This is the second part of a survey summarizing authors’ research over a period of two decades on enhancing impinging jet heat and/or mass transfer by periodic unsteadiness of nozzle flow rate. The first part, Tesař and Trávníček (2004 b), identified the reasons why pulsation does not always improve the transfer rate: the pulses do not reach up to the wall. The authors nevertheless demonstrate a transfer rate improvement, but in flows with inherent instability found in annular impinging jet. The excitation there causes a topological metamorphosis (reversal of flow character). Also in the extreme case of the synthetic (zero time-mean flow) jets the authors demonstrated a substantial improvement with the annular nozzle. The new approaches presented in the paper offer increased performance of drying and heating/cooling systems, in particular in microdevices with otherwise low or absent levels of natural jet turbulence.
[1]
Zdenek Trávnícek,et al.
Increasing heat and/or mass transfer rates in impinging jets
,
2005,
J. Vis..
[2]
V. Tesar.
Fluidic jet-type rectifier: experimental study of generated output pressure
,
1982
.
[3]
V. Tesař,et al.
Dominant vortices in impinging jet flows
,
2002
.
[4]
Z. Trávníček,et al.
Annular impinging jet with recirculation zone expanded by acoustic excitation
,
2004
.
[5]
F. Kremer,et al.
Giant lateral electrostriction in ferroelectric liquid-crystalline elastomers
,
2001,
Nature.
[6]
Václav Tesař,et al.
Annular synthetic jet used for impinging flow mass-transfer
,
2003
.