Angular momentum transport and flow organisation in Taylor-Couette flow at radius ratio of η=0.357

Abstract

We experimentally and numerically investigate the angular momentum transport in turbulent Taylor-Couette flow for independently rotating cylinders at a small radius ratio of η=0.357 for various shear Reynolds numbers (4.5× 103 ≤ ReS ≤ 1.2 × 105) and ratios of angular velocities (-0.5 ≤ μ ≤ 0.2). The momentum transport in terms of the pseudo-Nusselt number Nuω does not show a pure power law scaling with the forcing ReS and features non-constant effective scaling between 1.3× 104 ≤ ReS ≤ 4 × 104. This transition lies in the classical turbulent regime and is caused by the curvature-dependent limited capacity of the outer cylinder to emit small-scale plumes at a sufficient rate to equalize the angular momentum in the bulk. For counter-rotating cylinders, a maximum in the torque occurs at μ=-0.123 0.030. The origin of this maximum can be attributed to a strengthening of turbulent Taylor vortices, which is revealed by the flow visualization technique. In addition, different flow states at μ concerning the wavelength of the large-scale vortices have been detected. The experimental and numerical results for the Nusselt number show a very good agreement.