Title :
Micrometer-sized droplet ejection from a millimeter-sized spherical water drop using a megahertz multiple-fourier horn ultrasonic nozzle
Author :
Tsai, C.S. ; Lin, S.K. ; Mao, R.W. ; Tsai, Shih Chang
Author_Institution :
Dept. of Electr. Eng. & Comp. Sci., Univ. of California, Irvine, Irvine, CA, USA
Abstract :
A new phenomenon on droplet ejection, namely, one large spherical water drop ejecting simultaneously a very large number of monodisperse micro droplets was observed and studied in detail. An ultrasonic nozzle with multiple-Fourier horns in resonance enables controlled excitation of megahertz Faraday waves on the spherical water surface which leads to the ejection of 3.5-4.4μm monodisperse droplets at a high rate (>107 droplets per second). This is in stark contrast to the RayleighPlateau instability, which ejects one droplet at a time.
Keywords :
confined flow; drops; flow instability; millimetre wave devices; nozzles; two-phase flow; ultrasonic devices; water; waves; H2O; Rayleigh-Plateau instability; megahertz Faraday wave; megahertz multiple Fourier horn ultrasonic nozzle; micrometer sized droplet ejection; millimeter sized spherical water drop; monodisperse microdroplet; size 3.5 mum to 4.4 mum; spherical water surface; Acoustics; Face; Geometry; Liquids; Oscillators; Surface waves; Droplet ejection; Faraday waves; Fourier-horn ultrasonic nozzles; Spherical liquid surface; pulmonary drug delivery;
Conference_Titel :
Ultrasonics Symposium (IUS), 2012 IEEE International
Conference_Location :
Dresden
Print_ISBN :
978-1-4673-4561-3
DOI :
10.1109/ULTSYM.2012.0505
