Abstract:
Technological advancements to improve flow and heat
transfer characteristics in many processes are of great interest.
Many high performance systems demand simultaneously the
compactness, efficiency and control of heat transfer. In this
view, a new concept of micro heat exchanger was proposed for
the cooling of electronics devices for which the quality of heat
exchange between wall and fluid as well as pumping effect are
very critical. In the present work, the ability of a liquid heat
exchanger involving a dynamic deformation of one of its walls
to cool a microprocessor is investigated. For that purpose, 3-D
numerical simulations were performed using commercial
software based on the finite volume element in transient
regime. Effect of geometrical and actuation parameters has
been explored and the ability of such heat exchanger to
simultaneously pump the fluid and enhance the heat transfer
has been demonstrated. Based on these numerical results, a
physical prototype has been designed and realized. First
experimental results on the pumping capacity of this prototype
have been compared with numerical results. The good
agreement obtained allows validating the numerical procedure
and thus to be confident in the numerical parametric study
presented.
Description:
Papers presented at the 13th International Conference on Heat Transfer, Fluid Mechanics and Thermodynamics, Portoroz, Slovenia on 17-19 July 2017 .