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Journal of Dispersion Science and Technology Volume 39, 2018 - Issue 1
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Original Articles

Numerical simulation of deformation behavior of droplet in gas under the electric field and flow field coupling

Wenpeng HongDepartment of Power Engineering and Engineering Thermophysics, College of Energy and Power Engineering, Northeast Dianli University, Jilin, China
,
Xiangyun YeDepartment of Power Engineering and Engineering Thermophysics, College of Energy and Power Engineering, Northeast Dianli University, Jilin, ChinaCorrespondence[email protected]
ORCID Iconhttp://orcid.org/0000-0001-5849-956X
ORCID Icon &
Rong XueDepartment of Power Engineering and Engineering Thermophysics, College of Energy and Power Engineering, Northeast Dianli University, Jilin, China
Pages 26-32 | Received 29 Dec 2016, Accepted 04 Feb 2017, Published online: 05 Apr 2017
 
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ABSTRACT

The water droplets in the process of electrostatic coalescence are important when studying electrohydrodynamics. In the present study, the electric field and flow field are coupled through the phase field method based on the Cahn–Hilliard formulation. A numerical simulation model of single droplet deformation under the coupling field was established. It simulated the deformation behavior of the movement of a droplet in the continuous phase and took the impact of droplet deformation into consideration which is affected by two-phase flow velocity, electric field strength, the droplet diameter, and the interfacial tension. The results indicated that under the single action of the flow field, when the flow velocity was lower, the droplet diameter was greater as was the droplet deformation degree. When the flow velocity was increased, the droplet deformation degree of a small-diameter droplet was at its maximum size, the large-diameter droplet had a smaller deformation degree, and the middle-diameter droplet was at a minimum deformation degree. When the flow velocity was further increased, the droplet diameter was smaller, and the droplet deformation degree was greater. Under the coupled effect of the electric field and flow field, the two-phase flow velocity and the electric field strength were greater, and the degree of droplet deformation was greater. While the droplet diameter and interfacial tension were smaller, the degree of droplet deformation was greater. Droplet deformation degree increased along with the two-phase flow velocity. The research results provided a theoretical basis for gas–liquid separation with electrostatic coalescence technology.

GRAPHICAL ABSTRACT

Acknowledgments

We thank Carla Roberts for providing language help, and Johan Sjoblom for critically reading the manuscript and helpful discussions.

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