Ice Dendrite Growth Atop a Frozen Drop under Natural Convection Conditions

Condensation frosting is a type of icing encountered ubiquitously in our daily lives. Understanding the dynamics of condensation frosting is essential in developing effective technologies to suppress frost accretions that compromise heat transfer and system integrity. Here, we present an experimental study on ice dendrite growth atop a single frozen drop, an important step affecting the subsequent frosting process, and the properties of fully-developed frost layers. We evaluate the effect of natural convection by comparing the growth dynamics of ice dendrites on the surface of a frozen drop with three different orientations with respect to gravity. The results show that both the average deposition rate and its spatial variations are profoundly altered by surface orientations. Such behavior is confirmed by a numerical simulation, showing how gravity-assisted (hindered) vapor diffusion yields the deposition outcomes. These findings benefit the optimization of anti-/de- frosting technologies and the rational design of heat exchangers.

Automated summary

This study experimentally investigated the dynamics of condensation frosting, focusing on the growth of ice dendrites and the properties of fully-developed frost layers. The results showed that surface orientations have a significant impact on the growth rate and spatial variations of ice dendrites. These findings are valuable for optimizing defrosting technologies and heat exchanger design.