A nebuliser for nebulising liquid droplets, including: a housing; at least one piezoelectric substrate (2) accommodated within the housing and having a transducer surface (2a) upon which is located at least one electroacoustic transducer (48) for generating acoustic wave energy within the at least one piezoelectric substrate (2), and an opposing non-transducer surface (2b); a liquid supply system for supplying a liquid to at least one of the transducer and non-transducer surfaces, the liquid supply system including a reservoir (3) for accommodating the liquid, and at least one relatively rigid supply conduit in contact with the at least one piezoelectric substrate (2) for supplying the liquid from the reservoir (3) to the at least one piezoelectric substrate (2); and a sensor for detecting a volume of liquid on the at least one piezoelectric substrate (2).

A laundry washing machine comprising: a cabinet, a washing tub housed inside the cabinet, a tubular mantle rotatably housed inside the cabinet, an electric additive treating device mounted in/on the tubular mantle and configured for treating a washing and/or rinsing additive loaded within the tubular mantle in such a way to generate within the tubular mantle a solution of washing and/or rinsing additive water.

A processing liquid nozzle according to an aspect of the present invention comprises an ultrasonic application part (60), a first supply flow path (71), a discharge flow path (72), and a second supply flow path (73). The ultrasonic application part (60) has a vibrator (61) for generating ultrasonic waves, and a vibrating body (62) joined to the vibrator (61). The first supply flow path (71) supplies a first liquid (L1) to a position contacting the vibrating body (62) of the ultrasonic application part (60). The discharge flow path (72) supplies the first liquid (L1), to which ultrasonic waves have been applied by the ultrasonic application part (60), to a discharge port (74). The second supply flow path (73) is connected to the discharge flow path (72) on the downstream side from the ultrasonic application part (60), and supplies a second liquid (L2) to the discharge flow path (72).

A decontamination system not requiring large-scale equipment such as large-diameter ducts and anti-condensation heaters and for that reason capable of efficiently using a decontamination liquid. Long pipes can be installed for each of a plurality of rooms to be decontaminated, a decontamination liquid is not present in supply pipes as a residual dead liquid, and a proper amount of decontamination liquid can essentially be supplied for each room to cause no failure of an ultrasonic vibrator.

The decontamination system employs a decontamination mist and includes a compressed air generating means and a decontamination liquid supplying means, and each room to be decontaminated is provided with a primary mist generating means and a secondary mist generating means. The conveyance distance of a primary mist supply pipe communicating the primary mist generating means and the secondary mist generating means is longer than the conveyance distance of a decontamination liquid supply pipe communicating the decontamination liquid supplying means and the primary mist generating means.

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 nebulizer unit includes a housing, which includes an aerosol generator with a feed chamber disposed at one side, an ampoule receiver, an opening device with at least one opening, which is in communication with the feed chamber, and an ampoule with liquid, which comprises at least one opening, with which it can be inserted or used in the ampoule receiver, wherein the ampoule has a connection region, which interacts with a connector of the ampoule receptacle in order to hold the ampoule firmly in the ampoule receiver and to connect the openings and such that they are leak tight.

A dispenser capable of dispensing a fluid via a vertically-oriented piezo device comprises a reservoir in the form of a replaceable cartridge containing a fluid to be dispensed, a planar piezo element having front and rear surfaces and which in use is oriented with its plane vertical and which is drivable to vibrate and thereby dispense fluid from the front surface, and a pump to draw a predetermined amount, or dose, of fluid from the reservoir and to drive the dose of fluid at a predetermined above-atmospheric pressure to the rear surface of the piezo element for dispensing.

An electronic device for producing an aerosol for inhalation has a mouthpiece and an elongate housing. The mouthpiece attaches to an upper end of the housing. The housing contains a liquid container and a mesh assembly with mesh material that vibrates when actuated for aerosolizing liquid from the container. The mouthpiece covers the mesh assembly at the upper end of the housing, and the aerosol produced by the mesh assembly may be inhaled through the mouthpiece by a person. The housing contains circuitry and a power supply, preferably are located in a lower half of the housing, for actuating vibration of the mesh material. Electrical pathways connect the mesh assembly with the circuitry and power supply. The power supply may comprise one or more batteries located at the lower end of the housing. The aerosol is produced without smoldering of the liquid and without using a compressed gas.

The invention relates to a nebulizer system for a motor vehicle, which is arranged to be fluidly connected to a liquid storage reservoir, which is called a cartridge, the nebulizer system including: a tank, a nebulizer component producing a mist intended to penetrate a passenger compartment of the motor vehicle, a channel for circulation of the liquid from the cartridge to the tank, and a channel for circulation of air between the cartridge and the nebulizer system.

An aerosol-generating device includes: a housing having a liquid storage cavity for accommodating an aerosol-generating substrate; a metal element arranged outside the liquid storage cavity; a static electricity generating assembly including a positive terminal and a negative terminal, one of the positive terminal and the negative terminal being electrically connected to the metal element so as to cause a part of the aerosol-generating substrate that is close to the metal element in the liquid storage cavity to be charged by electrostatic induction when the static electricity generating assembly is electrified; and a vaporization sheet, that, when electrified, vaporizes the charged aerosol-generating substrate to generate a charged aerosol.