Title: Second law analysis of a multiport serpentine Micro-Channel Slab Heat Exchanger
Authors: Serena Askar; Amir Fartaj; Engr Sarbadaman Dasgupta; Abdul Quayium
Addresses: Mechanical, Automotive, and Materials Engineering Department (MAME), University of Windsor, Windsor, Ontario N9B 3P4, Canada ' Mechanical, Automotive, and Materials Engineering Department (MAME), University of Windsor, Windsor, Ontario N9B 3P4, Canada ' Mechanical, Automotive, and Materials Engineering Department (MAME), University of Windsor, Windsor, Ontario N9B 3P4, Canada ' Mechanical, Automotive, and Materials Engineering Department (MAME), University of Windsor, Windsor, Ontario N9B 3P4, Canada
Abstract: Second law analysis is recognised as an effective tool to determine the thermodynamic performance of many systems. In the present work, it is used for a steady-state multiport serpentine slab cross-flow Micro-Channel Heat Exchanger (MCHX) to analyse its thermodynamic performance. Micro-scale devices have been widely used due to advancements in micro-scale fabricating technologies. This type of heat exchanger has been known for its higher heat transfer coefficient and higher area per volume ratio. Conservation of energy and the increase in entropy principles were used to create a mathematical model that uses different parameters such as heat capacity rate ratio, fluids inlet temperatures ratio, effectiveness and pressure drop for obtaining the entropy generation. Results were obtained on the basis of the behaviour of the dimensionless entropy generation number with the key parameters. A good agreement between the predicted and the measured results was found.
Keywords: MCHX; microchannel heat exchangers; EGM; entropy generation minimisation; exergy; second law analysis; ethylene glycol; heat transfer; energy conservation; thermodynamics performance; multiport slab heat exchangers; serpentine slab heat exchangers; mathematical modelling.
International Journal of Exergy, 2012 Vol.10 No.4, pp.379 - 399
Received: 17 Jun 2011
Accepted: 11 Oct 2011
Published online: 25 Jun 2012 *