NDLI: Conjugate Mixed Convection With Surface Radiation and Substrate Conduction in Laminar Channel Flow With Discrete Flush-Mounted Heat Sources

Content Provider	The American Society of Mechanical Engineers (ASME) Digital Collection
Author	He, Jing Anthony, M. Jacobi
Copyright Year	2010
Abstract	Thermal analysis employing a full conjugation model is performed in this study for laminar airflow in a parallel-plate channel with discrete flush-mounted heat sources. The numerical model accounts for mixed convection, surface radiation, and two-dimensional conduction in the substrate. The effects of Reynolds number, surface emissivity of walls and heat sources, as well as thickness and thermal conductivity of the substrate, are analyzed in detail. It is shown that participation of radiation brings the wall temperatures closer, and the trend of temperature variation along the top wall is drastically altered. Such effects are pronounced for black enclosures and diminished for high Reynolds numbers. The influence of substrate conductivity and thickness is very similar in that a large value for both parameters would facilitate redistribution of heat and tend to yield a uniform temperature field in the substrate. For highly conductive or thick substrate, the ‘hot spot’ cools down and may move upstream to the penultimate source. Radiation loss to the ambient increases with substrate conductivity and thickness due to the elevated temperature near the inlet and outlet, yet the total heat transfer over the bottom surface by convection and radiation remains unaltered.
Starting Page	227
Ending Page	234
Page Count	8
File Format	PDF
ISBN	9780791844281
DOI	10.1115/IMECE2010-39916
Volume Number	Volume 4: Electronics and Photonics
Conference Proceedings	ASME 2010 International Mechanical Engineering Congress and Exposition
Language	English
Publisher Date	2010-11-12
Publisher Place	Vancouver, British Columbia, Canada
Access Restriction	Subscribed
Subject Keyword	Laminar channel flow Conjugate heat transfer Air cooling Flushed-mounted heat sources Heat conduction Heat Channel flow Mixed convection Radiation (physics) Heat transfer
Content Type	Text
Resource Type	Article

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