Author(s): Qigang Chen; Ronald J. Adrian; Qiang Zhong; Danxun Li; Xingkui Wang

Linked Author(s): Ronald J. Adrian, Qiang Zhong, Danxun Li, Xingkui Wang

Keywords: Hairpin vortex; net force; open-channel flow; Reynolds shear stress; spanwise vortex filament; turbulence

Abstract: The dynamic importance of spanwise vorticity and vortex filaments has been assessed in steady, uniform open-channel flows by means of particle image velocimetry. By expressing the net force due to Reynolds’ turbulent shear stress, , in terms of two velocity–vorticity correlations, and , the results show that both spanwise vorticity and the portion of it that is due to spanwise filaments make important contributions to the net force and hence the shape of the mean flow profile. Using the swirling strength to identify spanwise vortex filaments, it is found that they account for about 45% of , the remainder coming from non-filamentary spanwise vorticity, i.e. shear. The mechanism underlying this contribution is the movement of vortex filaments away from the wall. The contribution of spanwise vortex filaments to the Reynolds stress is small because they occupy a small fraction of the flow. The contribution of the induced motion of the spanwise vortex filaments is significant.

DOI: https://doi.org/10.1080/00221686.2014.919965

Year: 2014