A laminated glazing has a plurality of rigid transparent substrates that are bonded to one another pairwise via an intercalary adhesive layer, at least one of these transparent substrates being coated with an electrically conductive layer that is substantially uniform in nature and thickness, a zone of which has four edges opposing one another in pairs, first and second busbars being arranged along two opposite edges, ablation lines of the electrically conductive layer closing in on themselves while forming non-conductive strips, each occupying a major portion of the distance between the busbars, the shape of the non-conductive strips being capable of providing a temperature of heating by the electrically conductive layer that is virtually constant over the entire area of the zone.

A windshield with an electrically controllable sun visor is described. The windshield includes an outer pane and an inner pane that are bonded to one another via an intermediate layer. According to one aspect, a functional element with electrically controllable optical properties is incorporated into the intermediate layer and above a central field of vision. The functional element is connected to the outer pane via a region of a first thermoplastic layer, and is connected to the inner pane via a region of a second thermoplastic layer. According to another aspect, the region of the first thermoplastic layer and/or the region of the second thermoplastic layer is tinted or colored.

A transparent pane, having at least one heatable, electrically conductive coating connected to at least two collection electrodes, provided for electrically connecting to a supply voltage to generate a heating current that flows across a heating field formed between the at least two collection electrodes is described. The heating field includes at least one communication window free from the heatable, electrically conductive coating. The transparent pane further includes at least one heatable, electrically conductive coating. The additional electrode is connected to one of the two collection electrodes via a respective current supply line.

An electrically heatable pane with a switch region is presented. The pane has a transparent substrate, with at least one transparent electrically conductive layer that is, at least partially, arranged on a surface of the pane. At least one separating line electrically divides the layer into a heating region and a switch region. At least two busbars are provided for connection to a voltage source. The busbars being connected to the heating region, form a current path between the busbars. A heating current can therefore flow through the current path. Furthermore, the switch region has at least one contact region, a feed line region, and a connection region, where the connection region can be connected to sensor electronics.

An electrical current transmission system for transmitting an electrical current to an object via a substantially transparent structure, wherein the substantially transparent structure includes at least one transparent layer and at least two transparent electrically conductive elements. The substantially transparent structure further comprises means for connecting the at least two electrically conductive elements to an external power supply, and means for transfer of electrical current from the transparent structure to the object. The at least two electrically conductive elements are separated by a part of the structure which is electrically insulating.

A metal pattern film including a substrate; a first adhesion promoting layer provided on a first surface of the substrate; a second adhesion promoting layer provided on a second surface of the substrate, which is opposite to the first surface of the substrate; a metal pattern provided on a surface of the first adhesion promoting layer opposite to a surface of the first adhesion promoting layer adjoining the substrate; a first adhesive layer provided on a surface of the metal pattern opposite to the first adhesion promoting layer so as to cover the metal pattern; and a second adhesive layer provided on a surface of the second adhesion promoting layer opposite to a surface of the second adhesion promoting layer adjoining the substrate. Each of the first adhesion promoting layer and the second adhesion promoting layer includes an inorganic oxide. A method for preparing a metal pattern film.

A motor vehicle glazing, including: (i) two sheets of glass, external and internal, each respectively including an external face and an internal face, joined by one or more thermoplastic separator sheets, (ii) at least one electrically powered functional assembly being inserted between the glazing sheets, (iii) a capacitive sensor controlling the power supply of the functional assembly, the sensor also being arranged on a transparent support coated with an equally transparent conductive layer(consisting of a first area which corresponds to the capacitive electrode and a second area corresponding to the shielding electrode surrounding the first area, the first and second areas being separated by a distance A), and (iv) a capacitive switch placed at a distance B from the capacitive electrode, where the distances A and B are equal.

An electro-optic window is provided, together with a method of manufacturing the window. The window (3) is made of a material substantially transparent to at least one of infra-red, visible and UV radiation and treated to have reduced RF/MICROWAVE transmission characteristics by the provision of a grid (1) set into at least one surface (2) thereof. The grid (1) is formed of a material selected to be either reflective or absorptive to RF/MICROWAVE radiation.

An intelligent transmittance control system includes a multilayer film having electrically controllable fields, wherein the optical properties of the fields are influenced by the control, a controller, and a sensor, wherein the multilayer film includes first and second structured electrically conductive layers, wherein an electrically active layer is arranged between the first and second conductive layers, and wherein the structuring of the first electrically conductive layer has an angle of more than 0 relative to the structuring of the second electrically conductive layer. The controllable fields are created by overlapping the structures of the first and second conductive layers. The controller controls the strips of the first and second conductive layers as a function of the sensor such that the optical properties of one or a plurality of fields are selectively influenced.

A pane, having at least one first pane with an outer face and an inner face is described. The pane has at least one electrically conductive transparent coating which is arranged on the outer face and/or the inner face of the first pane, and at least two busbars which are provided for connecting to a voltage source and which are connected to the electrically conductive transparent coating such that a current path for a heating current is formed between the busbars. The electrically conductive transparent coating has at least three regions with decoated structures.