Behavior of Thermally Radiating Tree-Like Fins

David Calamas; John Baker

doi:10.1115/1.4024279

Behavior of Thermally Radiating Tree-Like Fins

David Calamas, John Baker

Mechanical Engineering

Department of Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

The performance of tree-like fins with varying bifurcation angle, surface emissivity, material, width-to-thickness ratio, and base heat rate was examined. Overall system performance was examined computationally. The computational results have been validated, verified, and cast in terms of commonly defined dimensionless parameters. Tree-like fins were found to be more effective and more efficient than the rectangular fins. Fin efficiency and effectiveness were found to increase with increasing bifurcation angles while base temperatures were found to decrease with increasing bifurcation angles. As expected, base temperatures were highest for the largest width-to-thickness ratios and smallest for materials with relatively higher thermal conductivities.

Original language	American English
Journal	Journal of Heat Transfer
Volume	135
DOIs	https://doi.org/10.1115/1.4024279
State	Published - Jul 18 2013

Disciplines

Mechanical Engineering
Heat Transfer, Combustion

Keywords

Bifurcation
Emissivity
Fins
Heat
Heat transfer
Temperature
Thickness

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title = "Behavior of Thermally Radiating Tree-Like Fins",

abstract = " The performance of tree-like fins with varying bifurcation angle, surface emissivity, material, width-to-thickness ratio, and base heat rate was examined. Overall system performance was examined computationally. The computational results have been validated, verified, and cast in terms of commonly defined dimensionless parameters. Tree-like fins were found to be more effective and more efficient than the rectangular fins. Fin efficiency and effectiveness were found to increase with increasing bifurcation angles while base temperatures were found to decrease with increasing bifurcation angles. As expected, base temperatures were highest for the largest width-to-thickness ratios and smallest for materials with relatively higher thermal conductivities.",

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AU - Baker, John

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N2 - The performance of tree-like fins with varying bifurcation angle, surface emissivity, material, width-to-thickness ratio, and base heat rate was examined. Overall system performance was examined computationally. The computational results have been validated, verified, and cast in terms of commonly defined dimensionless parameters. Tree-like fins were found to be more effective and more efficient than the rectangular fins. Fin efficiency and effectiveness were found to increase with increasing bifurcation angles while base temperatures were found to decrease with increasing bifurcation angles. As expected, base temperatures were highest for the largest width-to-thickness ratios and smallest for materials with relatively higher thermal conductivities.

AB - The performance of tree-like fins with varying bifurcation angle, surface emissivity, material, width-to-thickness ratio, and base heat rate was examined. Overall system performance was examined computationally. The computational results have been validated, verified, and cast in terms of commonly defined dimensionless parameters. Tree-like fins were found to be more effective and more efficient than the rectangular fins. Fin efficiency and effectiveness were found to increase with increasing bifurcation angles while base temperatures were found to decrease with increasing bifurcation angles. As expected, base temperatures were highest for the largest width-to-thickness ratios and smallest for materials with relatively higher thermal conductivities.

KW - Bifurcation

KW - Emissivity

KW - Fins

KW - Heat

KW - Heat transfer

KW - Temperature

KW - Thickness

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SN - 0022-1481

VL - 135

JO - Journal of Heat Transfer

JF - Journal of Heat Transfer

ER -

Behavior of Thermally Radiating Tree-Like Fins

Abstract

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Keywords

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