A method of manufacturing a window assembly having a solderless electrical connector includes forming a curved transparent substrate and applying a conductive ink having a thermal degradation temperature onto a surface of the curved transparent substrate. The method further includes applying an adhesive onto the surface of the curved transparent substrate adjacent to the conductive ink and optionally onto the applied conductive ink, and curing the adhesive at a temperature below the thermal degradation temperature of the conductive ink to form the solderless electrical connector with the solderless electrical connector being in electrical contact with the applied conductive ink.

The heating film including: a transparent substrate; a coating layer provided on the transparent substrate and having a refractive index of 1.450 to 1.485; and a metal foil pattern provided on the coating layer, in which a ten-point average roughness (Rz) of a surface of the metal foil pattern is more than 0.9 m.

A pane arrangement directed to a heatable composite pane having a capacitive switching region, including a substrate and a cover pane is disclosed. At least one intermediate layer is arranged between the substrate and the cover pane. A carrier film having an electrically conductive layer is arranged between the substrate and the intermediate layer or between the cover pane and the first intermediate layer. The electrically conductive layer forms a capacitive switching region having a contact region, a supply line region, and a connection region. The supply line region electrically connects the contact region to the connection region that can be electrically connected to a sensor electronics system. A heating wire and at least two busbars are arranged between the substrate and the cover pane, wherein one end of the heating wire is electrically connected to one of the busbars. A capacitive sensor electronics system is electrically connected to the connection region via a first input and to the heating wire or to the busbars via a second input.

A transparent window plate is provided with a plurality of defogging heat wires arranged to have a side parallel with a first direction. The transparent window plate includes: a plurality of repetitive patterns that are arranged between one of the plurality of defogging heat wires and an adjacent one of the plurality of defogging heat wires so as to be not in contact with the plurality of defogging heat wires, and each of the plurality of repetitive patterns having at least one side parallel with the plurality of defogging heat wires. The plurality of repetitive patterns are aligned along the first direction; and the plurality of repetitive patterns are repetitively arranged along a second direction perpendicular to the first direction.

A window glass for a vehicle including a laminated glass with a vehicle exterior side glass plate, a vehicle interior side glass plate and an interlayer interposed between the vehicle exterior side glass plate and the vehicle interior side glass plate. The window glass also having a conductor pattern including a heating wire disposed on a vehicle interior side surface of the vehicle exterior side glass plate to heat a heating area, as well as a feeding electrode disposed on a part of the vehicle interior side surface close to a lower side of the vehicle exterior side glass plate such that the heating wire is fed with power through the feeding electrode. The feeding electrode is disposed so as not to extend into the heating area.

A laminated glass for a vehicle includes a first glass plate, a second glass plate, an interlayer, a first busbar and a second busbar arranged such that a visible area is interposed in a predetermined direction between the first busbar and the second busbar, a plurality of electric heating wires arranged in the visible area to generate heat with a voltage applied by the first busbar and the second busbar, and a third busbar arranged at an opposite side of the visible area from the second busbar, wherein the third busbar and the first busbar are arranged such that an information acquisition area is interposed in the predetermined direction between the third busbar and the first busbar, and at least one of the electric heating wires is arranged in the information acquisition area to generate heat with a voltage applied by the third busbar and the first busbar.

A laminated glazing includes a first and a second glass sheet that are bonded by a first interlayer adhesive layer, a peripheral zone of the laminated glazing being covered by a stepped metal element, the laminated glazing including a heating network of wires and/or a heating electrically conductive layer that is provided with busbars, a plurality of probes and other optional electrical elements that are linked to an electrical power supply via the connector of the laminated glazing, an electrical conductor linking the stepped metal element to a busbar of the heating network of wires and/or of the heating electrically conductive layer; and/or to the cap of the connector of the laminated glazing, which is linked to the ground of the structure for mounting the laminated glazing; and/or to a contact of the connector.

A laminated glass having an interlayer between a glass plate on an exterior side of a vehicle and a glass plate on an interior side of the vehicle, includes a heat generator on a principal surface on a vehicle-exterior side of the glass plate that is on the interior side of the vehicle, wherein at least one of the glass plate on the exterior side of the vehicle and the glass plate on the interior side of the vehicle has a wedge shape in cross section, and wherein a maximum value of a layer thickness of the interlayer is less than or equal to 1 mm.

An automotive luminous signaling glazing for example forming a laminated vehicle front windshield, includes a first exterior glazing, with a first main face and a second main face; a lamination interlayer made of polymeric material and a set of electrically conductive wires anchored on an anchoring face of the lamination interlayer, which is either the fifth main face or the sixth main main of the lamination interlayer; an interior second glazing, with a third main face and a fourth main face, the second main face and the third main face being the internal faces of the laminated glazing; and a set of diodes emitting in the direction of the interior glass. For each of the diodes, the lamination interlayer comprises a blind aperture on the opposite face to the anchoring face.

A transparent pane having an electrically heatable coating and at least one coating-free zone that can be used, for example, as communication window, is presented. The electrically heatable coating is connected to two collecting electrodes, such that a supply voltage applied to the electrodes generates a heating current that flows via a heating field formed between the collecting electrodes, the heating field containing the coating-free zone whose zone-edge is formed, at least in sections, by the heatable coating. Other implementation details include provision of two electrical supply lines electrically connecting the two collecting electrodes to separate subdivisions of an additional electrode. In one case, the electrical supply lines run, at least in sections, in the heating field, in the coating-free zone, in a coating-free edge strip, in a subregion of the coating outside the heating field, and/or in the zone-edge. Methods for producing the transparent pane are also presented.