delimited by the optically transparent area, and at least one optical sensor device provided on the inner face of the inner pane integrated in the optically transparent area. The thermoplastic interlayer further includes a second zone delimited by the optically transparent area where the laminated glazing has a value of infrared transmission TIR1 higher than the value of infrared transmission TIR2 of the first zone for the working wavelengths of the optical device.

A laminated glazing with light transmission LT in the visible spectrum of at least 70%, includes two clear glass sheets bonded to one another by an adhesive interlayer, wherein one of the two faces of the glass sheets on the inside of the laminated structure is coated with a stack of thin layers adapted to reflect at least 17% of p-polarized light projected under an incident angle of 65°, and wherein the adhesive interlayer is tinted so as to absorb 5 to 25% of visible light.

A material includes one or more transparent substrates including two main faces, wherein one of the faces of one of the substrates is coated with a functional coating which can have an effect on solar radiation and/or infrared radiation, and a face not coated with the functional coating of one of the substrates includes an absorbent color-adjustment coating including an absorbent layer which absorbs solar radiation in the visible part of the spectrum.

A glass article with solar control properties, includes a glass substrate provided with a stack of layers that includes successively from the surface of the substrate a first module M.sub.1 made of layer(s) of dielectric material, a first layer TiN.sub.1 including titanium nitride, a second module M.sub.2 made of layer(s) of dielectric material, a second layer TiN.sub.2 including titanium nitride, a third module M.sub.3 made of layer(s) of dielectric material. The total thickness the TiN.sub.1 and TiN.sub.2 layers including titanium nitride is between 25 and 60 nm. The third module M.sub.3 includes a layer including an oxide or oxynitride of silicon having a thickness greater than 10 nm. An interlayer IL of titanium, aluminum, silicon, or an alloy thereof, or of a nickel chromium alloy, is deposited between the second layer TiN.sub.2 and the third module M.sub.3, the thickness of the interlayer IL being between 0.5 nm and 7 nm.

The invention concerns an automotive glazing comprising (i) at least one glass sheet having an absorption coefficient lower than 5 m.sup.−1 in the wavelength range from 1051 nm to 1650 nm and having an external face and an internal face, and (ii) an infrared filter. According to the present invention, an infrared-based remote sensing device in the wavelength range from 1051 nm to 1650 nm, is placed on the internal face of the glass sheet in a zone free of the infrared filter layer.

A method for producing an electrically connected coated substrate for vehicle glazing includes the steps of providing on a surface of a substrate a coating having a conducting layer, forming an opening in the coating, and applying an electrical connector having a conductive carrier on one side of the electrical connector to the coating directly over the opening, wherein the conductive carrier fills the opening to electrically connect the conducting layer.