Entropy generation of graphene-platinum hybrid nanofluid flow through a wavy cylindrical microchannel solar receiver by using neural networks

Khosravi Raouf; Rabiei Saeed; Khaki MohammadSafaei Mohammad RezaGoodarzi Marjan

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Entropy generation of graphene-platinum hybrid nanofluid flow through a wavy cylindrical microchannel solar receiver by using neural networks

机译：Entropy generation of graphene-platinum hybrid nanofluid flow through a wavy cylindrical microchannel solar receiver by using neural networks

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Analyzing microchannel heat sinks (MCHS) in terms of the second thermodynamic law is useful, and it is necessary to examine MCHSs in terms of irreversible factors. In this research, the second thermodynamic law analysis is conducted for graphene-platinum/water hybrid nanofluid flow to assess how a new cylindrical microchannel heat sink has wavy-shaped fins performs. A variety of Reynolds numbers, nanoparticle concentrations as well as wave amplitudes are used to simulate the problem, while the heat flux is constant. Fluent software is employed to solve the governing equations employing the control-volume method. The distributions of velocity and temperature are derived, and the entropy generation rate (including the generation of thermal as well as frictional entropy), along with the Bejan number, is obtained. The minimum values corresponding to the pointed parameters are, respectively, obtained as 7.63 x 10(-2), 1.24 x 10(-4), and 7.78 x 10(-2), while the maximum magnitudes are 1.09 x 10(-1), 1.49 x 10(-3), and 1.09 x 10(-1), respectively. Increasing each factor, including wave amplitude, particle fraction, and Reynolds number, causes a decline in the thermal entropy generation rate, while frictional entropy rises significantly. The Bejan number was obtained greater than 0.98 in all cases, which means that irreversibility mainly results from the thermal entropy generation. This could be a desirable finding, noting that increasing input variables reduced the thermal entropy generation rate. Finally, by employing an artificial neural network, a model is obtained for the entropy generation of entropy based on distinct factors of wave amplitude, nanofluid concentration, and Reynolds number.

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《Journal of thermal analysis and calorimetry》 |2021年第4期|1949-1967|共19页
作者
Khosravi Raouf; Rabiei Saeed; Khaki MohammadSafaei Mohammad RezaGoodarzi Marjan;
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作者单位

Ferdowsi Univ Mashhad, Dept Mech Engn, Mashhad, Razavi Khorasan, Iran;

Florida Int Univ, Dept Civil & Environm Engn, Miami, FL 33174 USA;

King Abdulaziz Univ, Fac Sci, Dept Math, POB 80259, Jeddah, Saudi Arabia;

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正文语种英语
中图分类物理化学（理论化学）、化学物理学;
关键词
Wavy-shaped fins; Hybrid nanofluid; Entropy generation; Bejan number; Artificial neural network;

Entropy generation of graphene-platinum hybrid nanofluid flow through a wavy cylindrical microchannel solar receiver by using neural networks

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