Perturbation theory for metal pad roll instability in cylindrical reduction cells

Perturbation theory for metal pad roll instability in cylindrical reduction cells

We propose a new theoretical model for metal pad roll instability in idealized cylindrical reduction cells. In addition to the usual destabilizing effects, we model viscous and Joule dissipation and some capillary effects. The resulting explicit formulas are used as theoretical benchmarks for two mu...

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Veröffentlicht in:Journal of fluid mechanics 2019-11, Vol.878, p.598-646
Hauptverfasser: Herreman, W., Nore, C., Guermond, J.-L., Cappanera, L., Weber, N., Horstmann, G. M.
Format: Artikel
Sprache:eng
Schlagworte:
Batteries
Benchmarks
Cells
Computational fluid dynamics
Control stability
Cylinders
Damping
Engineering Sciences
Fluid flow
Gravitational waves
Gravity waves
Instability
Interfaces
Liquid metals
Magnetohydrodynamics
Metals
Nonlinear Sciences
Perturbation theory
Physics
Product design
Reduction
Solvers
Viscous damping
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Zusammenfassung:We propose a new theoretical model for metal pad roll instability in idealized cylindrical reduction cells. In addition to the usual destabilizing effects, we model viscous and Joule dissipation and some capillary effects. The resulting explicit formulas are used as theoretical benchmarks for two multiphase magnetohydrodynamic solvers, OpenFOAM and SFEMaNS. Our explicit formula for the viscous damping rate of gravity waves in cylinders with two fluid layers compares excellently to experimental measurements. We use our model to locate the viscously controlled instability threshold in cylindrical shallow reduction cells but also in Mg–Sb liquid metal batteries with decoupled interfaces.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2019.642