Numerical Simulation of Flow Characteristic in Microchannel between Parallel Flat Plates

A mathematical model was developed in describing flow behaviors of a microchannel between two parallel flat plates. The model was solved numerically using the commercial software, Fluent, and the effect of microchannel size and structure on the transition Reynolds number (Rec) was analyzed. Comparis...

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Veröffentlicht in:	Applied Mechanics and Materials 2013-09, Vol.423-426 (Applied Materials and Technologies for Modern Manufacturing), p.1763-1767
Hauptverfasser:	Yu, Lu, Gong, Fa Quan, Han, Xin Min, Sang, Feng Ting, Liu, Wan Fa, Lu, Peng, Pan, Yan Qiu
Format:	Artikel
Sprache:	eng
Schlagworte:	Computational fluid dynamics Computer programs Equivalence Flat plates Flow characteristics Mathematical models Microchannels Optimization
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container_end_page	1767
container_issue	Applied Materials and Technologies for Modern Manufacturing
container_start_page	1763
container_title	Applied Mechanics and Materials
container_volume	423-426
creator	Yu, Lu Gong, Fa Quan Han, Xin Min Sang, Feng Ting Liu, Wan Fa Lu, Peng Pan, Yan Qiu
description	A mathematical model was developed in describing flow behaviors of a microchannel between two parallel flat plates. The model was solved numerically using the commercial software, Fluent, and the effect of microchannel size and structure on the transition Reynolds number (Rec) was analyzed. Comparison between model prediction and experimental data in literature shows a good agreement, which verifies the reliability of the model. The results also show that the equivalent diameter has little effect on Rec. The magnitude of the Rec depends largely upon the contraction ratio. Consequently, the Recs under different contraction ratios were determined, which provides a theoretical basis for performance analysis and optimization of microchannel.
doi_str_mv	10.4028/www.scientific.net/AMM.423-426.1763
format	Article
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The model was solved numerically using the commercial software, Fluent, and the effect of microchannel size and structure on the transition Reynolds number (Rec) was analyzed. Comparison between model prediction and experimental data in literature shows a good agreement, which verifies the reliability of the model. The results also show that the equivalent diameter has little effect on Rec. The magnitude of the Rec depends largely upon the contraction ratio. 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The model was solved numerically using the commercial software, Fluent, and the effect of microchannel size and structure on the transition Reynolds number (Rec) was analyzed. Comparison between model prediction and experimental data in literature shows a good agreement, which verifies the reliability of the model. The results also show that the equivalent diameter has little effect on Rec. The magnitude of the Rec depends largely upon the contraction ratio. 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subjects	Computational fluid dynamics Computer programs Equivalence Flat plates Flow characteristics Mathematical models Microchannels Optimization
title	Numerical Simulation of Flow Characteristic in Microchannel between Parallel Flat Plates
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