Numerical simulation of deformation/motion of a drop suspended in viscous liquids under influence of steady electric fields

Hua, Jinsong; Lim, Liang; Wang, Chi-Hwa

doi:10.1063/1.3021065

Cited by 141 publications

(80 citation statements)

References 26 publications

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“…However, this method is not used to model coalescence or pinch-off, since one weakness of VOF is that it can not distinguish topological changes precisely. The current literature also includes a fronttracking finite volume method that can model electric charge on the droplet surface [18]. In addition, mesoscopic methods such as Lattice Boltzmann methods have been used for simulating drop deformation using electric fields [41,14].…”

Section: Overview Of Numerical Approachesmentioning

confidence: 99%

An interface tracking model for droplet electrocoalescence.

Erickson¹

2013

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This report describes an Early Career Laboratory Directed Research and Development (LDRD) project to develop an interface tracking model for droplet electrocoalescence. Many fluid-based technologies rely on electrical fields to control the motion of droplets, e.g. microfluidic devices for high-speed droplet sorting, solution separation for chemical detectors, and purification of biodiesel fuel. Precise control over droplets is crucial to these applications. However, electric fields can induce complex and unpredictable fluid dynamics. Recent experiments ) have demonstrated that oppositely charged droplets bounce rather than coalesce in the presence of strong electric fields. A transient aqueous bridge forms between approaching drops prior to pinch-off. This observation applies to many types of fluids, but neither theory nor experiments have been able to offer a satisfactory explanation. Analytic hydrodynamic approximations for interfaces become invalid near coalescence, and therefore detailed numerical simulations are necessary. This is a computationally challenging problem that involves tracking a moving interface and solving complex multi-physics and multi-scale dynamics, which are beyond the capabilities of most state-of-the-art simulations. An interface-tracking model for electro-coalescence can provide a new perspective to a variety of applications in which interfacial physics are coupled with electrodynamics, including electro-osmosis, fabrication of microelectronics, fuel atomization, oil dehydration, nuclear waste reprocessing and solution separation for chemical detectors. We present a conformal decomposition finite element (CDFEM) interface-tracking method for the electrohydrodynamics of two-phase flow to demonstrate electro-coalescence. CDFEM is a sharp interface method that decomposes elements along fluid-fluid boundaries and uses a level set function to represent the interface.3

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Section: Overview Of Numerical Approachesmentioning

confidence: 99%

An interface tracking model for droplet electrocoalescence.

Erickson¹

2013

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“…The results indicated that the interpolation scheme to smoothen the electric properties (conductivity and permittivity) in the interface transition region had a significant influence on the solution in the bulk [17]. Hua et al summarized three different kinds of electric fields: leaky dielectric model, perfect dielectric model, and constant charge model and numerically investigated the deformation of droplet and internal flow inside droplet by employing the interface tracking method where the interface was considered to have a finite thickness of the same order as the mesh size instead of zero thickness [18]. Lin et al proposed the phase field method to study the two-phase electrohydrodynamic flow which was generated by electric field.…”

Section: Introductionmentioning

confidence: 99%

“…But this method is inaccurate for the calculation of surface tension. Some methods which treated the interface as a finite width region where the physical properties continuously transitioned from one phase to another phase were presented in recent years [16][17][18][19]. Zhang and Kwok investigated the droplet deformation driven by electrohydrodynamics using a multicomponent LBM method that a cosine function was employed to describe such transition interface.…”

Section: Introductionmentioning

confidence: 99%

Numerical Study on Deformation and Interior Flow of a Droplet Suspended in Viscous Liquid under Steady Electric Fields

Wang

Dong

Zhang

et al. 2014

Advances in Mechanical Engineering

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A model based on the volume of fluid (VOF) method and leaky dielectric theory is established to predict the deformation and internal flow of the droplet suspended in another vicious fluid under the influence of the electric field. Through coupling with hydrodynamics and electrostatics, the rate of deformation and internal flow of the single droplet are simulated and obtained under the different operating parameters. The calculated results show that the direction of deformation and internal flow depends on the physical properties of fluids. The numerical results are compared with Taylor's theory and experimental results by Torza et al. When the rate of deformation is small, the numerical results are consistent with theory and experimental results, and when the rate is large the numerical results are consistent with experimental results but are different from Taylor's theory. In addition, fluid viscosity hardly affects the deformation rate and mainly dominates the deformation velocity. For high viscosity droplet spends more time to attain the steady state. The conductivity ratio and permittivity ratio of two different liquids affect the direction of deformation. When fluid electric properties change, the charge distribution at the interface is various, which leads to the droplet different deformation shapes.

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“…Explicit approaches, such as boundary integral and front-tracking methods, track discrete points on the interface surface. The motion and deformation of droplets under the presence of an electric field [8][9][10][11][12] [14][15][16][17][18][19][20]. Each implicit technique to represent the interface has its own advantages and drawbacks.…”

Section: Introductionmentioning

confidence: 99%

Analysis of partial electrocoalescence by Level-Set and finite element methods

Vivacqua

Ghadiri

Abdullah

et al. 2016

Chemical Engineering Research and Design

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The coalescence of a water drop in a dieletric oil phase at a water layer interface in the presence of an electric field is simulated by solving the Navier-Stokes and charge conservation equations with the finite element method. The proprietary software Comsol Multiphysics is used for this purpose.The interface between the oil and water phases is tracked by implementing a Level Set approach. The sensitivity of the model with respect to some input parameters are reported. In particular, the calculations are sensitive to the size of the computational grid elements, interface thickness and reinitialisation parameter. The ratio between the volume of secondary droplets and the initial drop volume is calculated as a function of the initial drop size and compared with experiments available in the literature. A good quantitative agreement can be obtained if the parameters are suitably tuned.The model also predicts a strong role played by the water phase conductivity in the formation of progeny droplets.

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Numerical simulation of deformation/motion of a drop suspended in viscous liquids under influence of steady electric fields

Cited by 141 publications

References 26 publications

An interface tracking model for droplet electrocoalescence.

An interface tracking model for droplet electrocoalescence.

Numerical Study on Deformation and Interior Flow of a Droplet Suspended in Viscous Liquid under Steady Electric Fields

Analysis of partial electrocoalescence by Level-Set and finite element methods

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