A fog generator assembly includes a water vapor generator, a fragrance dispenser, and a mixing element fluidly coupled to the water generator and the fragrance dispenser. The mixing element is configured to mix a fog of water vapor from the water vapor generator with a fragrance from the fragrance dispenser to produce an aromatic fog.

A dispensing bottle, comprising a bottle body, a bottle neck connected to the upper portion of the bottle body and a bottle cap connected to the bottle neck; the bottom of the bottle neck extends outward to form a step surface, the top of the bottle body a portion is disposed on the step surface; and further includes a ring sleeve sleeved on the outer side of the bottle neck for squeezing and defining a top end portion of the bottle body which is disposed on the step surface of the bottom of the bottle neck, and is disposed on the outer side of the bottle neck.

A mist supply device configured to decontaminate a target with a proper amount of decontamination agent supplied to the target by converting such agent into a fine mist, and reducing the duration of operations such as aeration to increase decontamination efficiency. The device includes a mist generation means, a mist microparticulating means, and a supply port. The mist generation means converts the decontamination agent into a primary mist and supplies it to the mist microparticulating means, which includes at least one vibration board that is subjected to ultrasonic vibration to generate sound flows from board surfaces by an ultrasound in the vertical direction. The supplied primary mist is subjected to ultrasonic vibration by the sound flows to reduce the primary mist into a secondary mist of smaller size. The generated secondary mist is supplied to the inside of the room through the supply port.

A method of newborn screening (“NBS”) is disclosed comprising directing ultrasonic energy or ultrasonic waves into a metabolite or analyte sample derived from a newborn, neonate or infant so as to cause a mist of charged sample droplets or sample ions to be ejected. The charged sample droplets or sample ions are then mass analysed and a determination is made as to whether or not one or more first metabolites or analytes indicative of a disorder or inborn error are present in the sample.

A fogger includes a blower tube having a passageway, a fan configured to rotate to generate an airflow through the passageway, a reservoir configured to hold a volume of fluid and a volume of air, an air pump in fluid communication with the fluid in the reservoir, a motor configured to drive the fan and the air pump, an atomizing valve, a dispensing line fluidly coupling the atomizing valve to the passageway, a liquid tube fluidly coupling the fluid in the reservoir to the atomizing valve, and an air escape line fluidly coupling the air in the reservoir to the atomizing valve. In response to the air pump providing a stream of compressed air to the reservoir, air moves through the air escape line from the reservoir to the atomizing valve, such that fluid is drawn through the liquid tube and into the atomizing valve to be atomized.

An aeroponics apparatus (1, 201) comprising a grow bed (3, 203) with a reservoir (11, 211) for containing a liquid or a solution. An ultrasonic nebulizer module (5, 205) is attached to the grow bed (3, 203). The ultrasonic nebulizer module (5, 205) comprises an ultrasonic horn (23, 223) having an input end (25, 225) connected to an ultrasonic transducer (27, 227) and an output tip (35, 235). The ultrasonic horn (23, 223) is in contact with a wall (33, 233) of the reservoir (11, 211).

The present disclosure provides an aerosol delivery device and a liquid delivery and atomization assembly for use with an aerosol delivery device. In one implementation, the liquid delivery and atomization assembly comprises a liquid composition, an atomization assembly, and a liquid delivery component configured to transport at least a portion of the liquid composition to the atomization assembly. The liquid delivery component comprises at least one microchannel configured to deliver the portion of the liquid composition to the atomization assembly, and the microchannel includes a variable flow characteristic defined along at least a portion of the microchannel, the variable flow characteristic being configured to control the flow of the portion of liquid composition through the microchannel.

An atomization device includes an atomization machine and an atomization bottle which can be disposed after use. The atomization bottle receives a liquid to be atomized to form a mist. The atomization bottle includes an atomization bottle cork to prevent leakage of the liquid. The atomization bottle cork includes an atomizer fee of power and any control module. A power supply and a control module are disposed on a machine body of the atomization machine. When the atomization bottle is coupled with the atomization machine, the atomizer can be activated by the control module to generate a mist. After the liquid in the atomization bottle is used up, the atomization bottle can be replaced by a new atomization bottle.

Multistage vaporizers, such as for use in medical treatment systems, as well as related methods are described. In one example, a multistage vaporizer includes a first reservoir configured to hold a liquid and one or more pumping transducers positioned in the first reservoir. The multistage vaporizer also includes a second reservoir and one or more vaporizing transducers positioned in the second reservoir. The one or more pumping transducers positioned in the first reservoir are configured to generate and move droplets of a liquid in the first reservoir to the second reservoir, and the one or more vaporizing transducers positioned in the second reservoir are configured to create a vapor of the liquid in the second reservoir.

Systems and techniques are described herein for an insulation system that utilizes a treated gas, such as water vapor, to fill an at least partially transparent cavity that is part of a structure, to provide insulating properties and/or changes in exposure to the sun for a space, proximate to the structure. In some aspects, an insulation system may include a treated gas generation system, which includes at least one of a heating element, a cooling element, or a diffusing element for treating the gas. The system may also include a gas movement system in communication with the gas generation system. The system may further include a gas conduit system in communication with the gas movement system, where the gas movement system causes the treated to be injected into the gas conduit system to change insulation and/or sun exposure characteristics of a space in proximity to the gas conduit system.