Micro/nanostructuring of metal additively manufactured aluminum alloy for enhanced pool boiling of dielectric fluids
Surface micro/nanotextures have the potential to increase bubble nucleation and promote capillary liquid wicking to enhance pool boiling heat transfer significantly. Despite past studies implementing surface micro/nanofabrication strategies to enhance boiling, the role of structure length scale and...
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sg-ntu-dr.10356-1758802024-05-08T07:32:14Z Micro/nanostructuring of metal additively manufactured aluminum alloy for enhanced pool boiling of dielectric fluids Lum, Leymus Yong Xiang Liu, Pengfei Ho, Jin Yao School of Mechanical and Aerospace Engineering Singapore Centre for 3D Printing Engineering Nucleate pool boiling Additive manufacturing Surface micro/nanotextures have the potential to increase bubble nucleation and promote capillary liquid wicking to enhance pool boiling heat transfer significantly. Despite past studies implementing surface micro/nanofabrication strategies to enhance boiling, the role of structure length scale and morphology on boiling heat transfer coefficient (h) and critical heat flux (CHF) of low-surface-tension dielectric fluids remains unclear. In this study, we systematically tune the surface microstructures on additively and conventionally manufactured aluminum alloys (AM AlSi10Mg and Al6061) from 1 µm to 5 µm to study the influence of microstructure length scale on boiling performance. In addition, to further understand the effect of submicron structures on boiling, nanostructures of 300 nm length were generated on a plain AM surface and hierarchically incorporated atop the microstructures. Dielectric fluid, HFE-7100, was used to investigate the effects of surface morphology on pool boiling heat transfer coefficient (h) and critical heat flux (CHF). Our results show that the 5 µm microstructured AM surface, AM-H(400)E(5), attained a CHF of 19.44 W/cm2 and a maximum heat transfer coefficient (hmax) of 2.89 W/cm2·K, which represents a reduction in CHF of 28.5 % and an enhancement in hmax of 103.8 %, as compared to the plain Al6061 surface. In addition, AM-H(400)E(5) achieved a large enhancement ratio of 2.2 as compared to the plain Al6061 at a heat flux of 20 W/cm2, and the highest h value amongst all structured surfaces, indicating its cavity size is optimal for bubble nucleation. Through the systematic tuning of micro/nanostructures length scale and morphology, this study found that the micro/nanostructures of 1 µm size and below are too small to serve as bubble nucleation sites. Additionally, micro/nanostructure wickability plays a negligible role in affecting pool boiling performances of highly wetting dielectric fluids, while surface morphology plays a dominant role in bubble nucleation to enhance boiling. Lastly, high-speed immersion microscopy was performed to understand the effects of micro/nanostructures on bubble characteristics such as bubble departure diameter and growth period. In summary, this work not only reports the first micro/nanostructured AM surfaces utilizing scalable fabrication techniques for enhanced boiling, but it also demonstrates the potential of tunning the micro/nanostructure length scale to optimize the bubble nucleation site density, resulting in significantly improved pool boiling performances. Ministry of Education (MOE) Nanyang Technological University J.Y. Ho would like to acknowledge the financial support for this project under Nanyang Technological University’s Start-up Grant (SUG) and RS14/21 MOE Tier 1 Grant provided by Ministry of Education (MOE) Singapore. 2024-05-08T07:32:13Z 2024-05-08T07:32:13Z 2024 Journal Article Lum, L. Y. X., Liu, P. & Ho, J. Y. (2024). Micro/nanostructuring of metal additively manufactured aluminum alloy for enhanced pool boiling of dielectric fluids. International Journal of Heat and Mass Transfer, 221, 125090-. https://dx.doi.org/10.1016/j.ijheatmasstransfer.2023.125090 0017-9310 https://hdl.handle.net/10356/175880 10.1016/j.ijheatmasstransfer.2023.125090 2-s2.0-85181742773 221 125090 en NTU SUG RS14/21 International Journal of Heat and Mass Transfer © 2023 Elsevier Ltd. All rights reserved. |
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Engineering Nucleate pool boiling Additive manufacturing Lum, Leymus Yong Xiang Liu, Pengfei Ho, Jin Yao Micro/nanostructuring of metal additively manufactured aluminum alloy for enhanced pool boiling of dielectric fluids |
| description |
Surface micro/nanotextures have the potential to increase bubble nucleation and promote capillary liquid wicking to enhance pool boiling heat transfer significantly. Despite past studies implementing surface micro/nanofabrication strategies to enhance boiling, the role of structure length scale and morphology on boiling heat transfer coefficient (h) and critical heat flux (CHF) of low-surface-tension dielectric fluids remains unclear. In this study, we systematically tune the surface microstructures on additively and conventionally manufactured aluminum alloys (AM AlSi10Mg and Al6061) from 1 µm to 5 µm to study the influence of microstructure length scale on boiling performance. In addition, to further understand the effect of submicron structures on boiling, nanostructures of 300 nm length were generated on a plain AM surface and hierarchically incorporated atop the microstructures. Dielectric fluid, HFE-7100, was used to investigate the effects of surface morphology on pool boiling heat transfer coefficient (h) and critical heat flux (CHF). Our results show that the 5 µm microstructured AM surface, AM-H(400)E(5), attained a CHF of 19.44 W/cm2 and a maximum heat transfer coefficient (hmax) of 2.89 W/cm2·K, which represents a reduction in CHF of 28.5 % and an enhancement in hmax of 103.8 %, as compared to the plain Al6061 surface. In addition, AM-H(400)E(5) achieved a large enhancement ratio of 2.2 as compared to the plain Al6061 at a heat flux of 20 W/cm2, and the highest h value amongst all structured surfaces, indicating its cavity size is optimal for bubble nucleation. Through the systematic tuning of micro/nanostructures length scale and morphology, this study found that the micro/nanostructures of 1 µm size and below are too small to serve as bubble nucleation sites. Additionally, micro/nanostructure wickability plays a negligible role in affecting pool boiling performances of highly wetting dielectric fluids, while surface morphology plays a dominant role in bubble nucleation to enhance boiling. Lastly, high-speed immersion microscopy was performed to understand the effects of micro/nanostructures on bubble characteristics such as bubble departure diameter and growth period. In summary, this work not only reports the first micro/nanostructured AM surfaces utilizing scalable fabrication techniques for enhanced boiling, but it also demonstrates the potential of tunning the micro/nanostructure length scale to optimize the bubble nucleation site density, resulting in significantly improved pool boiling performances. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Lum, Leymus Yong Xiang Liu, Pengfei Ho, Jin Yao |
| format |
Article |
| author |
Lum, Leymus Yong Xiang Liu, Pengfei Ho, Jin Yao |
| author_sort |
Lum, Leymus Yong Xiang |
| title |
Micro/nanostructuring of metal additively manufactured aluminum alloy for enhanced pool boiling of dielectric fluids |
| title_short |
Micro/nanostructuring of metal additively manufactured aluminum alloy for enhanced pool boiling of dielectric fluids |
| title_full |
Micro/nanostructuring of metal additively manufactured aluminum alloy for enhanced pool boiling of dielectric fluids |
| title_fullStr |
Micro/nanostructuring of metal additively manufactured aluminum alloy for enhanced pool boiling of dielectric fluids |
| title_full_unstemmed |
Micro/nanostructuring of metal additively manufactured aluminum alloy for enhanced pool boiling of dielectric fluids |
| title_sort |
micro/nanostructuring of metal additively manufactured aluminum alloy for enhanced pool boiling of dielectric fluids |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/175880 |
| _version_ |
1800916122667581440 |