An electrically heating converter includes: a pillar shaped honeycomb structure made of conductive ceramics, including: an outer peripheral wall; and a partition wall disposed on an inner side of the outer peripheral wall, the partition wall defining a plurality of cells, each of the cells penetrating from one end face to other end face to form a flow path; metal electrodes; a pressing member configured to press each of the metal electrodes against the pillar shaped honeycomb structure, so that the pillar shaped honeycomb structure is electrically connected to each of the metal electrodes; and an antioxidant material of (i) or (ii) below: (i) an antioxidant material provided between the pillar shaped honeycomb structure and each of the metal electrodes, or (ii) an antioxidant material provided from a surface of the pillar shaped honeycomb structure over an outer surface of each of the metal electrodes.

A honeycomb structure made of ceramics, wherein the honeycomb structure includes: a borosilicate; and silicon particles doped with at least one dopant, the dopant is a Group 13 element or a Group 15 element, the silicon particles have a dopant amount (A) of 1×10.sup.16 to 5×10.sup.20/cm.sup.3, and the honeycomb structure has a silicon particle content (B) of 30 to 80% by mass.

An efficient reinforced heating assembly, including a reinforcing frame, a liquid conducting member and at least two heating members. The reinforcing frame is provided with a vent opening for air to pass therethrough. The at least two heating members are disposed on the reinforcing frame, disposed in the vent opening or covered on the vent opening, to be in contact with the air. The liquid conducting member is disposed on a side of the heating member and in contact with the heating member, so that the liquid conducting member is able to conduct an external liquid to the heating member for heating and atomizing to generate an aerosol, which is output via the vent opening. An atomizing device is further provided, including a shell and the efficient reinforced heating assembly disposed in the shell. The reinforcing frame supports the heating member to improve the strength of the heating member.

A novel solid-state heating element is disclosed. The heating element comprises a plurality of heating layers comprised of a mixture of carbon and a polymer or plastic. The heating layers are disposed on or infused into a substrate. Each heating layer can be disposed on, or infused into, its own substrate, or the heating layers can be disposed on or infused into opposites sides of the same substrate. A radiating element can be disposed in proximity to one or both of the heating layers. The radiating element absorbs the radiation put out by the heating layer(s) and reradiates heat. A heat transfer fluid such as air or a liquid can be directed across the radiating element and/or other areas of the heating element to transfer heat from the heating element to another location.

The present disclosure provides a heating core for hot air gun use and a hot air gun. The heating core comprises: a mount support; and a heating wire arranged on the mount support; wherein the heating wire includes a close wound segment on a surface of which an insulating layer is provided, an interval between adjacent heating wires in the close wound segment is D, 0≤D≤2 mm. The hot gun comprises a housing in which a hot air device producing hot air is provided, the hot air device comprising a heating core; a hot air tube provided at a front end of the housing, inside the hot air tube being disposed the heating core, wherein: the heating core is the heating core for hot air gun use according to any technical solution above. By providing a close wound segment on the heating wire and arranging an insulating layer on the surface of the heating wire, the heating capacity of the heating wire in the local space is increased, the heating density of the local space is improved, and thus the air-out temperature, working effect, and working efficiency of the hot air gun may be dramatically improved.

The present invention relates to an aerosol generator that vaporizes a liquid type inhalation material, and more particularly, to a circuit capable of sensing and controlling a heater voltage, without being affected by power of a battery, in an aerosol generator using a liquid cartridge. According to the present invention, there is provided a circuit for sensing and controlling a heater voltage in an aerosol generator, the circuit including: a battery that supplies power; a microcontroller; a first FET connected to the battery and turned on/off according to a sensing control signal output from the microcontroller; a sensing resistor connected to the first FET; a second FET connected to the battery and turned on/off according to a heater control signal output from the microcontroller; and a heater resistor connected to the second FET and also connected to one end of the sensing resistor, wherein the upstream end of the sensing resistor is connected to the microcontroller, and the downstream end of the sensing resistor has one side connected to the microcontroller and the other side connected to the second FET.

A reservoir refill system for an electronic vaping device includes a refill container and a reservoir. The refill container contains a pre-vapor formulation. The refill container includes a body, an opening in the body, and a first interlocking ring including at least one groove or at least one protrusion therein. The reservoir is configured to contain a pre-vapor formulation and includes a reservoir body, an opening in the reservoir body, and a second interlocking ring including at least one groove or at least one protrusion therein at an opening of the reservoir. The first interlocking ring is configured to mate with the second interlocking ring so as to release the pre-vapor formulation from the refill container to the reservoir.

An exhaust-gas heater for an exhaust system for an internal combustion engine includes a heating conductor with a first supply-voltage terminal, a second supply-voltage terminal and a heating region extending between the first supply-voltage terminal and the second supply-voltage terminal. A voltage-measuring section is integrated into the heating region.

A heating device, and a method of manufacturing the device, comprises an electrically conductive heating foam, a current conducting foam and two electrodes. The heating foam is divided by interruptions into sections, providing a predefined current path extending from a current lead-in point to a current lead-out point. The electrodes are electrically connected to the current lead-in and lead-out points, respectively, wherein the heating foam is provided on an outside at least in sections with the current conducting foam forming current conducting sections that electrically connect sections of the heating foam to one another. The current lead-in or lead-out point is provided as a connection section of the current conducting foam and extends in a circumferential direction along at least one current conducting section, but is electrically insulated therefrom. The two electrodes are spaced apart from one another in the circumferential direction by less than 180 degrees.

A device for treating exhaust gases which is designed for electrically contacting a plurality of conductor tracks, which are arranged within an interior space that is surrounded by an outer wall of the device, through the outer wall. One or more electrodes which may be electrically contacted through the outer wall are arranged in the interior space, each of which electrodes electrically contacts two or more of the conductor tracks in the interior space.