Melting dynamics of large ice balls in a turbulent swirling flow

Abstract

We study the melting dynamics of large ice balls in a turbulent von Kármán flow at very high Reynolds number. Using an optical shadowgraphy setup, we record the time evolution of particle sizes. We study the heat transfer as a function of the particle scale Reynolds number \documentclass[12pt]{minimal}\begin{document}$\mbox{\textit {Re}}_{D}$\end{document}ReD for three cases: fixed ice balls melting in a region of strong turbulence with zero mean flow, fixed ice balls melting under the action of a strong mean flow with lower fluctuations, and ice balls freely advected in the whole apparatus. For the fixed particles cases, heat transfer is observed to be much stronger than in laminar flows, the Nusselt number behaving as a power law of the Reynolds number: \documentclass[12pt]{minimal}\begin{document}$\mbox{\textit {Nu}} \propto \mbox{\textit {Re}}_{D}^{0.8}$\end{document}Nu∝ReD0.8. For freely advected ice balls, the turbulent transfer is further enhanced and the Nusselt number is proportional to the Reynolds number \documentclass[12pt]{minimal}\begin{document}$\mbox{\textit {Nu}} \propto \mbox{\textit {Re}}_{D}$\end{document}Nu∝ReD. Furthermore, the surface heat flux is found to be independent of the particles size, leading to an ultimate regime of heat transfer reached when the thermal boundary layer is fully turbulent.