An energy gathering device and an ultrasonic humidifier relate to a field of humidifier technology. The energy gathering device includes an energy gathering tube and an energy gathering floating body. The energy gathering device is arranged in a mist outlet tube. The mist outlet tube is disposed inside a water tank of an ultrasonic humidifier. The energy gathering floating body includes an energy gathering cavity. A first end of the energy gathering cavity is communicated with a second end of the energy gathering cavity. An extension direction of the energy gathering cavity is same as an extension direction of a tube cavity of the mist outlet tube. The energy gathering tube is fixed in the energy gathering cavity. A tube cavity of the energy gathering tube is communicated with the energy gathering cavity of the energy gathering floating body.

An energy gathering device and an ultrasonic humidifier relate to a field of humidifier technology. The energy gathering device includes an energy gathering tube and an energy gathering floating body. The energy gathering device is arranged in a mist outlet tube. The mist outlet tube is disposed inside a water tank of an ultrasonic humidifier. The energy gathering floating body includes an energy gathering cavity. A first end of the energy gathering cavity is communicated with a second end of the energy gathering cavity. An extension direction of the energy gathering cavity is same as an extension direction of a tube cavity of the mist outlet tube. The energy gathering tube is fixed in the energy gathering cavity. A tube cavity of the energy gathering tube is communicated with the energy gathering cavity of the energy gathering floating body.

A unit dose capsule for use with a sonic generator includes a deformable membrane adapted to releasably engage the distal end of the elongate horn, a nozzle including at least one delivery opening; a nozzle including at least one delivery opening; and a reservoir containing a liquid composition disposed therebetween. When the unit dose capsule is engaged to the distal end of the elongate horn, the nozzle is disposed in an outwardly facing orientation, and the reservoir is in liquid communication with the at least one nozzle. The unit dose capsule can be included in a kit with a handheld misting device comprising a housing having a dispensing window arranged and configured to contain a sonic generator and a power source.

A printing apparatus includes a carrying platform on which a substrate is placed, a cartridge configured to store and supply ink, and a print head configured to atomize the ink into ink droplets and deposit the ink droplets on a printing region of the substrate.

An aerosol generator with electrical power conducting pins has a vibratable plate with apertures therein and an annular piezo. An annular support member supports the piezo and the vibratable plate. A first electrical power conducting pin engages directly with a first, top, surface of the piezo. A second electrical power conducting pin indirectly conducts electrical power to a second surface of the piezo, by contacting an extension tab. There is a film of cured epoxy adhesive on the tab. The aerosol generator avoids need for soldered joints for electrical contact, and the pins are conveniently mounted parallel to each on the same lateral and top side of the piezo and support member. The pins may have multi-point tips for particularly effective electrical contact.

A humidification system including a water-delivery system, an air-delivery system, a control system, and at least one fog-generation system. In example forms, the system includes a water-and-air delivery bar, a fog-delivery block, and/or a tubing-and-track delivery system. In another example form, a humidification system includes a housing having a nozzle discharge body, an air inlet coupling having an air delivery conduit extending therethrough, and a water inlet coupling having a water delivery conduit extending therethrough, and further including means for providing heating and/or a consistent back-pressure and flowrate across multiple nozzles in a multi-nozzle array.

A humidification system including a water-delivery system, an air-delivery system, a control system, and at least one fog-generation system. In example forms, the system includes a water-and-air delivery bar, a fog-delivery block, and/or a tubing-and-track delivery system. In another example form, a humidification system includes a housing having a nozzle discharge body, an air inlet coupling having an air delivery conduit extending therethrough, and a water inlet coupling having a water delivery conduit extending therethrough, and further including means for providing heating and/or a consistent back-pressure and flowrate across multiple nozzles in a multi-nozzle array.

A volatile material dispenser comprises a base that houses a printed circuit board. The base includes at least one button and a plurality of visual indicators along a front portion. The volatile material dispenser further comprises a stand assembly that is coupled with the base. The stand assembly includes a platform defining a front portion and a rear portion, a stand that is disposed above and on the rear portion of the platform, a manifold that is disposed at an upper end of the stand and defines an outer side surface from which extends a plurality of radially spaced ribs, and a piezoelectric assembly disposed within the manifold. The volatile material dispenser further comprises a cover that is configured to be attachable to and detachable from the base. The cover defines a chimney that defines a longitudinal axis. The manifold includes a refill chassis.

Provided is a mist generator including: a container that stores a liquid; a gas supply unit that supplies a gas into the container; and an electrode that generates plasma of the gas between the electrode and the liquid, where the supply direction of the gas fed from the gas supply opening of the gas supply unit is different from a direction in which gravity acts.

An aperture plate is manufactured by plating metal around a mask of resist columns having a desired size, pitch, and profile, which yields a wafer about 60 μm thickness. This is approximately the full desired target aperture plate thickness. The plating is continued so that the metal overlies the top surfaces of the columns until the desired apertures are achieved. This needs only one masking/plating cycle to achieve the desired plate thickness. Also, the plate has passageways formed beneath the apertures, formed as an integral part of the method, by mask material removal. These are suitable for entrainment of aerosolized droplets exiting the apertures.