Abstract
Boiling heat transfer intensification is of significant relevance to energy conversion and various cooling processes. This study aimed to enhance the saturated pool boiling of FC-72 (a dielectric liquid) by surface modifications and explore mechanisms of the enhancement. Specifically, circular and square micro pin fins were fabricated on silicon surfaces by dry etching and then copper nanoparticles were deposited on the micro-pin-fin surfaces by electrostatic deposition. Experimental results indicated that compared with a smooth surface, the micro pin fins increased the heat transfer coefficient and the critical heat flux by more than 200 and 65–83%, respectively, which were further enhanced by the nanoparticles up to 24% and more than 20%, respectively. Correspondingly, the enhancement mechanism was carefully explored by high-speed bubble visualizations, surface wickability measurements, and model analysis. It was quantitatively found that small bubble departure diameters with high bubble departure frequencies promoted high heat transfer coefficients. The wickability, which characterizes the ability of a liquid to rewet a surface, played an important role in determining the critical heat flux, but further analyses indicated that evaporation beneath bubbles was also essential and competition between the wicking and the evaporation finally triggered the critical heat flux.
Highlights
We are in the age of digitalization, intelligentization, and automation, which greatly depends on electronics varying from small laptops to large servers and data centers, where electronic cooling is a big issue that affects the efficiency and life span.[1]
Nanoparticle-assisted pool boiling of FC-72 was experimentally studied on micro-pin-fin-surfaces (CPF-1, SPF1, and SPF-2)
In comparison to a smooth surface, the micro pin fins increase the heat transfer coefficient by more than 200% and the critical heat flux by 65−83%, while the nanoparticles can further enhance the critical heat flux and the heat transfer coefficient by up to 24% and more than 20%, respectively
Summary
We are in the age of digitalization, intelligentization, and automation, which greatly depends on electronics varying from small laptops to large servers and data centers, where electronic cooling is a big issue that affects the efficiency and life span.[1]. It is reported that the heat load of a blade server could reach up to 7.5−10.5 kW by 2020,4 which might be too high to be dissipated rapidly by air cooling. Stimulated by this, a supercooling scheme utilizing boiling heat transfer, viz., immersion cooling, is quite competitive because boiling has at least one order of magnitude higher heat transfer coefficients than air-forced convection,[5] and the immersion cooling has been regarded as the technology for data center cooling.[6] A few attempts have been made to investigate the immersion cooling performance,[7−10] with water and dielectric liquids, e.g., FC-72, HFE-7100, and Novec-649. It is essential to investigate the boiling performance of dielectric liquids with respect to their application in electronic cooling
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
