par Sobac, Benjamin 
;Rednikov, Alexei ;Maquet, Laurent;Darbois-Texier, Baptiste;Brandenbourger, Martin ;Duchesne, Alexis;Dorbolo, Stéphane;Colinet, Pierre
Référence (Boston, USA), American Physical Society, 68th Annual Meeting Division of Fluid Dynamics
Publication Publié, 2015
;Rednikov, Alexei ;Maquet, Laurent;Darbois-Texier, Baptiste;Brandenbourger, Martin ;Duchesne, Alexis;Dorbolo, Stéphane;Colinet, Pierre Référence (Boston, USA), American Physical Society, 68th Annual Meeting Division of Fluid Dynamics
Publication Publié, 2015
Abstract de conférence
| Résumé : | It is well known that a liquid drop released over a very hot surface generally does not contact the surface nor boils but rather levitates over a thin vapor film generated by its own evaporation (Leidenfrost effect). In particular, the case of a hot (and flat) solid substrate has been extensively studied in recent years. In contrast, we here focus on Leidenfrost drops over a superheated liquid bath, addressing the problem theoretically and comparing our predictions with experimental results, detailed in a separate talk. We predict the geometry of the drop and of the liquid bath, based on the hydrostatic Young-Laplace and lubrication equations. A good agreement is observed with the available experimental data concerning the deformation of the liquid bath. The modeling also yields a rather complete insight into the shape of the drop. As in the case of a solid substrate, the vapor layer generally appears to be composed of a vapor pocket surrounded by a circular neck. The influences of the superheat and of the drop size are parametrically investigated. A number of scaling laws are established. Unlike the case of a solid substrate, no chimney instability was found in the range of drop size studied. |
