The invention concerns a glazing comprising a first glass sheet having a surface; a printed layer on a part of the surface of the first glass sheet; a conductive coating on a part of the printed layer forming a coated print portion and on a part of the surface of the first glass sheet forming a coated glass portion; first and second busbars in electrical contact with the conductive coating and comprising a first or second busbar portion arranged on a different axis therefrom; a first printed layer portion adjacent the first or second busbar portion forming an adjustable coated print portion between the first and second busbars.

A method for obtaining a glazing includes a glass sheet covered, on one of its faces with electroconductive patterns having in at least one area, a so-called extra thickness area, a greater thickness than in the other areas, the method including depositing by screenprinting a first electroconductive layer forming patterns on one side of the glass sheet, then depositing by a digital printing technique, in the or each extra thickness area, a second electroconductive layer on the first layer while the latter is still wet, then a heat treatment step to cure the first and the second layer.

A glazing includes at least one glass sheet provided on one of the faces with an electrical network having resistance strips and collector strips, in which at least one portion of one face includes at least one strip obtained from an electrically conductive composition including a silver paste, the strip being in contact with another strip obtained from an electrically conductive composition including a copper paste, the other strip obtained from an electrically conductive composition including a copper paste being completely covered with a protective enamel layer.

The invention provides a glazing comprising first glass sheet comprising a printed layer on a portion of a surface of the glass sheet and a conductive coating on the surface of the first glass sheet. The conductive coating extends over at least a portion of the printed layer to form a coated print portion and extends over a portion of the surface of the glass sheet to form a coated glass portion. The coated print portion has a Developed Interfacial Area Ratio Sdr less than 27.45%. A method for producing the glazing and use of the glazing in a vehicle is also disclosed.

A coated glazing useful for vehicles includes a first glass substrate, and a heatable coating formed on the first glass substrate, the heatable coating including at least one heatable layer, at least one dielectric layer, and at least one integrated portion of a heatable layer and a dielectric layer, wherein the integrated portion is formed in a differential heating area of the heatable coating, for variably heating the first glass substrate for deicing wiper park areas or any other heating desirable areas.

A glazing includes at least one glass sheet provided on one of the faces with an electrical network having resistance strips and collector strips, in which at least one portion of one face includes at least one strip obtained from an electrically conductive composition including a silver paste, the strip being in contact with another strip obtained from an electrically conductive composition including a copper paste, the other strip obtained from an electrically conductive composition including a copper paste being completely covered with a protective enamel layer.

An anti-fog glass includes a glass body configured as a single layer or a multilayer stack; an active anti-fog layer disposed on the glass body and heating up when being provided with power; and a passive anti-fog layer disposed on the glass body and inhibiting fog from forming on the passive anti-fog layer. The passive anti-fog layer is a super hydrophobic coating and/or hydrophilic coating. Both the active anti-fog layer and the passive anti-fog layer are simultaneously disposed on the glass body to inhibit fog from forming. In this way, in a region of the glass body not covered by the active anti-fog layer, the anti-fog function is achieved by the passive anti-fog layer to a certain degree; in addition, in a region where the passive anti-fog layer itself cannot provide a desired anti-fog level, the active anti-fog layer together with the passive anti-fog layer provide a better anti-fog effect.

Methods and devices for producing a composite pane having a functional coating are presented. The functional coating is applied to part of a surface of a base pane, and a first pane is cut out from the base pane while introducing a frame-shaped peripheral coating-free region into the functional coating having an inner region that is not adjacent a side edge of the first pane. The surface of the first pane with the functional coating is then bonded via a thermoplastic intermediate layer to a surface of a second pane.

A substrate is coated on one face with a thin-films stack having reflection properties in the infrared and/or in solar radiation including a single metallic functional layer, based on silver or on a metal alloy containing silver, and two antireflection coatings. The coatings each include at least one dielectric layer. The functional layer is positioned between the two antireflection coatings. At least one of the antireflection coatings includes an intermediate layer including zinc tin oxide Sn.sub.xZn.sub.yO.sub.z with a ratio of 0.1≦x/y≦2.4, with 0.75(2x+y)≦z≦0.95(2x+y) and having a physical thickness of between 2 nm and 25 nm, or even between 2 nm and 12 nm.

A material includes a transparent substrate coated with a stack of thin layers successively including an alternation of three silver-based functional metal layers and of four dielectric coatings so that each functional metal layer is positioned between two dielectric coatings. Absorbent material is present between the first functional layer and the second functional layer, in a total thickness Abs2 such that 1.0≤Abs2≤5.0 nm and/or absorbent material is present between the second functional layer and the third functional layer, in a total thickness Abs3 such that 1.0≤Abs3≤5.0 nm. Additionally, absorbent material is present between the face of the substrate and the first functional layer in a total thickness such that 0.0<Abs1≤0.5 nm and absorbent material is present above the third functional layer, in a total thickness Abs4 such that 0.0<Abs4≤0.5 nm.