A vibrating device includes a dome-shaped cover, a cylindrical or substantially cylindrical vibrating body, and a piezoelectric element. The dome-shaped cover is disposed so as to include a detection field of an optical detector element, and the cylindrical or substantially cylindrical vibrating body is fixed to the cover. The piezoelectric element is fixed to the vibrating body and vibrates the cover via the vibrating body. The vibrating body includes a cylinder portion, a first connection portion connected to a first end portion of the cylinder portion, a first ring-shaped portion connected to the first connection portion at a position near the cover, a second connection portion connected to a second end portion of the cylinder portion, and a second ring-shaped portion connected to the second connection portion at a position opposite to a surface to which the cylinder portion is connected.

A nozzle plate (201) for use in a liquid droplet production apparatus and such apparatus, the nozzle plate comprising a flexible substrate having a linear array of nozzles that extend through said plate, said nozzles being arranged in at least one line, forming thereby a nozzle-bearing region, wherein the substrate is curved so as to impart an increased longitudinal stiffness to it. The apparatus comprises a piezo actuator (202, 203), which may have slots (211) separating fingers acting on the nozzle plate (201). The nozzle plate may be separable form the actuator.

A system comprises a plate (235) and one or more transducers (200) coupled to the plate (235). Each of the one or more transducers (200) is operable to generate ultrasonic waves which propagate through the plate (235) in a propagation direction (240), for ultrasonically clearing droplets (250) of fluid from the plate (235). The plate (235) comprises one or more structures disposed in the path of ultrasonic waves and configured to control the propagation of ultrasonic waves in the plate (235) to achieve a predetermined amount of ultrasonic wave energy propagating in a direction opposite to the propagation direction (240). The value of one or more parameters of the shape of each of the one or more structures is predetermined to achieve a predetermined effect on ultrasonic waves incident on the structure.

The invention discloses microparticle multi-channel time-sharing separation device and method based on an arcuate interdigital transducer. An arcuate interdigitated electrode is connected to an output channel of a signal generator. The arcuate interdigitated electrode and a polydimethylsiloxane (PDMS) microfluidic channel are placed on a lithium niobate chip. The arcuate interdigitated electrode is mainly formed by an interdigitated electrode being asymmetrically bent from a straight line into an arcuate curve. Two electrode ends of the arcuate interdigitated electrodes are asymmetrically arranged with one end big and another end small. The PDMS microfluidic channel includes a main flow channel, two inlet ends, and multiple outlet ends. The main flow channel is an approximately arcuate flow channel arranged around an outer side of the arcuate interdigitated electrode. Particles are patterned in a coverage section of surface acoustic waves to complete separation of microparticles.

An atomization apparatus includes: an atomization sheet for atomizing a drug and having a rated voltage; and a voltage control element, electrically connected to the atomization sheet, for providing a operating voltage for the atomization sheet, wherein the operating voltage is not less than 70 V, and the operating voltage is 60% to 150% of the rated voltage of the atomization sheet, or the ratio of the operating voltage to the rated voltage of the atomization sheet is greater than 100% and not greater than 150%. A quick atomization method includes: providing an operating voltage to an atomization sheet, wherein the operating voltage is not less than 70 V, and the operating voltage is 60% to 150% of a rated voltage of the atomization sheet, or the ratio of the operating voltage to the rated voltage of the atomization sheet is greater than 100% and not greater than 150%.

A method of measuring dissociation of the biomolecular bonds in one or multiple sample wells using super-resolution force spectroscopy (SURFS). SURFS utilizes precise ultrasound radiation to exert an acoustic radiation force on the biomolecular bonds labeled with magnetic particles. The force-induced dissociation of the protein bonds labeled with magnetic particles may be measured as a reduced magnetic signal by a magnetic sensor. The force resolution allows for differentiating biomolecular bonds with an extremely high level of precision. The biomolecular bonds include protein-protein, protein-nucleic acid, nucleic acid-nucleic acid, small molecule-protein, and small molecule-nucleic acid interactions.

The present disclosure provides an aerosol delivery device that may comprise a housing defining an outer wall and further including a power source and a control component. The device also includes a mouthpiece portion that defines an exit aerosol path, a tank portion that includes a reservoir configured to contain a liquid composition, and an atomization assembly configured to vaporize the liquid composition to generate an aerosol. The atomization assembly includes a mesh plate and a vibrating component, wherein the mesh plate and the vibrating component are configured to be separable from each other at a detachable interface. The detachable interface may be located at various locations of the device, including between the mouthpiece portion and the tank portion, within the mouthpiece portion, within the tank portion, within a separable atomization assembly, within a cartridge, within a control unit, or between a cartridge and a control unit.

The invention discloses microparticle multi-channel time-sharing separation device and method based on an arcuate interdigital transducer. An arcuate interdigitated electrode is connected to an output channel of a signal generator. The arcuate interdigitated electrode and a polydimethylsiloxane (PDMS) microfluidic channel are placed on a lithium niobate chip. The arcuate interdigitated electrode is mainly formed by an interdigitated electrode being asymmetrically bent from a straight line into an arcuate curve. Two electrode ends of the arcuate interdigitated electrodes are asymmetrically arranged with one end big and another end small. The PDMS microfluidic channel includes a main flow channel, two inlet ends, and multiple outlet ends. The main flow channel is an approximately arcuate flow channel arranged around an outer side of the arcuate interdigitated electrode. Particles are patterned in a coverage section of surface acoustic waves to complete separation of microparticles.

There is presented a method for driving a piezoelectric device and an atomizer for atomizing a fluid, and an atomization method for a fluid using a piezoelectric device; the atomizer employs a piezoelectric device and circuitry that uses a switching voltage across the piezoelectric device at an operating frequency; sensing a sensed voltage corresponding to a phase of the piezoelectric device; and responsive to whether the sensed voltage is in phase or out of phase relative to the switching voltage, changing the operating frequency provided to the piezoelectric device, and the changing is one of: increasing the operating frequency by a first value, or decreasing the operating frequency by a second value.

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.