Micro- and nanoengineered metal additively manufactured surfaces for enhanced anti-frosting applications
The greater geometrical design freedom offered by additive manufacturing (AM) as compared to the conventional manufacturing method has attracted increasing interest in AM to develop innovative and complex designs for enhanced performance. However, the difference in material composition and surface p...
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sg-ntu-dr.10356-1809622024-11-05T23:55:02Z Micro- and nanoengineered metal additively manufactured surfaces for enhanced anti-frosting applications Zhao, Huanyu Ye, Hanyang Rabbi, Kazi Fazle Wang, Xinrui Miljkovic, Nenad Ho, Jin Yao School of Mechanical and Aerospace Engineering Singapore Centre for 3D Printing Engineering Additive manufacturing Condensation frosting The greater geometrical design freedom offered by additive manufacturing (AM) as compared to the conventional manufacturing method has attracted increasing interest in AM to develop innovative and complex designs for enhanced performance. However, the difference in material composition and surface properties from conventional alloys has made surface micro-/nanostructuring of AM metals challenging. Frost accretion is a safety hazard in numerous engineering applications. To expand the application of AM, this study experimentally investigates the antifrosting performance of superhydrophobic and slippery lubricant-infused porous surfaces (SLIPSs) generated on AM alloy, AlSi10Mg. By strategically utilizing the subgrain structure in the metallography of the AM alloy, the functionalized superhydrophobic AM surface featuring hierarchical structures was shown to greatly reduce frost formation as compared to functionalized single-tier structured surfaces, hierarchical structures formed on conventional aluminum alloy surfaces, and SLIPSs. Optical observation of frost propagation demonstrated that the mechanism of frost delay is governed by the inhibition of spontaneous droplet freezing through exceptional Cassie state stability during condensation frosting. The Cassie stability results from the unique AM structure morphology, which creates a higher structural energy barrier to prevent condensate from infiltrating the cavities. This phenomenon also enables the formation of a high surface-to-droplet thermal resistance, which eliminates spontaneous droplet freezing down to a -15 °C surface temperature. Our work demonstrates a scalable structuring method for AM metals, which can result in delayed frost formation, and it also provides guidelines for the development of engineered surfaces requiring the antifrosting function for several industries. Ministry of Education (MOE) Nanyang Technological University National Research Foundation (NRF) The SLM-280HL equipment used in this research is supported by the National Research Foundation, Prime Minister’s Office, Singapore under its Medium-Sized Centre funding scheme. J.Y.H. would like to acknowledge the financial support for the projects under Nanyang Technological University’s Start-up Grant (SUG) and RS14/21 MOE Tier 1 Grant provided by Ministry of Education (MOE), Singapore. This research was partially supported by the Air Conditioning and Refrigeration Center at the University of Illinois. N.M. gratefully acknowledges funding support from the International Institute for Carbon Neutral Energy Research (WPI-I2CNER), sponsored by the Japanese Ministry of Education, Culture, Sports, Science, and Technology. 2024-11-05T23:55:01Z 2024-11-05T23:55:01Z 2024 Journal Article Zhao, H., Ye, H., Rabbi, K. F., Wang, X., Miljkovic, N. & Ho, J. Y. (2024). Micro- and nanoengineered metal additively manufactured surfaces for enhanced anti-frosting applications. ACS Applied Materials & Interfaces, 16(27), 35697-35715. https://dx.doi.org/10.1021/acsami.4c02765 1944-8244 https://hdl.handle.net/10356/180962 10.1021/acsami.4c02765 38934253 2-s2.0-85197646977 27 16 35697 35715 en RS14/21 NTU SUG ACS Applied Materials & Interfaces © 2024 American Chemical Society. All rights reserved. |
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Engineering Additive manufacturing Condensation frosting |
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Engineering Additive manufacturing Condensation frosting Zhao, Huanyu Ye, Hanyang Rabbi, Kazi Fazle Wang, Xinrui Miljkovic, Nenad Ho, Jin Yao Micro- and nanoengineered metal additively manufactured surfaces for enhanced anti-frosting applications |
| description |
The greater geometrical design freedom offered by additive manufacturing (AM) as compared to the conventional manufacturing method has attracted increasing interest in AM to develop innovative and complex designs for enhanced performance. However, the difference in material composition and surface properties from conventional alloys has made surface micro-/nanostructuring of AM metals challenging. Frost accretion is a safety hazard in numerous engineering applications. To expand the application of AM, this study experimentally investigates the antifrosting performance of superhydrophobic and slippery lubricant-infused porous surfaces (SLIPSs) generated on AM alloy, AlSi10Mg. By strategically utilizing the subgrain structure in the metallography of the AM alloy, the functionalized superhydrophobic AM surface featuring hierarchical structures was shown to greatly reduce frost formation as compared to functionalized single-tier structured surfaces, hierarchical structures formed on conventional aluminum alloy surfaces, and SLIPSs. Optical observation of frost propagation demonstrated that the mechanism of frost delay is governed by the inhibition of spontaneous droplet freezing through exceptional Cassie state stability during condensation frosting. The Cassie stability results from the unique AM structure morphology, which creates a higher structural energy barrier to prevent condensate from infiltrating the cavities. This phenomenon also enables the formation of a high surface-to-droplet thermal resistance, which eliminates spontaneous droplet freezing down to a -15 °C surface temperature. Our work demonstrates a scalable structuring method for AM metals, which can result in delayed frost formation, and it also provides guidelines for the development of engineered surfaces requiring the antifrosting function for several industries. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Zhao, Huanyu Ye, Hanyang Rabbi, Kazi Fazle Wang, Xinrui Miljkovic, Nenad Ho, Jin Yao |
| format |
Article |
| author |
Zhao, Huanyu Ye, Hanyang Rabbi, Kazi Fazle Wang, Xinrui Miljkovic, Nenad Ho, Jin Yao |
| author_sort |
Zhao, Huanyu |
| title |
Micro- and nanoengineered metal additively manufactured surfaces for enhanced anti-frosting applications |
| title_short |
Micro- and nanoengineered metal additively manufactured surfaces for enhanced anti-frosting applications |
| title_full |
Micro- and nanoengineered metal additively manufactured surfaces for enhanced anti-frosting applications |
| title_fullStr |
Micro- and nanoengineered metal additively manufactured surfaces for enhanced anti-frosting applications |
| title_full_unstemmed |
Micro- and nanoengineered metal additively manufactured surfaces for enhanced anti-frosting applications |
| title_sort |
micro- and nanoengineered metal additively manufactured surfaces for enhanced anti-frosting applications |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/180962 |
| _version_ |
1816858953929195520 |