Experimental and computational analysis of thermal mixing characteristics of a coaxial jet

•Experimental and numerical analyses of thermal mixing of a coaxial jet.•The dominant frequency of temperature fluctuation is found as 5Hz.•There is a good agreement between experimental and numerical studies with respect to spectral analyses.•Thermal mixing efficiency increases with increasing temp...

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Veröffentlicht in:	Experimental thermal and fluid science 2017-04, Vol.82, p.276-286
Hauptverfasser:	Kok, Besir, Varol, Yasin, Ayhan, Hüseyin, Oztop, Hakan F.
Format:	Artikel
Sprache:	eng
Schlagworte:	Automotive engineering CAD Coaxial jet Computational fluid dynamics Computer aided design Computer applications Computer simulation Flow rates Fluid flow Fluids Heat transfer Industrial applications Large eddy simulation LES Mass flow rate Mathematical models Temperature effects Thermal mixing Thermal stress Turbulence Variation
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creator	Kok, Besir Varol, Yasin Ayhan, Hüseyin Oztop, Hakan F.
description	•Experimental and numerical analyses of thermal mixing of a coaxial jet.•The dominant frequency of temperature fluctuation is found as 5Hz.•There is a good agreement between experimental and numerical studies with respect to spectral analyses.•Thermal mixing efficiency increases with increasing temperature difference between hot and cold jet. In this study, experimental and numerical analyses have been performed to investigate the mixing behavior of hot and cold fluids for a coaxial jet. Thermal mixing phenomenon is an important issue for many industrial applications, since thermal stress occurs when fluids do not mix completely. Several test cases were considered to investigate the mixing quality and frequency of temperature fluctuations. Computational study was performed using Large Eddy Simulation (LES) turbulence model, since this model is proven in this type calculations. A commercial CFD code, ANSYS-Fluent is used for numerical calculations. The study is performed for governing parameters as ratio of mass flow rate of hot (annular) jet to cold (central) jet and temperature difference between hot and cold jet. It is found that there is a good agreement between experimental and numerical studies with respect to spectral analyses. The dominant frequency of temperature fluctuation is found as 5Hz as compatible with literature. Thermal mixing efficiency increases with increasing temperature difference between hot and cold jet. Also, thermal mixing performance getting better with enhancing flow rate of hot jet in the first half of the channel and the best mixing observed at ṁh/ṁc=2 along second half of the channel.
doi_str_mv	10.1016/j.expthermflusci.2016.11.028
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The dominant frequency of temperature fluctuation is found as 5Hz as compatible with literature. Thermal mixing efficiency increases with increasing temperature difference between hot and cold jet. 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subjects	Automotive engineering CAD Coaxial jet Computational fluid dynamics Computer aided design Computer applications Computer simulation Flow rates Fluid flow Fluids Heat transfer Industrial applications Large eddy simulation LES Mass flow rate Mathematical models Temperature effects Thermal mixing Thermal stress Turbulence Variation
title	Experimental and computational analysis of thermal mixing characteristics of a coaxial jet
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