A composite pane with a capacitive switching zone includes a substrate, a first intermediate layer areally bonded to the substrate, a second intermediate layer areally bonded to the first intermediate layer, and a cover pane areally bonded to the second intermediate layer. A carrier film with an electrically conductive layer is arranged between the first and second intermediate layers. A capacitive switching zone is electrically isolated from the electrically conductive layer by a coating-free separating line, the capacitive switching zone has a contact zone, a supply line zone, and a connection zone; the supply line zone electrically connects the contact zone to the connection zone, and the connection zone is electrically connectable to sensor electronics. The surface capacitance between the contact zone and the outside surface of the substrate is greater than the surface capacitance between the contact zone and the outside surface of the cover pane.

A glazing unit with electrically controllable optical properties having multiple independent switching regions includes a laminated glass pane with an electrically controllable functional element and a control unit to control the optical properties of the functional element. The functional element has an active layer with electrically controllable optical properties between a first planar electrode and a second planar electrode. The first planar electrode is subdivided by at least one insulation line into at least two separate electrode segments, wherein a voltage is applicable independently between each electrode segment of the first planar electrode and the second planar electrode in order to control the optical properties of the section of the active layer located between them. The control unit is adapted to apply an AC voltage between at least two electrode segments of the first planar electrode and the second planar electrode, wherein the AC voltages are phase-shifted.

A panel, having at least: at least one first panel having an outer face and an inner face, at least one transparent, electrically-conductive coating, which is arranged on the outer face and/or on the inner face of the first panel, and at least one region having at least one outer de-coated structure and one inner de-coated structure, the transparent, electrically-conductive coating being located between the outer de-coated structure and the inner de-coated structure and inside the inner de-coated structure.

A method for supplying an electronic component of a laminated glazing unit with electrical power, the laminated glazing unit including at least two superposed glass sheets with, interposed, at least one thermoplastic interlayer, the electronic component being housed between the two glass sheets. The electronic component is connected to an electrical current source by an electrically conductive circuit that is housed between the glass sheets. Duration of activation of the electrical current source is controlled by a microcontroller.

A heatable laminated side pane is described. The heatable laminated side pane comprises at least an outer pane and an inner pane, which are connected to each other via a thermoplastic intermediate layer. An electrically conductive coating is arranged on the surface between the outer pane and the inner pane. The electrically conductive coating is divided into segments by isolation lines, wherein the coating has heating strips extending between a first current collector rail and a second current collector rail. Each collector rail contains at least one segment, wherein the heating strips are electrically isolated from each other. At least one heating strip is formed by at least two segments, which are electrically connected to each other via at least one electrically conductive connector element, and the length of each individual heating strip deviates by a maximum of 15% from the average length of the heating strips.

A polymer derived ceramic glass paint, glass coating, and glass composite. SiOC based glass paints. SiOC liquid coatings for glass substrates. SiOC particles and pigments for use in and on glass substrates. Methods of coating glass with SiOC based glass paints. Composites having a layer of conductive SiOC glass paint.

A composite pane having an electrically controllable functional element that can be switched in segments, includes first and second panes joined to one another via an intermediate layer, and a functional element with a plurality of side edges embedded in the intermediate layer. The functional element includes, arranged flat one over another, a first surface electrode and a second surface electrode, between which an active layer is arranged flat. The first surface electrode is divided into multiple segments by a separating line. A group of first busbars electrically conductively contact the first surface electrode, and each segment of the first surface electrode is electrically conductively contacted by one busbar from the group of the first busbars. A second busbar electrically conductively contacts the second surface electrode.

An improved a glazing unit including a glass panel which is low in reflectance for RF radiation, a coating system which is high in reflectance for RF radiation disposed on the said glass panel and creating onto the glazing unit a dual band bandpass filter. The glazing unit further includes at least one frequencies selective decoated portion of the coating system extending along a plane, P, defined by a longitudinal axis, X, and a vertical axis, Z; having a width, DW, measured along the longitudinal axis, X, and a length, DL, measured along the vertical axis, Z. The at least one frequencies selective decoated portion includes a first decoated element that includes a plurality of unit cells forming a regular grid of n rows by m columns unit cells and a plurality of second decoated elements.

A glazing unit having electrically controllable optical properties and multiple independent switching regions includes a composite pane with an electrically controllable functional element and a control unit to control the optical properties of the functional element. The functional element has an active layer having electrically controllable optical properties between a first flat electrode and a second flat electrode. The first flat electrode is divided by at least one insulation line into at least two separate electrode segments, wherein an electric voltage is applicable between each electrode segment of the first flat electrode and the second flat electrode independently of one another in order to control the optical properties of the section of the active layer situated therebetween. The second flat electrode is not segmented or is segmented to a lesser extent than the first flat electrode. The control unit is adapted to ascertain the temperature of the composite pane.

A system such as a vehicle may have windows. A window may have rigid clear layers such as layers of glass or rigid polymer. A polymer layer may be interposed between the rigid clear layers to form a laminated window structure. A conductive layer such as a silver layer or other metal layer in the window may be configured to block infrared light. The conductive layer may be patterned to form signal paths, a radio-transparent region, and other structures in a window. The conductive layer may be formed as a coating on a rigid clear window layer or may be formed on other window structures. The conductive layer may be patterned by removing conductive material from areas of the conductive layer. An insulating layer that visually matches the conductive layer may be formed in these areas without overlapping the conductive area.