1 research outputs found
Flow boiling in microchannels: Fundamentals and applications
The rapid advances in performance and miniaturization of electronics and high power devices resulted in
huge heat flux values that need to be dissipated effectively. The average heat flux in computer chips is
expected to reach 2–4.5 MW/m2 with local hot spots 12–45 MW/m2 while in IGBT modules, the heat flux
at the chip level can reach 6.5–50 MW/m2. Flow boiling in microchannels is one of the most promising
cooling methods for these and similar devices due to the capability of achieving very high heat transfer
rates with small variations in the surface temperature. However, several fundamental issues are still not
understood and this hinders the transition from laboratory research to commercial applications. The present
paper starts with a discussion of the possible applications of flow boiling in microchannels in order
to highlight the challenges in the thermal management for each application. In this part, the different
integrated systems using microchannels were also compared. The comparison demonstrated that miniature
cooling systems with a liquid pump were found to be more efficient than miniature vapour compression
refrigeration systems. The paper then presents experimental research on flow boiling in single tubes
and rectangular multichannels to discuss the following fundamental issues: (1) the definition of
microchannel, (2) flow patterns and heat transfer mechanisms, (3) flow instability and reversal and their
effect on heat transfer rates, (4) effect of channel surface characteristics and (5) prediction of critical heat
flux. Areas where more research is needed were clearly mentioned. In addition, correlations for the prediction
of the flow pattern transition boundaries and heat transfer coefficients in small to mini/micro diameter tubes were developed recently by the authors and presented in this paper