Non‐coalescence behavior of neutral droplets suspended in oil under a direct current electric field

Huang, Xin; He, Limin; Luo, Xiaoming; Yin, Haoran; Yang, Donghai

doi:10.1002/aic.16739

Cited by 10 publications

(17 citation statements)

References 35 publications

(44 reference statements)

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“…The field of view in Figure 9h is darker than that in Figure 9g, which is caused by lowering the light intensity of LED light. The critical electric field strength for complete coalescence gradually reduces as the droplet radius increases 30 . As time goes by, the droplet radius gradually increases due to the droplet coalescence.…”

Section: Resultsmentioning

confidence: 99%

Non‐coalescence and chain formation of droplets under an alternating current electric field

Huang

Luo

et al. 2021

AIChE Journal

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The dynamic behaviors of two droplets and droplet cluster under an alternating current (AC) electric field are investigated. Two droplets generally undergo transformation from complete coalescence to partial coalescence and finally to non‐coalescence as the electric capillary number Cap increases. The critical electric capillary number Capc for complete coalescence in the AC electric field remains unchanged and is twice as large as that in the direct current (DC) electric field when the frequency f ≥ 250 Hz. Charge transfer and reversal of electric field result in the reversal of the direction of electric force, which is the fundamental mechanism of non‐coalescence of two droplets and chain formation in droplet cluster. The number of rebounds dramatically increases as f increases, promoting the stability of droplet chain. The droplet chains in the high‐frequency AC electric field are longer and more stable than those in the low‐frequency AC electric field.

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Section: Resultsmentioning

confidence: 99%

Non‐coalescence and chain formation of droplets under an alternating current electric field

Huang

Luo

et al. 2021

AIChE Journal

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“…Moreover, according to the dipole-induced-dipole theory, 11 the enhancement of electric field strength can increase the electrostatic force, which is conducive to the improvement of demulsification efficiency. However, Huang et al 12 discovered that when E reaches a particular value, the droplets could not coalesce after contact. Obviously, this behavior evolution of droplets after contact does not work for demulsification.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, it is necessary to reveal the mechanisms of droplet behavior evolution for the optimization of the electric demulsification process, and many researchers have conducted experimental and theoretical studies. 16−18 Huang et al 12 studied the effects of initial separation distance between droplets, droplet radius, and surfactant concentration on the critical coalescence electric field strength E c . It was shown that E c first declines and then maintains as the initial separation distance increases.…”

Section: Introductionmentioning

confidence: 99%

Behavior Evolution of Droplets Suspended in Castor Oil under Alternating Current Electric Field

Jin

et al. 2022

Langmuir

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Electric fields, which can promote the approach of droplets and break the liquid film, are extensively used in the separation of the water phase in water-in-oil emulsions. However, there is an evolution of droplet behavior under an electric field. After the two droplets meet with each other, the electric force becomes undesirable, which would even cause breakup of the merged droplet. When the electric field strength E reaches a particular value, the final behavior of droplets is made, which goes against coalescence, and there are lots of behavior evolution types. Several research studies have studied on whether droplets coalesce and the critical condition, but few works have focused on the classification and mechanism of non-coalescence behaviors. In this paper, the behavior evolution of two single droplets suspended in castor oil under an alternating current electric field is studied by a high−speed camera. Six distinct behavior evolution modes are observed and summarized: coalescence, bounce, partial coalescence, partial rupture, coalescence−rupture, and rupture. The behavior evolution mode is influenced by the initial separation distance s 0 between droplets and the electric field strength. Moreover, there exist critical electric field strengths among different behavior evolution modes. As E gradually increases, two water droplets go through coalescence, partial coalescence, and coalescence−rupture in sequence when s 0 is small and coalescence, bounce, partial rupture, and rupture when s 0 is large. The mechanisms of behavior evolution are revealed by investigating the confrontation between electric force and capillary force in the condition with liquid bridge or pressure difference from the surrounding fluid and electric force in the condition without a liquid bridge. In addition, a cone−dimple mode of water droplets in castor oil is found, demonstrating the rationality of electric force theory.

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“…6,7 Especially for petrochemical industry, the high voltage electric field is widely used to demulsify the water-in-oil emulsion in the oil field and refinery. [8][9][10][11] Nevertheless, with the extensive application of polymer flooding technology, the emulsion contains a large number of polymer molecules, easily leading to a significant rise in the electric current and the collapse of electric field. 12,13 This will stop the electric dehydrator from working and deteriorate the oil-water separation efficiency, seriously restricting the development and application of electrostatic demulsification technology.…”

Section: Introductionmentioning

confidence: 99%

“…Examples of these include the droplet deformation and breakup in the thunderstorm, 1 electrostatic atomization, 2,3 electrospinning, 4 electrohydrodynamic inkjet printing, 5 and droplet manipulation in microfluidic and MEMS devices 6,7 . Especially for petrochemical industry, the high voltage electric field is widely used to demulsify the water‐in‐oil emulsion in the oil field and refinery 8–11 . Nevertheless, with the extensive application of polymer flooding technology, the emulsion contains a large number of polymer molecules, easily leading to a significant rise in the electric current and the collapse of electric field 12,13 .…”

Section: Introductionmentioning

confidence: 99%

Deformation and breakup of water droplets containing polymer under a DC electric field

et al. 2022

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The deformation and breakup behaviors of droplets containing polymer are investigated by high‐speed photography to reveal the mechanism of electric field collapse when treating the emulsion containing polymer. The results show the electric field collapse process caused by droplet breakup consists of three steps. First, the droplet containing polymer ejects liquid filament under strong electric field. Second, the liquid filament is continuously stretched until it touches positive and negative electrodes. Finally, the severe Joule heating effect appears because the strong electric current flows through the liquid filament. The release of a large amount of heat causes the formation, expansion, and collapse of bubble, resulting in the fracture of liquid filament and the collapse of electric field. The increase of polymer concentration strengthens the Joule heating effect and enlarges the influence scope of bubble expansion and collapse. These findings provide significant guidance for the stable operation of electric dehydrator.

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Non‐coalescence behavior of neutral droplets suspended in oil under a direct current electric field

Cited by 10 publications

References 35 publications

Non‐coalescence and chain formation of droplets under an alternating current electric field

Non‐coalescence and chain formation of droplets under an alternating current electric field

Behavior Evolution of Droplets Suspended in Castor Oil under Alternating Current Electric Field

Deformation and breakup of water droplets containing polymer under a DC electric field

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