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ABSTRACT
We report on a parallel study on properties of large-scale vortical structures in low- and high-swirl turbulent jets by means of the time-resolved tomographic particle image velocimetry technique. The high-swirl jet flow is featured by a well-established bubble-type vortex breakdown with a central recirculation zone. In the low-swirl flow, the mean axial velocity, while intermittently acquiring negative values, remains positive in the mean but with a local velocity defect immediately downstream from the nozzle exit, followed by a spiralling vortex core system and its eventual breakdown. Measurements of the 3D velocity fields allowed direct analysis of the azimuthal/helical modes via Fourier transform over the azimuthal angle and proper orthogonal decomposition (POD) analysis in the Fourier space. A precessing vortex core is detected for both swirl cases, whereas the POD analysis showed that the one originating in the bubble-type vortex breakdown is much more energetic and easier to detect.
Acknowledgments
This work was supported by the Russian Science Foundation under Grant No. 14-29-00203 (supervised by Prof. Kemal Hanjalic in NSU). A fruitful discussion with R. Mullyadzhanov on the salient structural differences between the low and high-swirling jets is much appreciated.
Disclosure statement
No potential conflict of interest was reported by the authors.