An electrodischarge apparatus has a nozzle that includes a discharge chamber that has an inlet for receiving water and an outlet. The apparatus has a first electrode extending into the discharge chamber that is electrically connected to one or more high-voltage capacitors. A second electrode is proximate to the first electrode to define a gap between the first and second electrodes. A switch causes the one or more capacitors to discharge across the gap between the electrodes to create a plasma bubble which expands to form a shockwave that escapes from the nozzle ahead of the plasma bubble.

The present invention includes and provides a method of delivering a medicament to an eye of a subject in need thereof a solution, the method comprising: (a) providing droplets containing the medicament with a specified average size and average initial ejecting velocity; and (b) delivering the medicament to the eye, where the droplets deliver a percentage of the ejected mass of the droplets to the eye.

Spraying devices capable of producing a fog of micro-droplets from a liquid, and which includes detection of the level of the liquid to be sprayed. The micro-droplets are generated by a piezoelectric element coupled to an acoustic concentrator.

A method of delivering safe, suitable, and repeatable dosages to a subject for topical, oral, nasal, or pulmonary use and a device for droplet ejection includes a fluid delivery system capable of delivering a defined volume of the fluid in the form of droplets having properties that afford adequate and repeatable high percentage deposition upon application. The method and device include a housing, a reservoir disposed within the housing for receiving a volume of fluid, an ejector mechanism configured to eject a stream of droplets having an average ejected droplet diameter greater than 15 microns, the stream of droplets having low entrained airflow such that the stream of droplets deposit on the eye of the subject during use.

An aerosol delivery device is provided that includes at least one housing, a nozzle and a control component. The housing encloses a reservoir configured to retain an aerosol precursor composition. The nozzle is coupled to the housing to discharge aerosol precursor composition from the reservoir, and the nozzle includes a piezoelectric or piezomagnetic material surrounding a mesh. The control component includes a microprocessor coupled to and configured to drive the piezoelectric or piezomagnetic material to vibrate and cause a discharge of components of the aerosol precursor composition through the mesh and thereby produce an aerosol for inhalation by a user, with the components of the aerosol precursor composition discharged through the mesh having a diameter of less than one micrometer.

An artificial flame apparatus produces a simulated flame using a plume of mist that is illuminated around, about, and through an artificial wick. A mist may be produced by a transducer, such as an ultrasonic transducer that is in contact with liquid from a liquid reservoir. The rate of mist exiting the housing may be modulated to produce a more realistic looking artificial flame. A light source is configured to illuminate the mist and/or the artificial wick. The artificial wick may be in the shape of a wick or flame and may include a light source. One or more light sources may be configured as the artificial wick. The light intensity, color and rate of change of light may be modulated to produce a more realistic looking artificial flame. A standing wave tube may vary the rate of mist exiting one or more enclosure openings in the tube enclosure.

An atomizing device comprises: a liquid conveying unit, wherein the liquid conveying unit comprises a liquid storage container having a liquid outlet, and the liquid conveying unit is configured to output a liquid to be atomized from the liquid outlet of the liquid storage container at a flow rate; an atomizing unit configured to receive the liquid to be atomized from the liquid outlet of the liquid storage container and atomize the liquid to be atomized into mist, wherein the atomizing unit has a predetermined atomization rate; and a control unit, the control unit being in communication with the liquid conveying unit, and the control unit is configured to control the flow rate at which the liquid conveying unit outputs the liquid to be atomized according to a predetermined atomization rate of the atomizing unit.

A method of delivering safe, suitable, and repeatable dosages to a subject for topical, oral, nasal, or pulmonary use and a device for droplet ejection includes a fluid delivery system capable of delivering a defined volume of the fluid in the form of droplets having properties that afford adequate and repeatable high percentage deposition upon application. The method and device include a housing, a reservoir disposed within the housing for receiving a volume of fluid, an ejector mechanism configured to eject a stream of droplets having an average ejected droplet diameter greater than 15 microns, the stream of droplets having low entrained airflow such that the stream of droplets deposit on the eye of the subject during use.

A compact apparatus for atomisation of fluid samples comprises a sonotrode (11), placed so that an ultrasonic wave emitted by the sonotrode is directed through a channel (25) in a separate channel device (21) and reflected by from the interface (26) in a high-low impedance transition zone (Tz), so that a standing wave is formed within the channel. A positive air flow through the channel, driven by a pressure differential at each end of the channel, interacts with the working fluid or slurry being delivered by a fluid delivery device (30) to atomise it. The speed of the air flow and the dispersal, homogeneity, and size of particles in the slurry sample can be controlled by varying the shape of the channel outlet.

A fluid ejection device is a fluid ejection device adapted to eject a fluent material including an actuator, and a drive signal supply section adapted to output a signal used to drive the actuator, wherein the actuator includes a first piezoelectric element and a second piezoelectric element connected in series to each other. The drive signal supply section is capable of outputting a first drive waveform and a second drive waveform having a voltage change part steeper than that of the first drive waveform to the first piezoelectric element and the second piezoelectric element, outputs the second drive waveform to the second piezoelectric element in a case of outputting the first drive waveform to the first piezoelectric element, and outputs the first drive waveform to the second piezoelectric element in a case of outputting the second drive waveform to the first piezoelectric element.