Suppressing condensation frosting using micropatterned ice walls
Condensation frosting is encountered ubiquitously in our daily life and numerous industrial applications, rooting many detrimental consequences in heat transfer and mechanical stabilities. In latest decades, both active de-frosting and passive anti-frosting methods have been developed. In this work,...
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sg-ntu-dr.10356-1746122024-04-03T08:19:02Z Suppressing condensation frosting using micropatterned ice walls Zuo, Zichao Zhao, Yugang Li, Kang Zhang, Hua Yang, Chun School of Mechanical and Aerospace Engineering Engineering Anti-frosting Microscopic patterns Condensation frosting is encountered ubiquitously in our daily life and numerous industrial applications, rooting many detrimental consequences in heat transfer and mechanical stabilities. In latest decades, both active de-frosting and passive anti-frosting methods have been developed. In this work, we adopt the concept of three-dimensional overlapping dry zones by patterning microscopic ice walls on a smooth substrate, engendering a sustainable frost coverage of less than 13 %. Patterned ice walls prevent vapor deposition on the substrate base by absorbing all incoming moisture on upper sidewalls, leaving the substrate base free of contaminates from both frost and condensate. To ensure vapor preferentially depositing on upper sidewalls, a critical ice wall height exists, below which fine ice grains initiate in the adjacent of the substrate base and grow substantially faster, compromising the anti-frosting performance. The proposed surface shows reasonable durability when exposed to varying substrate supercooling, and frost coverage may increase due to covering and fracturing of the out-of-plane growth of feather-like ice clusters at large substrate supercooling. Our findings provide an effective anti-frosting surface design that doesn't require any chemical or mechanical modifications on the targeted surfaces, showing great advantages compared to conventional icephobic surface designs. This study was supported by the National Natural Science Foundation of China (No. 52276079), the Experiments for Space Exploration Program and the Qian Xuesen Laboratory, China Academy of Space Technology (Grant No. TKTSPY-2020-01-01), Open Fund of Key Laboratory of Icing and Anti/De-icing (Grant No. IADL20200103), National Key R&D Program of China (Grant No. 2020YFF0303901), and the Central Guidance on Local Science and Technology Development Fund of Shanghai City (Grant No. YDZX20213100003002). 2024-04-03T08:19:02Z 2024-04-03T08:19:02Z 2023 Journal Article Zuo, Z., Zhao, Y., Li, K., Zhang, H. & Yang, C. (2023). Suppressing condensation frosting using micropatterned ice walls. Applied Thermal Engineering, 224, 120099-. https://dx.doi.org/10.1016/j.applthermaleng.2023.120099 1359-4311 https://hdl.handle.net/10356/174612 10.1016/j.applthermaleng.2023.120099 2-s2.0-85146866780 224 120099 en Applied Thermal Engineering © 2023 Elsevier Ltd. All rights reserved. |
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Engineering Anti-frosting Microscopic patterns |
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Engineering Anti-frosting Microscopic patterns Zuo, Zichao Zhao, Yugang Li, Kang Zhang, Hua Yang, Chun Suppressing condensation frosting using micropatterned ice walls |
| description |
Condensation frosting is encountered ubiquitously in our daily life and numerous industrial applications, rooting many detrimental consequences in heat transfer and mechanical stabilities. In latest decades, both active de-frosting and passive anti-frosting methods have been developed. In this work, we adopt the concept of three-dimensional overlapping dry zones by patterning microscopic ice walls on a smooth substrate, engendering a sustainable frost coverage of less than 13 %. Patterned ice walls prevent vapor deposition on the substrate base by absorbing all incoming moisture on upper sidewalls, leaving the substrate base free of contaminates from both frost and condensate. To ensure vapor preferentially depositing on upper sidewalls, a critical ice wall height exists, below which fine ice grains initiate in the adjacent of the substrate base and grow substantially faster, compromising the anti-frosting performance. The proposed surface shows reasonable durability when exposed to varying substrate supercooling, and frost coverage may increase due to covering and fracturing of the out-of-plane growth of feather-like ice clusters at large substrate supercooling. Our findings provide an effective anti-frosting surface design that doesn't require any chemical or mechanical modifications on the targeted surfaces, showing great advantages compared to conventional icephobic surface designs. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Zuo, Zichao Zhao, Yugang Li, Kang Zhang, Hua Yang, Chun |
| format |
Article |
| author |
Zuo, Zichao Zhao, Yugang Li, Kang Zhang, Hua Yang, Chun |
| author_sort |
Zuo, Zichao |
| title |
Suppressing condensation frosting using micropatterned ice walls |
| title_short |
Suppressing condensation frosting using micropatterned ice walls |
| title_full |
Suppressing condensation frosting using micropatterned ice walls |
| title_fullStr |
Suppressing condensation frosting using micropatterned ice walls |
| title_full_unstemmed |
Suppressing condensation frosting using micropatterned ice walls |
| title_sort |
suppressing condensation frosting using micropatterned ice walls |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/174612 |
| _version_ |
1814047213033095168 |