The effects of the surface roughness on the dynamic behavior of the successive micrometric droplets impacting onto inclined hot surfaces

•Experimental study on the surface roughness effects during micrometric droplets impacting onto inclined heated solid surfaces was studied.•The higher the surface roughness, the lower the quenching time during the spray cooling.•The surface roughness takes part as the interrupting the shrinking drop...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2016-10, Vol.101, p.1217-1226
Main Authors: Deendarlianto, Takata, Yasuyuki, Kohno, Masamichi, Hidaka, Sumitomo, Wakui, Takaaki, Majid, Akmal Irfan, Kuntoro, Hadiyan Yusuf, Indarto, Widyaparaga, Adhika
Format: Article
Language:English
Subjects:
Dimensional height
Droplet
Quenching curves
Sliding distance
Solid–liquid contact time
Spray cooling
Spread ratio
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Summary:•Experimental study on the surface roughness effects during micrometric droplets impacting onto inclined heated solid surfaces was studied.•The higher the surface roughness, the lower the quenching time during the spray cooling.•The surface roughness takes part as the interrupting the shrinking droplet.•The critical heat flux (CHF) and Leidenfrost temperatures are independent to the surface roughness. The effect of surface roughness on the dynamic behavior and the heat transfer phenomena of multiple successive micrometric water droplets impacting onto inclined heated solid surfaces has been studied experimentally. The inclination angles were 15°, 30°, and 45° from horizontal. The droplet diameters were 500μm and 700μm. The solid surface temperatures were decreased from 500°C to 100°C. The test material was stainless steel-grade 304 (SUS 304) with different surface roughness ranged from Ra 0.04 up to Ra 10. The droplet dynamics during the impacting onto inclined hot surfaces were investigated by using high-speed video camera. It was found that the surface roughness significantly affects quenching behavior. The higher the surface roughness, the lower the quenching time during the spray cooling. The solid-droplet contact time and the droplet spread diameter increase with the increase of surface roughness. Thus causing the decrease of the quenching time of inclined hot walls. Meanwhile, the critical heat flux and Leidenfrost temperatures are shown to be insensitive to the surface roughness.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2016.05.132