AI Article Synopsis
- - Researchers are exploring surface engineering techniques to boost boiling heat transfer, benefiting thermal management and power generation, but scalable methods are still lacking for large-scale applications.
- - This study examines sandblasting as a method for surface engineering, using different abrasive sizes (25, 50, 100, and 150 μm) to analyze its impact on silicon surfaces and boiling performance.
- - Findings show that larger abrasive sizes improve surface roughness and wicking rate, resulting in critical heat flux and heat transfer coefficient enhancements of up to 192.6% and 434.3%, highlighting sandblasting’s potential for industrial applications.
Article Abstract
Surface engineering has been leveraged by researchers to enhance boiling heat transfer performance, with benefits ranging from improved thermal management to more efficient power generation. While engineered surfaces fabricated using cleanroom processes have shown promising boiling results, scalable methods for surface engineering are still limited despite most real-world industry-scale applications involving large boiling areas. In this work, we investigate the use of sandblasting as a scalable surface engineering technique for the enhancement of pool boiling heat transfer. We vary the size of an abrasive AlO sandblasting medium (25, 50, 100, and 150 μm) and quantify its effects on silicon surface conditions and boiling characteristics. The surface morphology and capillary wicking performance are characterized by optical profilometry and capillary rise tests, respectively. Pool boiling results and surface characterization reveal that surface roughness and volumetric wicking rate increase with the abrasive size, which results in improvements in the critical heat flux and the heat transfer coefficient of up to 192.6 and 434.3% compared to a smooth silicon surface, respectively. The significant enhancement achieved with sandblasted surfaces indicates that sandblasting is a promising option for improving boiling performance in industry-scale applications.
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| http://dx.doi.org/10.1021/acsami.1c22207 | DOI Listing |
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