Study of a regenerative cooling system while using heat-conductive metal nanoparticle suspension in n-decane

The paper presents the calculation estimates for efficiency of regenerative cooling for a model cylinder-shaped flow duct using a suspension of heat-conductive metal nanoparticles in n-decane as fuel/coolant. We adapted a standard mathematical model of conjugated heat transfer that accounts for ther...

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Veröffentlicht in:	Thermophysics and aeromechanics 2023-09, Vol.30 (5), p.925-934
Hauptverfasser:	Arefiev, K. Yu, Saveliev, A. M., Voronetskii, A. V., Kruchkov, S. V.
Format:	Artikel
Sprache:	eng
Schlagworte:	Cooling systems Heat transfer Mathematical models Nanoparticles Physics Physics and Astronomy Regenerative cooling Thermodynamics Thermophysical models Thermophysical properties
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container_title	Thermophysics and aeromechanics
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creator	Arefiev, K. Yu Saveliev, A. M. Voronetskii, A. V. Kruchkov, S. V.
description	The paper presents the calculation estimates for efficiency of regenerative cooling for a model cylinder-shaped flow duct using a suspension of heat-conductive metal nanoparticles in n-decane as fuel/coolant. We adapted a standard mathematical model of conjugated heat transfer that accounts for thermophysical properties of the metal nanoparticle suspension and n-decane. The data are presented for heating up the nanosuspension and the model duct walls for the cases of different content of metal nanoparticles in nanosuspension. There exists a range beneficial for heat transfer from n-decane.
doi_str_mv	10.1134/S0869864323050104
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subjects	Cooling systems Heat transfer Mathematical models Nanoparticles Physics Physics and Astronomy Regenerative cooling Thermodynamics Thermophysical models Thermophysical properties
title	Study of a regenerative cooling system while using heat-conductive metal nanoparticle suspension in n-decane
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