Effects of Corner Geometry and Adiabatic Extensions on Heat Transfer through a Differentially Heated Square Cavity

Lei, C., Armfield, S. W., Patterson, J. C. and and O’Neill, A. (2007). Effects of Corner Geometry and Adiabatic Extensions on Heat Transfer through a Differentially Heated Square Cavity. In: Peter Jacobs, Tim McIntyre, Matthew Cleary, David Buttsworth, David Mee, Rose Clements, Richard Morgan and Charles Lemckert, 16th Australasian Fluid Mechanics Conference (AFMC). 16th Australasian Fluid Mechanics Conference (AFMC), Gold Coast, Queensland, Australia, (125-128). 3-7 December, 2007.

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Author Lei, C.
Armfield, S. W.
Patterson, J. C. and
O’Neill, A.
Title of paper Effects of Corner Geometry and Adiabatic Extensions on Heat Transfer through a Differentially Heated Square Cavity
Conference name 16th Australasian Fluid Mechanics Conference (AFMC)
Conference location Gold Coast, Queensland, Australia
Conference dates 3-7 December, 2007
Proceedings title 16th Australasian Fluid Mechanics Conference (AFMC)
Place of Publication Brisbane, Australia
Publisher School of Engineering, The University of Queensland
Publication Year 2007
Year available 2007
Sub-type Fully published paper
ISBN 978-1-864998-94-8
Editor Peter Jacobs
Tim McIntyre
Matthew Cleary
David Buttsworth
David Mee
Rose Clements
Richard Morgan
Charles Lemckert
Start page 125
End page 128
Total pages 4
Collection year 2007
Language eng
Abstract/Summary This study is concerned with heat transfer by natural convection in a differentially heated square cavity. The purpose is to explore numerically the effects of the corner geometry and adiabatic extensions on heat transfer through the sidewalls. Two sets of simulations have been carried out in this study. The first set is concerned with steady-state calculations with different corner shapes, and the second set considers both steady-state and transient heat transfer with adiabatic extensions of various dimensions. The numerical results are presented in this paper.
Subjects 290501 Mechanical Engineering
290200 Aerospace Engineering
Q-Index Code E1
Q-Index Status Provisional Code
Institutional Status Unknown

Document type: Conference Paper
Collection: 16th Australasian Fluid Mechanics Conference
 
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Created: Tue, 18 Dec 2007, 13:35:17 EST by Laura McTaggart on behalf of School of Engineering