Loading...
| Friend's email | |
| Your name | |
| Your email | |
| enter code | |
This page was sent successfuly
Approximate method of determining the optimum cross section of microhannel heat sink
Asgari, O ; Sharif University of Technology | 2010
1381
Viewed
- Type of Document: Article
- DOI: 10.1007/s12206-009-1018-8
- Publisher: 2010
- Abstract:
- Microchannels are at the forefront of today's cooling technologies. They are widely being considered for cooling of electronic devices and in micro heat exchanger systems due to their ease of manufacture. One issue which arises in the use of microchannels is related to the small length scale of the channel or channel cross-section. In this work, the maximum heat transfer and the optimum geometry for a given pressure loss have been calculated for forced convective heat transfer in microchannels of various cross-section having finite volume for laminar flow conditions. Solutions are presented for 10 different channel cross sections: parallel plate channel, circular duct, rectangular channel, elliptical duct, polygonal duct, equilateral triangular duct, isosceles triangular duct, right triangular duct, rhombic duct and trapezoidal duct. The model is only a function of the Prandtl number and the geometrical parameters of the cross-section, i. e., area and perimeter. This solution is performed with two exact and approximate methods. Finally, in addition to comparison and discussion of these two methods, validation of the relationship is provided using results from the open literature. © KSME & Springer 2009
- Keywords:
- Constructal ; Convective heat transfer ; Exact and approximate methods ; Laminar flow ; Microchannels ; Optimization ; Approximate methods ; Channel cross section ; Circular ducts ; Constructal ; Convective heat transfer ; Cooling of electronics ; Cooling technology ; Cross section ; Exact and approximate methods ; Finite volume ; Forced convective heat transfer ; Geometrical parameters ; Isosceles triangular ; Laminar flow conditions ; Length scale ; Maximum heat transfer ; Micro-heat exchangers ; Optimum geometry ; OR channels ; Parallel-plate channels ; Pressure loss ; Rectangular channel ; Approximation theory ; Cooling systems ; Ducts ; Geometry ; Heat convection ; Heat exchangers ; Laminar flow ; Microchannels
- Source: Journal of Mechanical Science and Technology ; Volume 23, Issue 12 , 2010 , Pages 3448-3458 ; 1738494X (ISSN)
- URL: http://link.springer.com/article/10.1007/s12206-009-1018-8