A method of controlling application of material onto a substrate includes ejecting atomized droplets from an array of micro-applicators while the array of micro-applicators cyclically moves about at least one axis. The atomized droplets from each of the plurality of micro-applicators overlap with atomized droplets from adjacent micro-applicators and a diffuse overlap of deposited atomized droplets from adjacent micro-applicators is provided on a surface of the substrate. The array of micro-applicators cyclically rotates back and forth around the at least one axis and/or moves back and forth parallel to the at least one axis. For example, the at least one axis can be a central axis of the array of micro-applicators, a length axis of the array of micro-applicators, a width axis of the array of micro-applicators, and the like. Also, the array of micro-applicators can be part of an ultrasonic material applicator used to paint vehicles.

A method of controlling application of material onto a substrate is provided. The method includes ejecting an ultraviolet (UV) curable material through a plurality of micro-applicators in the form of atomized droplets. At least one UV light source is positioned adjacent to the plurality of micro-applicators and the atomized droplets are irradiated with UV light by the at least one UV light source and curing of the atomized droplets is initiated. The atomized droplets are deposited onto a surface of the substrate and a UV cured coating on the surface is formed thereon. The UV curable material may include a photolatent base catalyst such that the atomized droplets deposited onto the surface continue to cure after being irradiated with the at least one UV light source. The at least one UV light source can include a UV light ring, a UV light emitting diode, and the like.

A fluid filling apparatus for filling containers with a fluid is provided. An ultrasonic frequency is used to vibrate a filling nozzle between successive container filling cycles. The vibrations break a liquid string filament formed at a discharge end of the filling nozzle at the end of each filling cycle. Methods and a fluid filling nozzle for filling containers with a fluid are also provided.

A device or system is provided that provides olfactory stimuli, and includes a piezoelectric vibration device that is used to produce scents corresponding to actions performed in a VR or AR environment, or other application. In some implementations, a user interacts with one or more game elements within a game program being executed by a game engine, and responsive to the interaction, the game engine may communicate a series of commands that cause a piezoelectric device of the device to generate scents to be experienced by the user.

A vibrating piezoelectric atomizer comprising: a piezoelectric tube having a length, a first end defining an opening and a second end, the second end of the piezoelectric transducer tubular body is connected to a horn; the horn is dimensioned to be half wavelength resonator; the horn is folded and located alongside the piezoelectric tube; a metallic disk is connected to the horn near the first end of the piezoelectric tube, whereby by applying an alternating voltage across electrodes of the piezoelectric tube, the piezoelectric tube is excited into a resonant vibration when frequency of excitation equals to half wavelength resonant frequency of the piezoelectric tube's length and vibrates in synchronism and is communicated to the metallic disk to atomize a liquid.

A nozzle apparatus is described in relation to dispensing colorant liquid in a paint tinting system. The nozzle apparatus comprises: a nozzle (12, 13) with a passage (14, 15) for a colorant liquid (16), the passage (14, 15) extending to an outlet for dispensing colorant liquid from the nozzle (12, 13); and an ultrasound transducer (20) for applying ultrasonic vibration to the nozzle (12, 13) and/or to liquid (16) at the nozzle outlet.

The invention discloses a low-frequency electrostatic ultrasonic atomization nozzle that relates to an electrostatic atomizer in the field of agricultural engineering. The low-frequency electrostatic ultrasonic atomization nozzle comprises a transducer back cover, piezoelectric ceramics, a transducer front cover, an ultrasonic horn and a fastening screw. Furthermore, the fastening screw is set through the transducer back cover, the piezoelectric ceramics and the center round hole of the transducer front cover in sequence; a liquid inlet channel is designed in the axial center of the ultrasonic horn; an air intake channel is designed in a position that deviates from the axial center; the top of the ultrasonic horn is machined as a concave spherical surface; and a suspended ball is arranged on the concave spherical surface. Moreover, compressed air in the axial eccentric position is used for rotating the suspended ball at high speeds; a charging needle is electrified to generate an electric field for the suspended ball that the droplets generated by low-frequency ultrasonic atomization and can electrostatically atomize again, and it can make the droplets take on an electrostatic charge; finally, the electrified droplets are sprayed out from the nozzle. The low-frequency electrostatic ultrasonic atomization nozzle breaks through the bottleneck of a low-frequency ultrasonic atomization nozzle that struggles to generate ultrafine droplets and enables the droplets to take on static electricity to increase adhesion so that the droplets can attach to crops more efficiently.

An atomizer for applying a coating includes a nozzle plate, an actuator, and an acoustic focusing device. The nozzle plate defines at least one aperture. The actuator is configured to oscillate to form pressure waves within a fluid to eject the fluid from the nozzle plate. The acoustic focusing device focuses the pressure waves toward the apertures.

A method of prepping a cylindrical inner surface of a bore using a high-frequency forced pulsed waterjet apparatus entails generating a pressurized waterjet using a high-pressure water pump, generating a high-frequency signal using a high-frequency signal generator, applying the high-frequency signal to a transducer having a microtip to cause the microtip to vibrate to thereby generate the high-frequency forced pulsed waterjet, and rotating the rotatable ultrasonic nozzle inside the bore to prep the inner cylindrical surface of the bore using the high-frequency forced pulsed waterjets exiting from the angled exit orifices of the rotatable ultrasonic nozzle.

Disclosed is an essence atomizer having an integrally formed universal connector, comprising: an atomizer universal connector integrally formed into a pipe piece, and an outer shell. Wherein, the pipe port of the first end portion is greater than the pipe port of the second end portion. On the pipe port of the first end portion is disposed inward in sequence a front connection port, the inner threads, and a bottom groove for placing a rubber ring. While on the pipe port of the second end portion is disposed an expansion ring connected to an atomizer plate, an oil prevention pad, and a nozzle cover. The essence atomizer is compact in size and simple in structure Since the essence atomizer is integrally formed into a piece, so it requires less components, and the production process can be reduced.