A method is disclosed comprising drawing air into a robotic vapor device, exposing the drawn air to a sensor to detect one or more constituents in the drawn air, determining first measurement data for the one or more constituents of the drawn air via the sensor, transmitting the first measurement data to a one or more of a plurality of vapor devices via a peer-to-peer network, receiving second measurement data from the one or more of the plurality of vapor devices via the peer-to-peer network, determining one or more vaporizable materials to vaporize based on the first measurement data and the second measurement data, and dispensing a vapor comprised of the one or more vaporizable materials.

A fan coil apparatus includes a humidification unit having a water mist production member, and an air flow path. The water mist production member includes a chamber. In operation, a water mist produced by the water mist production member is present in the chamber. The air flow path extends from an air inlet to an air outlet and passes through the chamber. Air passing through the air flow path draws water mist from the chamber and out the air outlet. The air inlet includes a scoop positioned in a first portion of an air flow path of the fan coil apparatus.

An olfactory display includes a housing and a plurality of fragrance chambers formed in the housing. In each fragrance chamber, a solid-like fragrance source is accommodated and an airflow source is provided to send air into the fragrance chamber from an air intake port. An auxiliary airflow source that emits odorless air is also provided in the housing. The airflow source and the auxiliary airflow source are operated alternately or simultaneously. In response to a user operating an adjustment knob of a controller, operating time periods and stopping time periods of the airflow source and the auxiliary airflow source are changed, or the number of operating times is changed within a predetermined operating time period. A mixing ratio of the fragrance and the odorless air may also be adjusted by changing a voltage value of an alternating voltage to be applied to a piezoelectric device of the airflow source.

A constant water level humidifier has an outer tank with an outer outlet disposed at the bottom, the outer outlet is disposed with an oscillating plate, the upper portion of the outer tank is disposed with an outer air vent connected to the outer world; wherein the outer tank is further disposed with an inner tank, the upper portion of the inner tank is disposed with an inner air vent connected to the outer air vent, the bottom portion of the inner tank is disposed with an inner outlet connected to the outer outlet of the outer tank and an inner inlet connected to the chamber of the outer tank, the inner inlet is disposed with a water level control mechanism.

A floating-type humidifier according to an exemplary embodiment of the present invention includes: a floating body which floats in a reservoir that accommodates water; an ultrasonic wave generation unit which is installed by being inserted into the floating body, and atomizes the water, which is introduced into a lower side of the floating body, into a water particles state by means of ultrasonic vibration; a guide tube which is detachably coupled to the floating body, is installed above the ultrasonic wave generation unit, guides the water particles, and has a fan installation hole horizontally and penetratively formed in a lateral portion of the guide tube; a blower fan which is coupled in the fan installation hole, and injects air into the guide tube so as to discharge the water particles to an upper side of the guide tube; and a discharge groove which is formed in an upper surface of the floating body so as to communicate with the fan installation hole in which the blower fan is mounted.

A method for controlling temperature of a heating element in an electronic inhaler for vaporizing an aerosol forming substrate. The method includes, in a first stage, applying power to and increasing a temperature of the heating element from an initial temperature to a first temperature; in a second stage, controlling power to decrease the temperature of the heating element from the first temperature to a second temperature; and in a third stage, controlling the heating element to provide a constant temperature operation at the second temperature. During detection of inhalation, power to the heating element is increased to raise its temperature to a third temperature. In the third stage, the heating element increases the temperature only when suction is detected, thereby ensuring that a supply of an aerosol to the inhaler and minimize waste of electric energy and the aerosol forming substrate.

A method is disclosed comprising drawing air into a robotic vapor device, exposing the drawn air to a sensor to detect one or more constituents in the drawn air, determining first measurement data for the one or more constituents of the drawn air via the sensor, transmitting the first measurement data to a one or more of a plurality of vapor devices via a peer-to-peer network, receiving second measurement data from the one or more of the plurality of vapor devices via the peer-to-peer network, determining one or more vaporizable materials to vaporize based on the first measurement data and the second measurement data, and dispensing a vapor comprised of the one or more vaporizable materials.

The present invention relates to an electrostatic atomizing device of a disposable capsule, wherein the capsule in accordance with an embodiment may include an ejection pin having a functional water solution impregnated therein, a sealing member for sealing the ejection pin, and a pressing member for pushing the ejection pin with external force to move the ejection pin such that a portion of the ejection pin penetrates the sealing member and is projected to an outside of the capsule, and the electrostatic atomizing device in accordance with an embodiment may include a hole for receiving a capsule, and a voltage applying portion in the hole so as to be brought into contact with an ejection pin being projecting to an outside of the capsule received in the hole for applying a voltage to the ejection pin in contact with thus.

A cylindrical humidifier, including a housing, a water tank, an atomization assembly, and a water feed assembly. The water tank is mounted in the housing, and is detachably connected to the atomization assembly. A lower end of the atomization assembly is arranged in the housing while an upper end thereof is detachably connected to a top end of the housing. The water feed assembly is mounted at the bottom of the atomization assembly and the water tank. The water feed assembly includes a lever bracket, a sealing bar, a pushing block, a spring, a pushing ball, a pushing bar, and a float. Water entering the water tank is controlled through the water feed assembly, so that the humidifier can maintain a constant water depth, and is always kept in the best working state, thereby achieving the maximum atomization efficiency.

In an ultrasonic atomizing device of the present disclosure, a raw material solution separation pipe is provided on a side surface of an atomization container. The raw material solution separation pipe has a raw material solution storage space for storing the raw material solution, and a raw material solution passage port for supplying and discharging the raw material solution to and from the raw material solution container. A liquid surface detection unit is provided in the vicinity of the raw material solution separation pipe. The liquid surface detection unit detects the level of the liquid level of the raw material solution in the raw material solution storage space, and outputs a liquid surface detection signal indicating the level of the detected liquid level.