A step cavity type low frequency ultrasonic atomization nozzle with a swirlable vortex impeller, has an air intake casing, an inlet casing, a Laval core, a fixed cap, an adjustable pedestal, and taper rectifying sleeve, swirlable vortex impeller, stepped resonance tube, regulative plunger, positioning lead, second pedestal. The regulative plunger is located in the second stepped hole of the stepped resonance tube, and its axial position is adjustable; the swirlable vortex impeller is fixed on the taper resonance tube through the bearing, and the outer cone surface is matched with the inner cone surface of the taper rectifying sleeve. The resonant cavity is improved so that the two-phase fluid in the cavity can generate higher frequency and greater fluctuation of the pressure fluctuation amplitude, optimize the initial atomization performance of the nozzle, and optimize the nozzle outlet, and increase the swirlable vortex impeller.

A mechanical device used to atomize liquids. The device eliminates circular instability at elevated generation frequencies, producing drops of 30-40μ. This is achieved when the central bar has been made with the diameter equal to the diameter of the nozzle. The longitudinal grooves in the central bar are located at the distance which does not exceed the quarter of the wave length of the nozzle working frequency. The depth of grooves at the central bar 8, their width t, number n, the generation frequency f, the width of the resonance groove of the pneumoacoustic bar nozzle a and the distance between the circular gas nozzle H and the bottom of the ring-like resonator were selected based on the ratio:
S=n.Math.8.Math.t,
where S is the aggregate cross section of grooves upon the preset gas efficiency;
12.5˜f.Math.8˜15;
1.8˜a/8˜2.1;
7˜H/8˜8.

An air-assisted electrostatic ultrasonic atomization nozzle includes an intake sleeve, a Laval tube, a resonant body and a jet element body. The left end of the intake sleeve is equipped with the air intake, and the right end of the air inlet sleeve is connected with the left end of the Laval tube. The right end of the Laval tube is connected with the left end of the resonant body. The right end of the resonant body is connected with the left end of the jet element body. The sealing surface of the resonant tube is arranged between the resonant body and the jet element body. The sealing surface of the resonant tube obstructs the gas-liquid in the axial direction of the resonant body and the jet element body. The resonant body has a resonant chamber, and the sidewall of the resonant body is equipped with a V-shaped resonant tube.

An air-assisted electrostatic ultrasonic atomization nozzle includes an intake sleeve, a Laval tube, a resonant body and a jet element body. The left end of the intake sleeve is equipped with the air intake, and the right end of the air inlet sleeve is connected with the left end of the Laval tube. The right end of the Laval tube is connected with the left end of the resonant body. The right end of the resonant body is connected with the left end of the jet element body. The sealing surface of the resonant tube is arranged between the resonant body and the jet element body. The sealing surface of the resonant tube obstructs the gas-liquid in the axial direction of the resonant body and the jet element body. The resonant body has a resonant chamber, and the sidewall of the resonant body is equipped with a V-shaped resonant tube.

A step cavity low-frequency ultrasonic atomizing nozzle includes an air inlet casing tube, a water inlet casing tube, a de Laval valve, a fixed cap, a first adjustable base, a tapered rectification sleeve, a vortex flow impeller, a stepped resonance tube, an adjustment plunger, a positioning screw, and a second base. The adjustment plunger is located within a second step hole of the stepped resonance tube, and the axial position thereof is adjustable. The vortex flow impeller is fixed on the stepped resonance tube via a bearing, and an outer tapered surface thereof attaches to an inner tapered surface of the tapered rectification sleeve.

An ultrasonic injection device and methods of use are presented. The ultrasonic injection device comprises a housing, an injection nozzle attached to the housing, an ultrasonic vibration generator attached to the housing, and a pressure applicator. The injection nozzle has a number of openings configured to dispense a fluid. The ultrasonic vibration generator is configured to apply ultrasonic energy to fluid within the injection nozzle. The pressure application is configured to propel the fluid towards and out of the number of openings.

An ultrasonic injection device and methods of use are presented. The ultrasonic injection device comprises a housing, an injection nozzle attached to the housing, an ultrasonic vibration generator attached to the housing, and a pressure applicator. The injection nozzle has a number of openings configured to dispense a fluid. The ultrasonic vibration generator is configured to apply ultrasonic energy to fluid within the injection nozzle. The pressure application is configured to propel the fluid towards and out of the number of openings.