A product includes a three-dimensional resistive heating element formed by additive manufacturing and a catalytic component on at least an external surface of the resistive heating element. The resistive heating element has a pre-defined geometric arrangement of features, and the resistive heating element includes a conductive ceramic material.

A method of manufacturing a layered heater includes: applying a dielectric material on a substrate to form a dielectric layer; thermal-spraying a resistive material on the dielectric layer to form a resistive layer on the dielectric layer; forming a plurality of conductive overlays at predetermined locations on the substrate; and forming a plurality of cuts into the resistive layer by laser cutting to form a resistive circuit pattern that overlaps the conductive overlays.

A device (100, 200, 1100, 2100) converts electricity into heat. A first flat winding support (110, 130, 210a, 210b, 230a, 230b, 310a, 310b, 330a, 330b, 510, 610, 630, 710, 1110, 1130, 2110, 2130) including electrically insulating material, has a first electric heating element (140, 150, 240a, 240b, 250a, 250b, 340a, 340b, 350a, 350b, 540, 640, 650, 740, 750) wound thereon. The first flat winding support with wound first electric heating element is inserted into a housing (190, 290, 1190, 2190) electrically insulated against the housing. A second flat winding support, including electrically insulating material, has a second electric heating element (140, 150, 240a, 240b, 250a, 250b, 340a, 340b, 350a, 350b, 540, 640, 650, 740, 750), which is galvanically separated from the first electric heating element, wound thereon. The second flat winding support with wound second electric heating element is inserted into the housing electrically insulated against the housing.

Articles for emitting infrared energy comprising a nanostructured member including a plurality of nanotubes, the member being configured to emit infrared energy when an electrical current is applied; a reflecting member configured to direct at least a portion of the emitted infrared energy in a desired direction for heating a remotely-situated target, and optionally a spacer situated between the nanostructured member and the reflecting member to maintain a predetermined spacing there between, the predetermined spacing selected to minimize destructive interference between the infrared energy emitted by the nanostructured member and the infrared energy reflected by the reflecting member. In alternative embodiments, a carbonaceous member may be substituted for the nanostructured member.

A heating assembly according to one example embodiment includes a thermally conductive heat transfer plate and a plurality of modular heaters mounted to the heat transfer plate. Each modular heater includes a ceramic substrate having at least one electrically resistive trace thick film printed on the ceramic substrate and at least one electrically conductive trace thick film printed on the ceramic substrate. Each modular heater is configured to generate heat when an electric current is supplied to the at least one electrically resistive trace, and the heat transfer plate is positioned to transfer heat from the plurality of modular heaters for heating a desired heating area.

A cooking device according to one example embodiment includes a plurality of modular heaters. Each modular heater includes a ceramic substrate and an electrically resistive trace positioned on the ceramic substrate. Each modular heater is configured to generate heat when an electric current is supplied to the electrically resistive trace. The cooking device includes a thermally conductive heating plate. The plurality of modular heaters are positioned against a bottom surface of the heating plate. The heating plate includes a top surface positioned to transfer heat provided by the plurality of modular heaters to a cooking vessel for cooking an item held by the cooking vessel.

A coated article includes: a substrate; a first dielectric layer over at least a portion of the substrate; a first metallic layer over at least a portion of the first dielectric layer; a first primer layer over at least a portion of the first metallic layer; and a second dielectric layer over at least a portion of the first primer layer; where the first primer layer is selected from the group consisting of zinc, aluminum-doped silver, aluminum zinc, vanadium zinc, tungsten tantalum, titanium niobium, zirconium niobium, tungsten niobium, aluminum niobium, aluminum titanium, tungsten titanium, tantalum titanium, zinc titanium, zinc tin, indium zinc, silver zinc, gallium zinc, indium tin, mixtures thereof, combinations thereof, and alloys thereof.

A co-continuous mouldable polymeric composite with PTC effect has a matrix that comprises at least two immiscible polymers (HDPE, POM), and an electrically conductive filler (CB) in the matrix. At least one of said immiscible polymers is high-density polyethylene (HDPE), and at least one other of said immiscible polymers is polyoxymethylene (POM).

The present invention relates to a heating mat, and can provide a heating mat comprising: a surface layer formed from one of PVC, PU and TPU; a carbon heating element formed under the surface layer, emitting far infrared rays and generating heat; a short-circuit prevention layer provided under the carbon heating element; a copper plate provided under the short-circuit prevention layer and uniformly dispersing heat; a first cushion layer provided under the copper plate, and providing a cushiony feeling; and a bottom layer provided under the first cushion layer and coming into contact with the ground.

An ultrafine bubble generating apparatus generates thermal-ultrafine bubbles by bringing a liquid into film boiling while using a heater provided to a substrate. The ultrafine bubble generating apparatus includes a control unit which inputs energy to the heater such that a value of a ratio of energy to be inputted to the heater relative to energy with which the heater generates film boiling falls below 1.17 under a condition that the energy to be inputted to the heater is larger than the energy with which the heater generates film boiling.