THERMAL-FLUID ANALYSIS AND OPTIMIZATION OF MICRO-SCALE HEAT SINKS WITH SLIP BOUNDARY CONDITION USING ENTROPY GENERATION MINIMIZATION METHOD Conference Paper

abstract

• Abstract Performance of a micro-scale heat sink with slip boundary condition at walls is evaluated using entropy generation minimization (EGM) approach. Optimum geometrical parameters and working conditions are obtained by applying two different constraints of fixed microchannel height and constant maximum pressure drop. It has been observed that with fixed channel height constraint, the optimum aspect ratio and Reynolds number are 2.5 and 700, respectively. Slip boundary condition has negligible effect on optimum working parameters while it enhances the thermal performance of the heat sink by almost 4% at fixed height constraint. At maximum pressure drop constraint, the optimum working parameters are aspect ratio of 2.25 and Reynolds number of 850. Slip on the microchannel walls reduces pressure drop and enhances the thermal performance of the heat sink by 11%.

name of conference

• Volume 1: Fluid Applications and Systems; Fluid Measurement and Instrumentation

authors

• Fathi, Nima

published proceedings

• PROCEEDINGS OF THE ASME 2020 FLUIDS ENGINEERING DIVISION SUMMER MEETING (FEDSM2020), VOL 1

author list (cited authors)

• Pourghasemi, M., Fathi, N., & Anderson, K. R.

citation count

• 0

complete list of authors

• Pourghasemi, Mahyar||Fathi, Nima||Anderson, Kevin R

publication date

• July 2020

publisher

• ASME International  Publisher

published in

• Proceedings of the ASME Fluids Engineering Division Summer Meeting  Journal

keywords

• Entropy Generation
• Heat Transfer
• Micro-scale Heat Sink
• Slip

Digital Object Identifier (DOI)

• 10.1115/fedsm2020-20478

URL

• http://dx.doi.org/10.1115/fedsm2020-20478