Electrocoalescence of water drop trains in oil under constant and pulsatile electric fields

V. Vivacqua, S. Mhatre, M. Ghadiri, A. M. Abdullah, A. Hassanpour, Jaber Al Marri, B. Azzopardi, B. Hewakandamby, B. Kermani

Research output: Contribution to journalArticle

23 Citations (Scopus)

Abstract

This study addresses the effectiveness of constant and pulsed DC fields in promoting coalescence of dispersed water drops in an oil-continuous phase. For this purpose, a train of drops of relatively uniform size is injected into a stream of flowing sunflower oil. This stream is then admitted to a coalescing section, where an electric field is applied between a pair of ladder-shape bare electrodes. The capability of this device to enhance coalescence of droplets in a chain is investigated at different field intensities, frequencies and waveforms. The effect of the initial inter-droplet separation distance on the process performance is also addressed under constant DC fields. The dominant coalescence mechanism is found to be due to dipole-dipole interaction at low field strength, whereas electrophoresis becomes predominant at higher field strength. Experiments reveal the existence of an optimal frequency, where the average droplet size enlargement is maximized, especially at low field strengths. The droplet size at the outlet of the coalescer is also found to be dependent on the field waveform.

Original languageEnglish
Pages (from-to)658-668
Number of pages11
JournalChemical Engineering Research and Design
Volume104
DOIs
Publication statusPublished - 1 Jan 2015
Externally publishedYes

Fingerprint

Oils
Electric fields
Coalescence
Water
Sunflower oil
Ladders
Electrophoresis
Electrodes
Experiments

Keywords

  • Electrocoalescence
  • Electrostatic de-emulsification
  • Oil treatment
  • Phase separation

ASJC Scopus subject areas

  • Chemistry(all)
  • Chemical Engineering(all)

Cite this

Electrocoalescence of water drop trains in oil under constant and pulsatile electric fields. / Vivacqua, V.; Mhatre, S.; Ghadiri, M.; Abdullah, A. M.; Hassanpour, A.; Al Marri, Jaber; Azzopardi, B.; Hewakandamby, B.; Kermani, B.

In: Chemical Engineering Research and Design, Vol. 104, 01.01.2015, p. 658-668.

Research output: Contribution to journalArticle

Vivacqua, V, Mhatre, S, Ghadiri, M, Abdullah, AM, Hassanpour, A, Al Marri, J, Azzopardi, B, Hewakandamby, B & Kermani, B 2015, 'Electrocoalescence of water drop trains in oil under constant and pulsatile electric fields', Chemical Engineering Research and Design, vol. 104, pp. 658-668. https://doi.org/10.1016/j.cherd.2015.10.006
Vivacqua, V. ; Mhatre, S. ; Ghadiri, M. ; Abdullah, A. M. ; Hassanpour, A. ; Al Marri, Jaber ; Azzopardi, B. ; Hewakandamby, B. ; Kermani, B. / Electrocoalescence of water drop trains in oil under constant and pulsatile electric fields. In: Chemical Engineering Research and Design. 2015 ; Vol. 104. pp. 658-668.
@article{f799e5a223284fc993c53baca55df1e9,
title = "Electrocoalescence of water drop trains in oil under constant and pulsatile electric fields",
abstract = "This study addresses the effectiveness of constant and pulsed DC fields in promoting coalescence of dispersed water drops in an oil-continuous phase. For this purpose, a train of drops of relatively uniform size is injected into a stream of flowing sunflower oil. This stream is then admitted to a coalescing section, where an electric field is applied between a pair of ladder-shape bare electrodes. The capability of this device to enhance coalescence of droplets in a chain is investigated at different field intensities, frequencies and waveforms. The effect of the initial inter-droplet separation distance on the process performance is also addressed under constant DC fields. The dominant coalescence mechanism is found to be due to dipole-dipole interaction at low field strength, whereas electrophoresis becomes predominant at higher field strength. Experiments reveal the existence of an optimal frequency, where the average droplet size enlargement is maximized, especially at low field strengths. The droplet size at the outlet of the coalescer is also found to be dependent on the field waveform.",
keywords = "Electrocoalescence, Electrostatic de-emulsification, Oil treatment, Phase separation",
author = "V. Vivacqua and S. Mhatre and M. Ghadiri and Abdullah, {A. M.} and A. Hassanpour and {Al Marri}, Jaber and B. Azzopardi and B. Hewakandamby and B. Kermani",
year = "2015",
month = "1",
day = "1",
doi = "10.1016/j.cherd.2015.10.006",
language = "English",
volume = "104",
pages = "658--668",
journal = "Chemical Engineering Research and Design",
issn = "0263-8762",
publisher = "Institution of Chemical Engineers",

}

TY - JOUR

T1 - Electrocoalescence of water drop trains in oil under constant and pulsatile electric fields

AU - Vivacqua, V.

AU - Mhatre, S.

AU - Ghadiri, M.

AU - Abdullah, A. M.

AU - Hassanpour, A.

AU - Al Marri, Jaber

AU - Azzopardi, B.

AU - Hewakandamby, B.

AU - Kermani, B.

PY - 2015/1/1

Y1 - 2015/1/1

N2 - This study addresses the effectiveness of constant and pulsed DC fields in promoting coalescence of dispersed water drops in an oil-continuous phase. For this purpose, a train of drops of relatively uniform size is injected into a stream of flowing sunflower oil. This stream is then admitted to a coalescing section, where an electric field is applied between a pair of ladder-shape bare electrodes. The capability of this device to enhance coalescence of droplets in a chain is investigated at different field intensities, frequencies and waveforms. The effect of the initial inter-droplet separation distance on the process performance is also addressed under constant DC fields. The dominant coalescence mechanism is found to be due to dipole-dipole interaction at low field strength, whereas electrophoresis becomes predominant at higher field strength. Experiments reveal the existence of an optimal frequency, where the average droplet size enlargement is maximized, especially at low field strengths. The droplet size at the outlet of the coalescer is also found to be dependent on the field waveform.

AB - This study addresses the effectiveness of constant and pulsed DC fields in promoting coalescence of dispersed water drops in an oil-continuous phase. For this purpose, a train of drops of relatively uniform size is injected into a stream of flowing sunflower oil. This stream is then admitted to a coalescing section, where an electric field is applied between a pair of ladder-shape bare electrodes. The capability of this device to enhance coalescence of droplets in a chain is investigated at different field intensities, frequencies and waveforms. The effect of the initial inter-droplet separation distance on the process performance is also addressed under constant DC fields. The dominant coalescence mechanism is found to be due to dipole-dipole interaction at low field strength, whereas electrophoresis becomes predominant at higher field strength. Experiments reveal the existence of an optimal frequency, where the average droplet size enlargement is maximized, especially at low field strengths. The droplet size at the outlet of the coalescer is also found to be dependent on the field waveform.

KW - Electrocoalescence

KW - Electrostatic de-emulsification

KW - Oil treatment

KW - Phase separation

UR - http://www.scopus.com/inward/record.url?scp=84955252844&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=84955252844&partnerID=8YFLogxK

U2 - 10.1016/j.cherd.2015.10.006

DO - 10.1016/j.cherd.2015.10.006

M3 - Article

VL - 104

SP - 658

EP - 668

JO - Chemical Engineering Research and Design

JF - Chemical Engineering Research and Design

SN - 0263-8762

ER -