Thermo-electric convection in a cylindrical annulus during a sounding rocket flight

Meyer, Antoine; Meier, Martin; Motuz, Vasyl; Egbers, Christoph

doi:10.1017/jfm.2023.677

J. Fluid Mech.

2023

DOI: 10.1017/jfm.2023.677

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Thermo-electric convection in a cylindrical annulus during a sounding rocket flight

Antoine Meyer,

Martin Meier,

Vasyl Motuz

et al.

Abstract: An experiment on convective flows induced by the dielectrophoretic force was performed under the microgravity condition provided during a sounding rocket flight. The dielectrophoretic force possesses a non-conservative term that can be seen as resulting from an electric gravity. That gravity can be responsible for an electric Rayleigh–Bénard convection between a hot inner cylinder and a cold outer cylinder when an electric field is applied in the radial direction. Four cells with independent temperature and el… Show more

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2024

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Thermoelectrohydrodynamic convection in a finite cylindrical annulus under microgravity

Kang,

Mutabazi,

Yoshikawa

2024

J. Fluid Mech.

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Numerical simulations of thermoelectrohydrodynamic convection in a dielectric liquid inside a finite-length cylindrical annulus with a fixed temperature difference have been performed with increasing high-frequency electric tension under microgravity conditions. The electric field, coupled with the permittivity gradient, generates a dielectrophoretic buoyancy force whose non-conservative part can induce thermoelectric convection in the liquid. The liquid remains in a conductive state below a critical value of the applied electric voltage. At a critical value, a supercritical bifurcation occurs from the conductive state to a convective state made of stationary helicoidal vortices. A further increase of electric voltage leads to oscillatory helicoidal vortices and then to wavy patterns before spoke patterns dominate the convective flow. The dielectrophoretic force is shown to enhance the heat transfer from the hot to cold walls due to induced convective flows. Particularly, these results demonstrate that the dielectrophoretic buoyancy force holds promise to replace the gravitational force to induce efficient heat transfer in microgravity conditions, and they contribute to a better fundamental understanding of heat transfer in microgravity.

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Thermoelectrohydrodynamic convection in a finite cylindrical annulus under microgravity

Kang,

Mutabazi,

Yoshikawa

2024

J. Fluid Mech.

View full text Add to dashboard Cite

show abstract

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Thermo-electric convection in a cylindrical annulus during a sounding rocket flight

Cited by 1 publication

References 47 publications

Thermoelectrohydrodynamic convection in a finite cylindrical annulus under microgravity

Thermoelectrohydrodynamic convection in a finite cylindrical annulus under microgravity

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