Simulation numérique de l'ébullition pour les procédés de trempe industrielle

摘要

This thesis focuses on the modelling of boiling that plays an important role on the coolingand heat treatment in quenching processes, it has two components: numerical simulations andexperimental measurements. Both simulations and experiments are envisaged for two scales. Thefirst one concerns small scales: the scale of one or few bubbles. In this case, the focus is put onvery precise numerical simulations for multiphase flows taking into account the surface tension,the direct computations of flows at high Reynolds number, and on reflecting the detachmentand coalescence of bubbles. On that same scale, experimental observations are performed tocontrol, in the volume or at surface, the nucleation of a vapour bubble using a high speedcamera. Measurements of velocity fields by PIV and the temperature by PLIF are realizedunder the same conditions. This will allow us to compare the growth dynamics and shapesof bubbles observed and calculated. Advanced numerical methods are used to fulfil this task:VMS stabilized finite elements, level set, anisotropic adaptation and parallel computing. Thenumerical models proposed in this work are extended and also used to deal with macroscopicscales: at the level of industrial parts considering the vapour films (or a phase of liquid vapourmixture). The additional challenge resides in the modelling of turbulence induced by boiling ina CFD approach.