Heat Transfer in the Slip Flow with Axial Heat Conduction in a Microchannel with Walls Having a Constant Temperature

被引:0
|
作者
Y. Haddout
A. Oubarra
J. Lahjomri
机构
[1] Ibn Zohr University,Research Team ERMAM, Polydisciplinary Faculty of Ouarzazate
[2] Hassan II University,Laboratory of Mechanics, Faculty of Science Ain Chock
来源
Journal of Engineering Physics and Thermophysics | 2020年 / 93卷
关键词
heat transfer; forced convection; slip flow; axial heat conduction; rarefaction; self-adjoint formalism;
D O I
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学科分类号
摘要
The problem on thermally developed laminar slip gas flow with axial heat conduction in a microchannel (a micropipe or a parallel-plate microchannel) with walls having a constant temperature was solved analytically with the use of the self-adjoint formalism method involving the rearrangement of the energy equation for this flow into a system of two partial differential equations of the first order. The temperature distribution and Nusselt numbers in such a flow have been determined on the assumption that it is hydrodynamically fully developed in the region of the thermal entrance of a microchannel. The data obtained show that the heat transfer in this flow is substantially dependent on the axial heat conduction in it and its rarefaction.
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页码:605 / 616
页数:11
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