Title :
Dielectric liquid-in-liquid dispersion by applying pulsed voltage
Author :
Sato, Masayuki ; Morita, Norihisa ; Kuroiwa, Ikuyo ; Ohshima, Takayuki ; Urashima, Kuniko
Author_Institution :
Dept. of Chem. & Environ. Eng., Gunma Univ. Kiryu, Kiryu, Japan
fDate :
4/1/2009 12:00:00 AM
Abstract :
Liquid-in-liquid dispersion, such as organic liquid in water or water in organic liquid, has been performed using dc or ac voltage applied between nozzle and ground electrode. In the present study, pulsed high voltage was applied to produce droplets with controlled diameter in wide range. The high voltage pulse source was capacitor discharge type with 20 - 50 Hz and ranged from 0 to several kV. Water glass was atomized in alcohol solution into diameters ranging from several mum to sub-mm, depending on applied voltage. The atomized water glass droplets were solidified by removing water molecules from the water glass. Synchronized droplet formation with pulse frequency was possible by controlling pulse voltage, width and frequency, which produced uniform sized droplets successively. When the pulse voltage was raised, the droplet formation mode changed from the synchronized formation to dispersion mode through transient mode. In the dispersion mode, droplets of several mum diameter having high uniformity were produced. Utilization of high voltage and high-speed pulse to liquid-liquid dispersion could make it possible to atomize in a conductive liquid without electrolysis.
Keywords :
dielectric liquids; disperse systems; drops; alcohol solution; capacitor discharge type; dielectric liquid-in-liquid dispersion; frequency 20 Hz to 50 Hz; ground electrode; high voltage pulse source; nozzle; organic liquid; water glass droplets; Capacitors; Dielectric liquids; Electrochemical processes; Electrodes; Fault location; Frequency synchronization; Glass; Size control; Space vector pulse width modulation; Voltage control; Pulse voltage application, liquid-liquid atomization, uniform sized particle, silica particle production, synchronized droplet formation, dielectric liquids;
Journal_Title :
Dielectrics and Electrical Insulation, IEEE Transactions on
DOI :
10.1109/TDEI.2009.4815169
