Dominant features in three-dimensional turbulence structure: comparison of non-uniform accelerating and decelerating flows

Pu, Jaan H., Tait, Simon J., Guo, Yakun, Huang, Y., Hanmaiahgari, P.R.

06 November 2017

Yes / The results are presented from an experimental study to investigate three-dimensional turbulence structure profiles, including turbulence intensity and Reynolds stress, of different non-uniform open channel flows over smooth bed in subcritical flow regime. In the analysis, the uniform flow profiles have been used to compare with those of the non-uniform flows to investigate their time-averaged spatial flow turbulence structure characteristics. The measured non-uniform velocity profiles are used to verify the von Karman constant κ and to estimate sets of log-law integration constant Br and wake parameter П, where their findings are also compared with values from previous studies. From κ, Br and П findings, it has been found that the log-wake law can sufficiently represent the non-uniform flow in its non-modified form, and all κ, Br and П follow universal rules for different bed roughness conditions. The non-uniform flow experiments also show that both the turbulence intensity and Reynolds stress are governed well by exponential pressure gradient parameter β equations. Their exponential constants are described by quadratic functions in the investigated β range. Through this experimental study, it has been observed that the decelerating flow shows higher empirical constants, in both the turbulence intensity and Reynolds stress compared to the accelerating flow. The decelerating flow also has stronger dominance to determine the flow non-uniformity, because it presents higher Reynolds stress profile than uniform flow, whereas the accelerating flow does not. / Major State Basic Research Development Grant No. 2013CB036402.

アスペクト比が小さい場合のテイラー渦流れ (時間発展力学系におけるモード形成と分岐)

古川, 裕之, FURUKAWA, Hiroyuki, 渡辺, 崇, WATANABE, Takashi, 戸谷, 順信, TOYA, Yorinobu, 中村, 育雄, NAKAMURA, Ikuo

03 1900

No description available.

Computational Fluid Dynamics

Stability

Fluid Transients

Taylor Vortex Flow

Nonlinear Dynamics

Small Aspect Ratio

Decelerating Flow

Mode Exchange

Bifurcation