Research output: Contribution to journal › Article › peer-review
Flow dynamics of an axisymmetric impinging jet under two-frequency external forcing. A study by time-resolved PIV and DMD. / Stroeva, P. S.; Frolova, E. N.; Nichik, M. Y. et al.
In: International Journal of Heat and Fluid Flow, Vol. 103, 109196, 10.2023.Research output: Contribution to journal › Article › peer-review
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TY - JOUR
T1 - Flow dynamics of an axisymmetric impinging jet under two-frequency external forcing. A study by time-resolved PIV and DMD
AU - Stroeva, P. S.
AU - Frolova, E. N.
AU - Nichik, M. Y.
AU - Dulin, V. M.
AU - Markovich, D. M.
N1 - Acknowledgements: The assistance of Dr. M. Tokarev with heat transfer measurements is kindly acknowledged (supported by the Ministry of Science and Higher Education of Russia, agreement No. 075-15-2020-806). The flow measurements were performed in frames of the grant from Russian Science Foundation (No 19-79-30075).
PY - 2023/10
Y1 - 2023/10
N2 - The present paper reports on the experimental study of the dynamics of large-scale vortex structures in an axisymmetric impinging jet forced periodically with amplitude modulation. The velocity field measurements are conducted by the particle image velocimetry method. IR imaging is applied to evaluate the effect of external perturbations on local heat transfer coefficient. The Reynolds number of the jet flow is 12,500 and the distance between the nozzle and flat impingement plate is two nozzle diameters. The amplitude modulation corresponds to two-frequency forcing with a main harmonic (for the Strouhal number 0.5) and different sub-harmonics. To analyze quasi-periodic formation and near-wall merging of primary vortex structures and induced secondary vortices in the near-wall boundary layer, the obtained time-resolved velocity data sets are processed by the dynamic mode decomposition method. It is shown that the amplitude modulation can be efficiently used to attenuate the strength of the forced vortices due to the produced blowing events with different momenta and to control vortices pairing process in the near-wall region. It is also shown that two-frequency forcing can provide slightly greater intensification of heat transfer around the stagnation point with considerably smaller energy, consumed during the forcing.
AB - The present paper reports on the experimental study of the dynamics of large-scale vortex structures in an axisymmetric impinging jet forced periodically with amplitude modulation. The velocity field measurements are conducted by the particle image velocimetry method. IR imaging is applied to evaluate the effect of external perturbations on local heat transfer coefficient. The Reynolds number of the jet flow is 12,500 and the distance between the nozzle and flat impingement plate is two nozzle diameters. The amplitude modulation corresponds to two-frequency forcing with a main harmonic (for the Strouhal number 0.5) and different sub-harmonics. To analyze quasi-periodic formation and near-wall merging of primary vortex structures and induced secondary vortices in the near-wall boundary layer, the obtained time-resolved velocity data sets are processed by the dynamic mode decomposition method. It is shown that the amplitude modulation can be efficiently used to attenuate the strength of the forced vortices due to the produced blowing events with different momenta and to control vortices pairing process in the near-wall region. It is also shown that two-frequency forcing can provide slightly greater intensification of heat transfer around the stagnation point with considerably smaller energy, consumed during the forcing.
KW - Dynamic mode decomposition
KW - Heat transfer
KW - IR imaging
KW - Impinging jet
KW - Particle image velocimetry
KW - Periodic forcing
KW - Two-frequency forcing
KW - Vortex dynamics
UR - https://www.scopus.com/record/display.uri?eid=2-s2.0-85164987413&origin=inward&txGid=32626d6686fb193be3a646c38a4b51da
UR - https://www.mendeley.com/catalogue/2ebca2e6-d6c1-3020-abbe-75b3cf52d50a/
U2 - 10.1016/j.ijheatfluidflow.2023.109196
DO - 10.1016/j.ijheatfluidflow.2023.109196
M3 - Article
VL - 103
JO - International Journal of Heat and Fluid Flow
JF - International Journal of Heat and Fluid Flow
SN - 0142-727X
M1 - 109196
ER -
ID: 53971525