Effects of charge relaxation on the electrohydrodynamic breakup of leaky-dielectric jets

The breakup process of a charged, leaky-dielectric jet subjected to an axial perturbation is computationally analysed from the perspectives of linear and nonlinear dynamics using the arbitrary Lagrangian–Eulerian technique. The linear dynamics of the leaky-dielectric jet is quantitatively predicted...

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Bibliographic Details
Published in:Journal of fluid mechanics 2021-10, Vol.925, Article A4
Main Authors: Nie, Qichun, Li, Fang, Ma, Qianli, Fang, Haisheng, Yin, Zhouping
Format: Article
Language:English
Subjects:
Breakup
Compression
Computational fluid dynamics
Conduction
Convection
Dynamic stability
Dynamics
Electric fields
Electrodes
Electrohydrodynamics
Fluid flow
JFM Papers
Ligaments
Nonlinear dynamics
Nonlinear systems
Perturbation
Shear stress
Simulation
Stability analysis
Surface charge
Viscosity
Wavelengths
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Summary:The breakup process of a charged, leaky-dielectric jet subjected to an axial perturbation is computationally analysed from the perspectives of linear and nonlinear dynamics using the arbitrary Lagrangian–Eulerian technique. The linear dynamics of the leaky-dielectric jet is quantitatively predicted by the dispersion relation from the linear stability analysis. Regarding the nonlinear dynamics, it is found that the charge relaxation is responsible for the radial compression of satellite droplets, which is validated by experiments. Two types of charge relaxations, namely, ohmic conduction and surface charge convection, define the pinching process into three breakup modes, i.e. ligament pinching, end pinching and transition pinching. In the ligament-pinching mode, the ohmic conduction dominates the jet breakup since the charge relaxes to the jet ligament instantaneously. In contrast, the surface charge convection takes effect in the end-pinching mode since the surface charge is convected to the jet end via fluid flow. When the ohmic conduction is comparable to the surface charge convection, the breakup occurs simultaneously at the end and the ligament. Finally, the influences of the perturbed wavenumber, the electric field intensity and the viscosity on the breakup mode and the local dynamics at pinch-off are comprehensively discussed.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2021.639