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Détail de l'auteur
Auteur V. Shankar
Documents disponibles écrits par cet auteur
Affiner la rechercheElastohydrodynamic suppression of free-surface instabilities in annular liquid film flow outside wires and inside tubes / Aashish Jain in Industrial & engineering chemistry research, Vol. 47 N°17 (Septembre 2008)
[article]
in Industrial & engineering chemistry research > Vol. 47 N°17 (Septembre 2008) . - p. 6473–6485
Titre : Elastohydrodynamic suppression of free-surface instabilities in annular liquid film flow outside wires and inside tubes Type de document : texte imprimé Auteurs : Aashish Jain, Auteur ; V. Shankar, Auteur Année de publication : 2008 Article en page(s) : p. 6473–6485 Note générale : Chemical engineering Langues : Anglais (eng) Mots-clés : Free-surface instability Low-wavenumber perturbation analysis Numerical method Résumé : The linear stability of gravity-driven annular liquid film flow outside wires and inside tubes is analyzed when the rigid surface is replaced by a deformable (neo-Hookean) solid wall. On a rigid surface, an annular liquid thread becomes unstable due to a Rayleigh-type capillary instability even in the absence of flow. In the presence of flow, the annular liquid film becomes unstable due to a flow-driven, free-surface instability, which occurs over and above the curvature-induced capillary instability. In this paper, a low-wavenumber perturbation analysis is first used to elucidate the effect of wall deformability on the free-surface instability. It is shown that the free-surface instability is completely stabilized in the low-wavenumber limit when the wall is made sufficiently deformable. A numerical method is subsequently used to determine the stability of the system at arbitrary wavenumbers. Results from the numerical solution reveal that the prediction of instability suppression at low wavenumbers extends to finite wavenumbers as well. However, as the solid wall is made deformable even further, the free surface is destabilized at finite wavenumbers by the deformability; in addition, the liquid−solid interface could also become unstable when the solid deformability becomes high. It is demonstrated, however, that there is a sufficient range of shear modulus of the solid where the annular flow is stable at all wavenumbers. The results of this study have implications in wire-coating operations, as well as in biological settings such as closure of lung airways. En ligne : http://pubs.acs.org/doi/abs/10.1021/ie701771m [article] Elastohydrodynamic suppression of free-surface instabilities in annular liquid film flow outside wires and inside tubes [texte imprimé] / Aashish Jain, Auteur ; V. Shankar, Auteur . - 2008 . - p. 6473–6485.
Chemical engineering
Langues : Anglais (eng)
in Industrial & engineering chemistry research > Vol. 47 N°17 (Septembre 2008) . - p. 6473–6485
Mots-clés : Free-surface instability Low-wavenumber perturbation analysis Numerical method Résumé : The linear stability of gravity-driven annular liquid film flow outside wires and inside tubes is analyzed when the rigid surface is replaced by a deformable (neo-Hookean) solid wall. On a rigid surface, an annular liquid thread becomes unstable due to a Rayleigh-type capillary instability even in the absence of flow. In the presence of flow, the annular liquid film becomes unstable due to a flow-driven, free-surface instability, which occurs over and above the curvature-induced capillary instability. In this paper, a low-wavenumber perturbation analysis is first used to elucidate the effect of wall deformability on the free-surface instability. It is shown that the free-surface instability is completely stabilized in the low-wavenumber limit when the wall is made sufficiently deformable. A numerical method is subsequently used to determine the stability of the system at arbitrary wavenumbers. Results from the numerical solution reveal that the prediction of instability suppression at low wavenumbers extends to finite wavenumbers as well. However, as the solid wall is made deformable even further, the free surface is destabilized at finite wavenumbers by the deformability; in addition, the liquid−solid interface could also become unstable when the solid deformability becomes high. It is demonstrated, however, that there is a sufficient range of shear modulus of the solid where the annular flow is stable at all wavenumbers. The results of this study have implications in wire-coating operations, as well as in biological settings such as closure of lung airways. En ligne : http://pubs.acs.org/doi/abs/10.1021/ie701771m