A device for emanating materials in the environment, preferably by heat evaporation, including: a supply for materials; an emitter of materials, for emitting the materials from the supply to surrounding environment, by application of power from a power supply according to an operation mode; an operation mode adjusting mechanism for adjusting the operation mode of the emitter, by controlling the power delivered to the emitter according to a determined transfer function. The transfer function is modular, so that it can be changed or completely replaced while keeping at least partially the adjusting mechanism in the device.

A device for emanating materials in the environment, preferably by heat evaporation, including: a supply for materials; an emitter of materials, for emitting the materials from the supply to surrounding environment, by application of power from a power supply according to an operation mode; an operation mode adjusting mechanism for adjusting the operation mode of the emitter, by controlling the power delivered to the emitter according to a determined transfer function. The transfer function is modular, so that it can be changed or completely replaced while keeping at least partially the adjusting mechanism in the device.

An aerosol generating device includes a housing having an open end and forms a cavity in communication with the open end for receiving an aerosol generating article. The device further includes a rotatable capture element disposed in the cavity. The rotatable capture element is operable to retain the aerosol generating article within the cavity. The rotatable capture element is longitudinally movable within the cavity. The device further includes a heating element in communication with the cavity. The heating element is operable to heat the aerosol generating article retained by the capture element within the cavity. Combined rotation and longitudinal movement of the capture element causes the aerosol generating element to spiral relative to the heating element.

An aerosol generating device includes a housing having an open end and forms a cavity in communication with the open end for receiving an aerosol generating article. The device further includes a rotatable capture element disposed in the cavity. The rotatable capture element is operable to retain the aerosol generating article within the cavity. The rotatable capture element is longitudinally movable within the cavity. The device further includes a heating element in communication with the cavity. The heating element is operable to heat the aerosol generating article retained by the capture element within the cavity. Combined rotation and longitudinal movement of the capture element causes the aerosol generating element to spiral relative to the heating element.

A heat exchanger includes a metal fiber structure (20) formed from metal fibers, and a housing body (for example, a pipe (10)) in which the metal fiber structure (20) is housed, and a gap is formed at least partially between the metal fiber structure (20) housed in the housing body and an inner surface of the housing body.

A heat exchanger includes a metal fiber structure (20) formed from metal fibers, and a housing body (for example, a pipe (10)) in which the metal fiber structure (20) is housed, and a gap is formed at least partially between the metal fiber structure (20) housed in the housing body and an inner surface of the housing body.

Disclosed are electromagnetic cells assembled together. The plurality of Electromagnetic Cells are arranged in an electromagnetic plate, the electromagnetic plate can float or hover. The Electromagnetic Plate comprises an enclosure of a first set of alternating layers of electric and dielectric materials. The plurality of electromagnetic cells, each arranged in an individual socket embedded in the holding element inside the Electromagnetic plate, and each electromagnetic cell is comprised of a second set of alternating layers of electric and dielectric materials, and a holding cup cover that screws in to provide structural integrity and an electromagnetic core including a metal tube and electromagnetic coil. At the opening of the Electromagnetic Cell, a tube mechanism can be added which would allow certain liquids to be inserted inside of the cell. The cells heats up as a result of the electric current flowing through the coil inside of the cell, thus resulting in an increased temperature of such liquid.

An electrical heater and a method of heating a catalyst. The heater includes a honeycomb body that includes a honey-comb structure. The honeycomb structure includes a central axis extending longitudinally and a plurality of interconnected walls. The interconnected walls include a plurality of radial walls extending along a radius of the honeycomb body between the central axis and an outermost periphery of the honeycomb body and a plurality of angular walls arranged concentrically with respect to the central axis and spanning between the radial walls. The honeycomb structure includes a plurality of cells defined by the interconnected walls. The heater comprises a first electrode disposed at the central axis and a second electrode disposed radially outwardly of the central axis and in electrical communication with the first electrode via one or more of the intersecting walls that are located between the first electrode and second electrode.

An electrical heater and a method of heating a catalyst. The heater includes a honeycomb body that includes a honey-comb structure. The honeycomb structure includes a central axis extending longitudinally and a plurality of interconnected walls. The interconnected walls include a plurality of radial walls extending along a radius of the honeycomb body between the central axis and an outermost periphery of the honeycomb body and a plurality of angular walls arranged concentrically with respect to the central axis and spanning between the radial walls. The honeycomb structure includes a plurality of cells defined by the interconnected walls. The heater comprises a first electrode disposed at the central axis and a second electrode disposed radially outwardly of the central axis and in electrical communication with the first electrode via one or more of the intersecting walls that are located between the first electrode and second electrode.

Various embodiments disclose a glow plug for a solid oxide fuel cell system. The glow plug includes a housing having a first end portion and a second end portion. The glow plug includes a heating element longitudinally disposed in the housing, extending from the second end portion of the housing towards the first end portion and extending outwardly from the housing for igniting fuel. Further, the glow plug includes a pair of coiled wires electrically connected to the heating element. Further, the glow plug includes a potting compound disposed within the second end portion of the housing for securing electrical coupling of the pair of coiled wires with the heating element. Furthermore, the glow plug includes a sealing element configured to form an air-tight connection between the housing and the heating element. The sealing element is positioned on top of the potting compound.