High-Prandtl-number thermocapillary liquid bridges with dynamically deformed interface: effect of an axial gas flow on the linear stability

Stojanović, Mario; Romanò, Francesco; Kuhlmann, Hendrik C.

doi:10.1017/jfm.2023.944

J. Fluid Mech.

2024

DOI: 10.1017/jfm.2023.944

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High-Prandtl-number thermocapillary liquid bridges with dynamically deformed interface: effect of an axial gas flow on the linear stability

Mario Stojanović,

Francesco Romanò,

Hendrik C. Kuhlmann

Abstract: The linear stability of the axisymmetric steady flow in a thermocapillary liquid bridge made from 2-cSt silicone oil $({Pr}=28)$ is investigated numerically. The liquid bridge is heated either from above or below and exposed to an axial air flow which is confined to a concentric tube surrounding the bridge. At the annular inlet, the air flow is fully developed and has the same temperature as the adjacent support rod. Using an extended Oberbeck–Boussinesq approximation in which the d… Show more

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2024

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References 68 publications

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Scaling and modeling of the heat transfer across the free surface of a thermocapillary liquid bridge

Romanò,

Stojanović,

Kuhlmann

2024

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Purpose This paper aims to derive a reduced-order model for the heat transfer across the interface between a millimetric thermocapillary liquid bridge from silicone oil and the surrounding ambient gas. Design/methodology/approach Numerical solutions for the two-fluid model are computed covering a wide parametric space, making a total of 2,800 numerical flow simulations. Based on the computed data, a reduced single-fluid model for the liquid phase is devised, in which the heat transfer between the liquid and the gas is modeled by Newton’s heat transfer law, albeit with a space-dependent Biot function Bi(z), instead of a constant Biot number Bi. Findings An explicit robust fit of Bi(z) is obtained covering the whole range of parameters considered. The single-fluid model together with the Biot function derived yields very accurate results at much lesser computational cost than the corresponding two-phase fully-coupled simulation required for the two-fluid model. Practical implications Using this novel Biot function approach instead of a constant Biot number, the critical Reynolds number can be predicted much more accurately within single-phase linear stability solvers. Originality/value The Biot function for thermocapillary liquid bridges is derived from the full multiphase problem by a robust multi-stage fit procedure. The derived Biot function reproduces very well the theoretical boundary layer scalings.

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Scaling and modeling of the heat transfer across the free surface of a thermocapillary liquid bridge

Romanò,

Stojanović,

Kuhlmann

2024

HFF

Self Cite

View full text Add to dashboard Cite

show abstract

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High-Prandtl-number thermocapillary liquid bridges with dynamically deformed interface: effect of an axial gas flow on the linear stability

Cited by 1 publication

References 68 publications

Scaling and modeling of the heat transfer across the free surface of a thermocapillary liquid bridge

Scaling and modeling of the heat transfer across the free surface of a thermocapillary liquid bridge

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