synthetc jet heat transfer particle image velocimetry critical stroke length
Issue Date:
2009
Publisher:
Elsevier
Citation:
Valiorgue, P., Persoons, T., McGuinn, A. and Murray, D.B. ‘Heat transfer mechanisms in an impinging synthetic jet for a small jet-to-surface spacing’ in Experimental and Thermal Fluid Science, 33, 2009, pp 597 - 603
Series/Report no.:
Experimental and Thermal Fluid Science 33
Abstract:
Impinging synthetic jets have been identified as a promising technique for cooling miniature surfaces like
electronic packages. This study investigates the relation between the convective heat transfer characteristics
and the impinging synthetic jet flow structure, for a small jet-to-surface spacing H/D = 2, dimensionless
stroke length 1 < L0/D < 22, and Reynolds number 1000 < Re < 4300. The heat transfer
measurements show evidence for a power law relationship between the Reynolds and Nusselt number
for a constant stroke length. A critical stroke length L0/H = 2:5 has been identified. Using phase-resolved
particle image velocimetry, vortex quantification is applied to elucidate the influence of the impinging
vortex on the time-averaged heat transfer distribution.
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