DocumentCode
355922
Title
Conjugate mixed convection in a cooling duct
Author
Andrade, Cláudia R. ; Zaparoli, Edson L.
Author_Institution
Dept. de Energia, Inst. Tecnologico de Aeronaut., Sao Paulo, Brazil
Volume
1
fYear
2000
fDate
2000
Lastpage
367
Abstract
This work reports a numerical study of the mixed convection in finned duct flow that occurs in heat sinks devices. The laminar flow is considered fully developed and the convection-conduction coupling is treated by a conjugated approach. The mathematical formulation of this problem is constituted by the mass, momentum and energy equations. This partial differential equations system is solved by the Galerkin finite element method, adopting a pressure Poisson equation to establish the pressure-velocity coupling and to obtain a mass conserving flow. It was studied the effect of duct aspect ratio on the heat transfer rate and friction coefficient. Also the influence of the fluid to wall conductivity ratio in the Nusselt number results was investigated. This analysis tool was shown appropriate for the optimization of electronic components air-cooled heat sinks
Keywords
Galerkin method; Poisson equation; convection; cooling; finite element analysis; friction; heat conduction; heat sinks; laminar flow; partial differential equations; pipe flow; Galerkin finite element method; Nusselt number; Poisson equation; air cooling; conjugate mixed convection; electronic component; energy equation; finned duct flow; friction coefficient; heat conduction; heat sink; heat transfer; laminar flow; mass equation; momentum equation; optimization; partial differential equation; pressure-velocity coupling; Conductivity; Cooling; Ducts; Finite element methods; Friction; Heat sinks; Heat transfer; Moment methods; Partial differential equations; Poisson equations;
fLanguage
English
Publisher
ieee
Conference_Titel
Thermal and Thermomechanical Phenomena in Electronic Systems, 2000. ITHERM 2000. The Seventh Intersociety Conference on
Conference_Location
Las Vegas, NV
ISSN
1089-9870
Print_ISBN
0-7803-5912-7
Type
conf
DOI
10.1109/ITHERM.2000.866848
Filename
866848
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