Droplet evaporation and boiling for different mixing ratios of the silver-graphene hybrid nanofluid over heated surfaces

Research output: Journal Publications and Reviews (RGC: 21, 22, 62)21_Publication in refereed journalpeer-review

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Author(s)

  • F. R. Siddiqui
  • C. Y. Tso
  • S. C. Fu
  • H. H. Qiu
  • Christopher Y.H. Chao

Related Research Unit(s)

Detail(s)

Original languageEnglish
Article number121786
Journal / PublicationInternational Journal of Heat and Mass Transfer
Volume180
Online published6 Aug 2021
Publication statusOnline published - 6 Aug 2021

Abstract

Thermal management of many high heat flux devices depends on droplet based cooling, such as the spray cooling or electro-wetting for hotspot cooling. Recently, heat dissipation in these devices increased to unprecedented levels, pressing a need for advanced thermal fluids in droplet based cooling systems. In this paper, we address this challenge by investigating the evaporation and boiling performance of the silver-graphene hybrid nanofluid (SGHF) droplet for its various mixing ratios and droplet sizes on a heated copper and a residue surface, obtained from the evaporation of the first SGHF droplet. The results show that low mixing ratio (MR ≤ 0.1) SGHF droplets exhibit highest evaporation rates for substrate temperature (Ts) in a range of 25 °C ≤ Ts≤ 100 °C. However, this trend is reversed in the nucleate boiling regime, where high mixing ratio (MR ≥ 0.9) droplets give highest evaporation rates. Moreover, all SGHF droplets, irrespective of their mixing ratio, exhibit similar evaporation rates in the film-boiling regime. Furthermore, the SGHF droplet evaporation rate on its porous residue surface increases up to 173% for 25 °C ≤ Ts≤ 100 °C and by an order of magnitude in the nucleate boiling regime as compared to a plain copper surface. We also show that besides the synergistic thermal effect, the thermal Marangoni convection also affects the SGHF droplet evaporation rate. Moreover, we develop a diffusion-convection evaporation model that can predict the evaporation rate for different mixing ratios of the SGHF droplet on heated copper and residue surfaces. Moreover, we demonstrate that the latent heat flux up to 890 W/cm2 and 850 W/cm2 can be achieved using a SGHF droplet on heated copper and residue surfaces, respectively, suggesting its potential application in high heat flux device cooling. Finally, we discuss the effects of spray hydrodynamic parameters on critical heat flux of the SGHF spray cooling.

Research Area(s)

  • Boiling, Droplet residue, Evaporation, Hybrid nanofluid, Marangoni effect

Citation Format(s)

Droplet evaporation and boiling for different mixing ratios of the silver-graphene hybrid nanofluid over heated surfaces. / Siddiqui, F. R.; Tso, C. Y.; Fu, S. C.; Qiu, H. H.; Chao, Christopher Y.H.

In: International Journal of Heat and Mass Transfer, Vol. 180, 121786, 12.2021.

Research output: Journal Publications and Reviews (RGC: 21, 22, 62)21_Publication in refereed journalpeer-review