Effect of moderate DC electric field on formation of surfactant-laden drops

•The continuous formation of mm-scale surfactant-laden aqueous drops in oil was studied.•Critical electric field strength and drop sizes in the periodic dripping regime independent ofpolarity.•The effect of the electric field increased with a decrease of interfacial tension and density . The continu...

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Bibliographic Details
Published in:Chemical engineering research & design 2020-05, Vol.157, p.133-141
Main Authors: Kovalchuk, N., Alberini, F., Simmons, M.J.H.
Format: Article
Language:English
Subjects:
Direct current
Dispersion
Drop size
Electric field
Electric field strength
Electric fields
Emulsion
Flow velocity
Parameter estimation
Polarity
Size reduction
Studies
Surface tension
Surfactant
Surfactants
Viscosity
Viscosity ratio
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Summary:•The continuous formation of mm-scale surfactant-laden aqueous drops in oil was studied.•Critical electric field strength and drop sizes in the periodic dripping regime independent ofpolarity.•The effect of the electric field increased with a decrease of interfacial tension and density . The continuous formation of mm-scale surfactant-laden aqueous drops in oil was studied under an applied DC electric field of 0–267 kV/m. The parameters varied included the flow rate of dispersed phase, the electric field strength, the viscosities and densities of dispersed and continuous phase and the surfactant type (anionic or cationic) and concentration. An increase in the electric field strength resulted in a decrease of the drop size due to increasing stresses on the drop interface. The size reduction continued until transition to the irregular regime. The values of critical electric field strength for this transition increased with an increase in both the flow rate and the viscosity ratio between the dispersed and continuous phase. The critical electric field strength and the size of the drops formed in the periodic dripping regime were independent of the electric field polarity. The effect of the electric field increased with a decrease of interfacial tension and density difference between the dispersed and continuous phase.
ISSN:0263-8762
1744-3563
DOI:10.1016/j.cherd.2020.03.009