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3rd Thermal and Fluids Engineering Conference (TFEC)

ISSN: 2379-1748

THERMOSYPHON PERFORMANCE IN DEPENDENCE OF CARBON-BASED NANOFLUIDS

Agnieszka Wlazlak
Wroclaw Univeristy of Science and Technology, Department of Mechanical and Power Engineering, Wybrzeże St. Wyspiańskiego 27, 50-370 Wrocław, Poland; Institut für Luft- und Kältetechnik, Bertolt-Brecht-Allee 20, Dresden 01309, Germany

B. Zajaczkowski
Wroclaw Univeristy of Science and Technology, Department of Mechanical and Power Engineering, Wybrzeże St. Wyspiańskiego 27, 50-370 Wroclaw, Poland

M. Woluntarski
Institute of Electronics Materials Technology, Department of Chemical Technologies, Wólczyńska 133, Warsaw 01-919, Poland

Matthias H. Buschmann
Institut für Luft- und Kältetechnik gGmbH, Bertolt-Brecht-Allee 20, 01309 Dresden, Germany

DOI: 10.1615/TFEC2018.mnh.021951
pages 1661-1665


KEY WORDS: Thermosyphon, nanofluids, graphene oxide, nanohorns, surfactant

Abstract

Increasing global energy demands results in the need for efficient and environmentally friendly solutions. Nanofluids, which are suspensions of particles with an average size smaller than 100 nm in basefluids (mostly water, glycols and refrigerants), may become such a solution. Upward trends in excess heat which should be removed from electronic devices intensify research on this topic. Nanofluids show potential to work as ecological heat carriers without clogging, sedimentation and abrasion problems, commonly met with suspensions of larger particles.

Usage of nanofluids in heat exchangers may result in enhanced thermal efficiency what for thermosyphon means lower thermal resistance. Two-phase closed thermosyphon is relatively simple device that is characterized by quite complex thermodynamics. Experimental study presented here focuses on selected carbon-based nanofluids: nanohorns stabilized with SDS and graphene oxide with and without addition of the same surfactant, employed as working fluid in thermosyphon.

Addition of nanoparticles to water may improve heat transfer processes in the device by various mechanisms, among others by nanolayer deposition on the inner surface of the evaporator and lowering the surface tension. Moreover, some nanofluids prevents thermal instabilities − geyser boiling - appearing in the device exposed to high heat fluxes. This somewhat unforeseen result is mostly affected by employed surfactants. However, it turns out that chemistry of the particle surface also plays a key role.

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