posted on 2020-11-04, 11:43authored byYuchen Shen, Haoyang Zou, Sophie Wang
Microscale
surface structures have been widely explored as a promising
tool for antifreezing or frost avoidance on heat transfer surfaces.
Despite studies of many surface feature designs, the mechanisms associated
with condensation freezing and ice propagation on microstructured
surfaces have yet to be thoroughly elucidated, espectially when it
comes to quantitative understanding. In this work, condensation freezing
on circular micropillar surfaces is investigated, with varying pillar
spacing and height (layout/microscale roughness) but a constant pillar
diameter. The pillar layout is found to have significant effects on
both liquid nucleation and neighboring droplet interactions, as reflected
by the condensation droplet distribution prior to soilidification
and eventually the freezing front propagation area velocity. In general,
nucleation is preferred on the pillar top rather than the bottom of
the pillared surface unless there is a large distance between the
pillars. Interactions between neighboring droplets solely on pillar
tops (or bottom surfaces) can induce heterogeneity in the droplet
distribution and slow freezing front propagation. Based on the roles
the pillars play in nucleation, droplet coalescence, and ice bridging,
four different condensation states are identified and related to the
layout of the pillars, and the freezing front area propagation velocity
is found to be different in each state. The findings provide a quantitative
basis for designing antifreezing surfaces, applicable to a wide range
of thermal systems.