An evaporator unit for an inhaler, in particular for an electronic cigarette product, comprises an electrically operable, in particular planar, heating body which has an inlet side and an outlet side, and a plurality of microchannels which each extend from the inlet side to the outlet side through the heating body, the heating body being designed to evaporate, by applying a heating voltage, liquid transferred through the microchannels. A porous and/or capillary wick structure is arranged on the inlet side of the heating body, which structure rests flat against and in contact with the heating body and covers all of the microchannels on the inlet side.

The invention relates to a device for producing special effect fog, in particular in the field of stage technology, comprising fog generator (1) which is equipped with a heating element, wherein a fog fluid is evaporated by means of the heating element, and at least one ultrasonic vaporizer (5) which is arranged in a housing (2) on the bottom (3) of a main mixing chamber (4), wherein the fog which is generated by the fog generator (1) can be conducted into the main mixing chamber (4), and wherein, furthermore, a baffle wall (7) is provided in the main mixing chamber (4) close to an outlet opening (6). In addition, a pre-mixing chamber (8) is provided, into which an air stream which is generated by a fan (9) and the fog which is generated by the fog generator (1) can be introduced via respective access openings (14, 15). The pre-mixing chamber (8) is connected by means of a transfer opening (10) to the main mixing chamber (4), wherein the transfer opening (10) is arranged in the main mixing chamber (4) so as to lie opposite the baffle wall (7).

A humidification system of a dispensing head of a dosing machine of fluid products, where the dispensing head includes a closing device having a cup, which can be moved between a distal inoperative position and an operative position where the dispensing head is isolated from the environment. The humidification system automatically generates a humid environment inside the cup, in the proximal position of the closing element, by means of a Peltier cell inserted in a forced flow duct of ambient air. The condensed and/or frosted water from the Peltier cell is fed from a collecting tank to the cup of the closing element automatically through a control unit.

An atomizing spray device includes a housing having inlets that receive a first fluid and a slurry of ceramic particles and a second fluid. The inlets are fluidly coupled with outlets by an interior chamber that mixes the first fluid with the slurry to form a primary mixture of the first fluid and first atomized droplets of the slurry. A first outlet on a first side of the housing and a second outlet on the first side of the housing are shaped to change the primary mixture to form a secondary mixture of the first fluid and second atomized droplets of the slurry. The first outlet sprays the secondary mixture onto a first surface as a first layer of coating and the second outlet sprays the secondary mixture onto the first surface as a second layer of coating while the housing moves in a direction along the first surface.

An aerosol generating device includes a reservoir configured to contain a liquid medium and a heating body including a sheet of an electrically-conductive material having a first surface in physical contact with the liquid medium and a second surface opposite the first surface, interfacing with ambient air, and including an array of micro-nozzles disposed over an area of the sheet and extending through the sheet from the first surface to the second surface. An electrical power unit, is configured to inject pulses of electrical current through the area of the sheet, with a pulse energy selected so as to heat the conducting material sufficiently to vaporize the liquid medium. The micro-nozzles have a profile selected so as to cause a vapor of the liquid medium to be accelerated by the micro-nozzles to form respective high-speed jets of hot vapor into the ambient air.

A device for cooking food may include a steam-generating chamber, which may provide steam to a cooking chamber at a regulated steam temperature, that may comprise a liquid-heating element and an atomizer. The liquid-heating element may heat a liquid to a regulated liquid temperature, which may be less than a boiling temperature of the liquid. The regulated steam temperature may be based on the regulated liquid temperature. The cooking chamber may include an air-heating element, which may heat the air within the cooking chamber. The air-heating element may be heated to a regulated heater temperature less than the boiling temperature of the liquid. The cooking chamber may receive the steam, and maintain the air within the cooking chamber at a regulated air temperature based on the regulated heater temperature of the air-heating element and the regulated steam temperature of the steam.

A thermal fogger includes an air-supply system and a chemical injector. The air-supply system includes an air chamber, a pre-heater configured to heat air in the air chamber, and a blower in fluid communication with the air chamber and configured to blow a flow of heated air through an outlet of the air chamber. The chemical injector is coupled to the outlet of the air chamber and is configured to inject a liquid chemical into the flow of heated air to produce an air-chemical mixture.

The invention relates to an inhaler component for forming a vapor-air mixture and/or condensation aerosol by vaporizing a liquid material and optionally condensing the vapor formed, including: a heating element for vaporizing a portion of the liquid material; a wick for automatically supplying the liquid material to the heating element, wherein the wick includes at least two end sections arranged apart from each other; a first capillary gap for automatically supplying the liquid material to the wick, wherein a first end section of the wick projects into the first capillary gap. In order that the heating element can be supplied more quickly and more reliably with the liquid material, a second capillary gap is provided, which receives therein the second end section of the wick.

An aerosol forming component for volatilizing a liquid in an aerosol delivery device is disclosed. The aerosol forming component includes a first aerosol-forming member configured to be heated up to a first operating temperature and thereafter to a second higher operating temperature, and a second aerosol-forming member configured to be heated up to at least the first operating temperature as the first aerosol-forming member reaches the second higher operating temperature so that liquid volatilized from the two aerosol-forming members mix with one another.

An atomizing assembly includes a tubing section having an inlet end and an outlet end. The inlet end of the tubing section is connectable to a liquid storage portion, and the outlet end of the tubing section is in fluid communication with an atomizing nozzle. The tubing section is configured to deliver a flow of liquid aerosol-forming substrate through the atomizing nozzle. The atomizing nozzle includes an air channel configured to establish an air flow through the nozzle. The air flow is mixed with the flow of liquid aerosol-forming substrate.