A liquid atomizing apparatus includes: an atomizing body member made of a porous body having micropores connected in a three-dimensional network, the atomizing body member having a surface including a part serving as a gas pressurized-inflow surface and another part serving as a gas release surface; a liquid supply unit for supplying a liquid to the atomizing body member, the liquid being to be impregnated into the micropores of the atomizing body member; and a gas supply unit for setting gas pressure on the gas pressurized-inflow surface of the atomizing body member to be higher than on the gas release surface of the atomizing body member and injecting the gas into the micropores of the atomizing body member through the gas pressurized-inflow surface, and releasing a mist of the liquid having been impregnated in the micropores together with the gas from the gas release surface.

A vapor delivery system having: a) a base unit configured to generate a supply of vapor; and b) a vapor control system configured to allow a user to selectively: a) cause vapor generated by the base unit to be discharged primarily to a surrounding space within which the base unit resides to thereby increase vapor density in the surrounding space; and b) cause vapor generated by the base unit to be discharged primarily to a vapor guide structure configured to: i) be placed operatively with respect to a user's face; and ii) guide discharging vapor generated by the base unit into at least one of the user's nose and mouth with the vapor guide structure placed operatively with respect to the user's face.

A battery assembly for an electronic cigarette, configured to form an electronic cigarette in combination with an atomizing assembly, wherein the atomizing assembly is provided with a magnetic material containing information to be identified, and the battery assembly includes: a magnetic sensor arranged on the battery assembly and configured to obtain the information to be identified; and a microcontroller connected to the magnetic sensor, and configured to control a circuit between the battery assembly and the atomizing assembly to be switched on in a case that the microcontroller determines that the information to be identified matches a preset information, to enable the electronic cigarette to work normally.

An electronic cigarette, comprising a casing and an electrode assembly disposed therein; the electrode assembly comprising an outer electrode (30) and an inner electrode (40), which are insulated from each other; outer electrode (30) being provided with a first through-hole (312); inner electrode (40) being provided with a second through-hole (412); first through-hole (312) and second through-hole (412) communicating to form the gas flow communication channel of the electronic cigarette. The electronic cigarette causes gas to flow directly from the first through-hole (312) to the second through-hole (412), thus shortening the flow path of the gas, making gas flow changes more smoothly, and reducing noise when smoking, improving user experience.

A steam inhaler includes a steam chamber housing having mounted therein a heater assembly. The steam chamber housing defines a steam chamber adapted to receive water. A fitting mounted to the steam chamber housing has a steam conduit section extended toward an exterior vent opening, a nozzle conduit section extended from the steam conduit, and a fresh air conduit section extended from the steam conduit section at a location downstream of the nozzle conduit section. The fitting is configured such that steam flows freely from the steam chamber, through the steam conduit section toward the exterior vent opening, a suction provided at the nozzle redirects at least a portion of the steam into the nozzle conduit section toward a mask, and the fresh air conduit directs fresh air into the steam conduit section to reduce a temperature of the steam exiting the exterior vent opening.

A steam inhaler includes a steam chamber housing having mounted therein a heater assembly. The steam chamber housing defines a steam chamber adapted to receive water. A fitting mounted to the steam chamber housing has a steam conduit section extended toward an exterior vent opening, a nozzle conduit section extended from the steam conduit, and a fresh air conduit section extended from the steam conduit section at a location downstream of the nozzle conduit section. The fitting is configured such that steam flows freely from the steam chamber, through the steam conduit section toward the exterior vent opening, a suction provided at the nozzle redirects at least a portion of the steam into the nozzle conduit section toward a mask, and the fresh air conduit directs fresh air into the steam conduit section to reduce a temperature of the steam exiting the exterior vent opening.

Devices and methods for administering halotherapy are provided for treating respiratory or skin conditions. Variations include a portable devices as well as stationary devices suitable for administering therapy in permanent settings (e.g., in the home).

A moisturizing apparatus includes an ion generating device, a mist generating device, and a control device. The ion generating device generates positive ions and negative ions bound to water molecules from the air by an electrical discharge in the atmosphere. The mist generating device reduces the liquid to fine particles in the form of mist and sprays the liquid in the form of mist. The moisturizing apparatus moisturizes the skin or hair, through combined use of application of ions from the ion generating device and spraying of the mist from mist generating device, toward the skin or hair.

A moisturizing apparatus includes an ion generating device, a mist generating device, and a control device. The ion generating device generates positive ions and negative ions bound to water molecules from the air by an electrical discharge in the atmosphere. The mist generating device reduces the liquid to fine particles in the form of mist and sprays the liquid in the form of mist. The moisturizing apparatus moisturizes the skin or hair, through combined use of application of ions from the ion generating device and spraying of the mist from mist generating device, toward the skin or hair.

The invention relates to a method and a device for generating a nanoaerosol, wherein at least one fluid to be atomized is atomized in a nozzle via a nozzle opening of the nozzle along a discharge direction in the form of fluid particles, the atomized fluid particles are deflected from the discharge direction and larger fluid particles are at least partially separated from smaller fluid particles, the separated larger fluid particles are returned to the fluid to be atomized and the smaller fluid particles are dispensed onto the environment. A cartridge in which the nozzle and the fluid to be atomized are arranged is used. According to the invention, a stream of a carrier gas is generated in the nozzle and at least one fluid to be atomized is brought into contact with the carrier gas.