An electrically heatable laminated automotive glazing unit including an exterior glass sheet that is curved and tempered and a thin glass interior sheet that is also tempered, these sheets being joined by means of a thermoplastic interlayer sheet. The glazing unit is configured to receive mechanical moving and/or fastening means and a portion of the exterior sheet is not covered by the thin interior sheet. The glazing unit is fastened in the zone not covered by the thin sheet, and the glazing unit includes at least one electrically heatable zone comprising (i) a substantially transparent, electrically conductive coating layer and (ii) spaced busbars adapted to supply electrical voltage across the substantially transparent, electrically conductive coating layer. The spaced busbars are placed in the portion of the exterior sheet which is not covered by the thin interior sheet.

A heating pad, a portable electric heater and/or an article of manufacture. The heating pad comprising: a first heating fabric comprising graphene; a nanotube-based film having a first surface coupled to the first heating fabric; a second heating fabric coupled to a second opposing surface of the nanotube-based film; and a flexible circuit disposed between the first heating fabric and the nanotube-based film, the flexible circuit configured to facilitate an increase in temperature by at least the first and second heating fabrics.

A traffic light with a housing, a light assembly mounted to the housing, a visor extending from the housing surrounding the light assembly. The traffic light further including a heater element having multiple layers.

A heating element composite comprises a substrate of one or more fibers or threads and an electrically-conductive polymer coating comprising an electrically-conductive polymer material deposited onto the one or more fibers or threads. A thickness of the electrically-conductive polymer coating is at least about 100 nanometers and the electrically-conductive polymer coating covers at least about 75% of an external surface area of the one or more fibers or threads of the substrate. The resulting heating element composite has a sheet resistance of from about 2Ω/□ to about 200Ω/□.

A heater system for an LED light assembly having a lens includes a flexible composite positioned around an outer surface of the lens. The flexible composite includes a polymer base layer, a plurality of conductive buses provided on the base layer, and a resistive layer electrically connecting the plurality of buses to form a circuit. The resistive layer includes conductor particles dispersed in a polymer matrix. The resistive layer has a crystalline first condition prior to applying electricity to one of the buses and an amorphous second condition in response to applying electricity to one of the buses.

A multifunctional assembly having a resistive element a conductive element in electrical communication with the resistive element, the conductive element defining at least one of a plurality of multifunctional zones of the resistive element, wherein the conductive element is configured to direct a flow of electricity across at least one of the plurality of multifunctional zones of the resistive element in a preselected manner.

A laminated glazing comprising an assembly including (i) at least a thermoplastic interlayer, (ii) a first busbar laid over the thermoplastic interlayer, (iii) at least one heating wire laid over the first busbar, (iv) a second busbar at least partly laid over the heating wire and at least partly laid over the first busbar, (v) where a solder layer suitable for melting in an autoclave covers at least part of a surface of the first busbar or the second busbar and is arranged to contact the heating wire, and (vi) where the assembly is laminated with at least a glass sheet.

Proposed is a transparent heating element for an eye protector such as goggles for snowmobiling, skiing, motorcycling, and the like on which a lens is mounted, and is a manufacturing method thereof. On a surface of a transparent base that configures the lens of the eye protector, a lattice film formed of a dried material or a calcined material of a conductive ink or a conductive paste is provided. The lattice film has a line width of 2.5 μm to 20 μm, a lattice pitch of 0.1 mm to 5.0 mm, a surface resistance value of 10 Ω/cm.sup.2 to 50 Ω/cm.sup.2, and a light transmittance of 90% when the transparent base is excluded. An anti-fog coating treatment is performed on the opposite surface of the transparent base. The surface resistance value is partially changed by changing the lattice pitch.

A window glass for a vehicle includes a glass plate for window of the vehicle, a defogger on the glass plate, and an antenna on the glass plate. The defogger includes a pair of bus bars extending in a height direction of the glass plate, a first defogging area formed by a plurality of first heating wires connected between the pair of bus bars and extending in a widthwise direction of the glass plate, and a second defogging area formed by at least a second heating wire connected to the pair of bus bars or to the first defogging area and extending in a protruding manner to one side in the height direction to surround a wiring-prohibited area. The antenna is provided in at least one of areas that are an area on left of the second defogging area and an area on right of the second defogging area.

A method of coating a substrate with a particulate coating composition is disclosed that creates a coated substrate having a controlled, nonuniform surface property profile that varies along at least one primary dimension. The substrate is positioned on a textured template. An effective amount of the particulate coating composition is buffed onto a surface of the substrate with the at least one orbital applicator moving in a plane parallel to surface in a plurality of directions relative to a point on the surface in an orbital manner while at least one process variable is changed during the coating of the substrate. Process variable that can be varied during coating include application time, application pressure, coating temperature, the contour of the textured template, orbital speed, web speed, and the particulate coating composition.