A seat heater includes a substrate. A formed heating wire is disposed on the substrate. A sewing thread attaches the formed heating wire to the substrate. A method of fabricating the seat heater includes forming a straight heating wire into a formed heating wire having miniature wave shape, feeding the formed heating wire onto a substrate, and attaching the formed heating wire onto the substrate by sewing a thread.

There is disclosed a heater for an automotive vehicle or other article of manufacture. The heater typically includes a first conductive medium and a second conductive medium disposed upon a carrier. In a preferred embodiment, the first conductive medium includes a first section and a second section that are electrically connected by a second conductive medium. The second conductive medium preferably exhibits a positive thermal coefficient.

A radiant heating panel, for typical use as cover for interior walls and ceilings, is provided, that is manufactured in a continuous process involving at least one sheet material, a settable material and a heating element. A method of installing such a heating panel is also provided, along with an apparatus and method required to terminate the heating panel.

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.

An occupant support surface heater includes a foundation, a cover, an optional comfort layer, an activation layer, and at least one bus bar secured between the foundation and the cover. The foundation may include a foam pad and the comfort layer includes a conductive material mat that is contiguous with the foundation. The activation layer includes thermally conductive material in the form of an inorganic or organic nanotube structure to provide efficient thermal diffusion and heat delivery for the occupant support. The occupant support surface heater may be used to heat an occupant in the occupant support or to provide heat at a predetermined temperature for a predetermined period of time in order to destroy live viruses or live bacteria at a surface of the unoccupied occupant support.

A silicon heating mat, the mat being formable and deformable and including a matrix made of elastic material, in which at least one cavity is arranged that fully passes through the matrix, the at least one cavity being intended to accommodate a resistive filament connected to a heating cycles management unit. Furthermore, the at least one cavity has an undulating layout, with each resistive filament being able to move inside said at least one cavity, and each resistive filament having a zigzag or spiral shape.

An integral resistance heater is disclosed. The heater includes a beryllium oxide (BeO) ceramic body having a first surface and a second surface. A heating element is formed from a metal foil or metallizing paint and is printed onto the top or second surface of the beryllium oxide ceramic body.

An electrical heating device with a tubular metal jacket and with at least one electrical heating element, which is arranged electrically isolated from the tubular metal jacket in an interior of the tubular metal jacket. The electrical heating element runs parallel to a tube center axis of the tubular metal jacket and has a wave-like shape such that wave peaks and wave valleys are produced.

A vape pen includes a first housing and a mouthpiece detachably and electrically coupled to the first housing. The mouth piece is configured to accommodate a liquid and a heating element for atomizing the liquid. The heating element includes a first tube includes an inlet for receiving the liquid, the inlet having a main-slit portion, a bottom-slit portion and a top-slit portion spaced apart from the bottom-slit portion, the main-slit portion interconnecting the top-slit portion to the bottom-slit portion. The heating element further includes a pair of electrical leads for conducting electrical power from the power source and a wire mesh disposed between the pair of electrical leads, the wire mesh configured to generate heat when energized so as to atomize the liquid.

A heater includes a plurality of heat-generating cells partitioned by a boundary line arranged on a base body, and includes one resistive heating wire formed in each heat-generating cell and having a zig-zag shape as a whole, the resistive heating wire formed by connecting a parallel wiring and a turn-back wiring formed so as to turn back the parallel wiring in a vicinity of the boundary line between adjacent heat-generating cells. In the adjacent heat-generating cells, the resistive heating wire of a heat-generating cell has an extension portion extending the parallel wiring past the boundary line, and the resistive heating wire of the other heat-generating cell is shortened or deformed so that a wiring of a portion facing the extension portion maintains an electrical insulation with the extension portion. The resistive heating wires of the adjacent heat-generating cells include extension portions alternately in a boundary line direction.