A misting system has a fan unit. A housing is provided having an opening formed there through. The fan unit is positioned within the opening. A plurality of apertures is formed in a bottom section of the housing. A plurality of misting nozzles is provided, wherein an individual misting nozzle is positioned proximate each aperture. A cap is positioned over the opening in a bottom section of the housing. A plurality of channels formed in the cap, wherein each of the plurality of channels is curved in a same direction of a rotational direction of the fan unit when the fan unit is forcing air downward and extend down and away from the cap forming a curved “V” shaped trough, wherein at least one curved “V” shaped trough is aligned with each of the plurality of misting nozzles.

A humidifier includes a first housing removably connected to a second housing that includes the majority of the electrical components of the humidifier. The first housing includes a first air inlet for accepting air; a first air outlet; a central chamber for holding water; a piezoelectric transducer installed in the central chamber for atomizing water; and a first electrical connector electrically connected to the piezoelectric transducer. The first housing is configured to discharge humidified air from the first air outlet. The second housing includes a second air outlet removably connectable to the first air inlet; a forced air source for forcing air out of the second air outlet; a second electrical connector configured to removably electrically connect to the first electrical connector; and an electric circuit electrically coupled to the forced air source for electrically powering the forced air source and electrically coupled to the second electrical connector for electrically powering the piezoelectric transducer.

Mist based humidification systems are employed in numerous environments. However, such systems are typically small portable units whilst it would be beneficial to employ ultrasonic based mist humidifiers in larger environments. However, these environments introduce additional requirements such as reducing the emission/distribution of condensed water as droplets from the humidifier, allowing independent placement of the mist generator from the mist distribution element(s), and the requirement to throw the mist a reasonable distance into the environment rather than relying upon the circulation within the environment to achieve distribution. Embodiments of the invention address these issues whilst also supporting modular humidification systems operating at multiple capacities.

A system for purifying and pre-conditioning intake air in an air conditioning unit comprises an energy exchange unit having an air inlet, an air outlet, a primary air flow running from the air inlet to the air outlet, and an active energy exchanging element or elements, and at least one spray washer having at least one nozzle, the spray washer positioned between the air inlet and the next active element, wherein the at least one spray washer is configured to dispense droplets of a fluid into the intake air from the at least one nozzle. A method for purifying and pre-conditioning intake air in an air conditioning unit is also described.

A spray device includes a base seat unit, a liquid container having a liquid-receiving space, a nozzle unit including a nozzle and a drawing tube, and an electric gas pump. The nozzle has an outlet, and a gas inlet and a liquid entrance that are in spatial communication with the outlet. The drawing tube spatially interconnects the liquid-receiving space and the liquid entrance. The electric gas pump has a gas supplying hole spatially communicated with the gas inlet. The electric gas pump is operable to provide a gas into the gas inlet through the gas supplying hole, such that the liquid stored in the liquid-receiving space is drawn into the liquid entrance through the drawing tube and thereafter exits the outlet together with the gas.

The application discloses a humidifier with a mist outlet, including a water tank; a seat provided with a water groove for receiving water from the water tank and a heating cavity; a first water channel provided on the seat, communicated the water groove with the heating cavity; and a first air duct enabling airflow introduced by an air inlet component to flow through the first water channel to cool the water in the first water channel, and enabling the airflow to flow to the mist outlet of the humidifier after flowing through the first water channel. When the heat in the heating cavity is transferred to the first water channel, the water in the first water channel can be purged by the airflow guided by the first air duct to cool the water. This prevents an increase in a temperature of a humidifier housing.

An evaporation heater arranged in a constant-temperature high-humidity storage, the evaporation heater comprising: a water storage tank arranged in a lower part of an enclosure of the evaporation heater; a temperature regulator configured to set water stored in the water storage tank to a target temperature; and an air blowing mechanism which is arranged in front in an air-blowing direction with respect to the water storage tank and which is configured to blow air to water in the water storage tank, set the temperature inside the constant-temperature high-humidity storage to the target temperature, and hold the humidity inside the constant-temperature high-humidity storage at saturated humidity.

The present disclosure relates to a field of humidifiers and in particular to an atomization humidifier that increases an amount of vapor through a specially designed atomizing air channel. The atomization humidifier includes a main body and an atomizing chamber arranged in the main body. The atomizing chamber includes an atomizing generator. An atomizing air channel is arranged on the atomizing generator. A flow guide plate is obliquely arranged on a top end of the atomizing air channel. A water inlet is arranged on an upper end of the atomizing air channel. An opening of the water inlet is upward. A lower end of the atomizing air channel is an air guide tube with hollow vacancies. The atomization humidifier realizes water vapor concentration by setting the atomizing air channel arranged on the atomizing generator, which improves an atomizing efficiency of the atomization humidifier by optimized structure, and is low in cost and good in atomizing effect.

A humidifying apparatus includes a nozzle and a base on which the nozzle is mounted. The nozzle has respective first and second air inlets, air outlets and interior passages for conveying air therefrom and thereto. The nozzle defines a bore through which air outside the humidifying apparatus is drawn by air emitted from the air outlets. The base generates first and second air flows through the respective first and second interior passages, and a water reservoir. First and second air passageways convey the first and second air flows to the respective first and second air inlets. As the second air passageway conveys the second air flow over the water in the reservoir, water stored in the reservoir is agitated. An ultraviolet radiation generator irradiates the agitated water for a period of time before water stored in the reservoir is atomized to increase the humidity of the second air flow.

A dry fog diffuser comprises a support. A shroud is mounted to the support. The shroud comprises a tubular elbow having an inlet end and an outlet end. The shroud is mounted with a long side of the elbow including a drain port facing downward. An atomizing nozzle is mounted at the inlet end of the elbow and aligned with an axis of the elbow at the inlet end. The nozzle is connected, in use, to a water supply and an air supply. The diffuser produces a dry fog exiting shroud at the outlet end of the tubular elbow.