Large-eddy simulation and modeling of Taylor-Couette flow with an outer stationary cylinder

Abstract

We present wall-resolved large-eddy simulations (LES) of the incompressible Navier-Stokes equations together with empirical modeling for turbulent Taylor-Couette (TC) flow where the inner cylinder is rotating with angular velocity i and the outer cylinder is stationary. A simple empirical model of the turbulent, TC flow is developed consisting of near-wall, log-like turbulent wall layers separated by an annulus of constant angular momentum. The model is closed by a proposed scaling relation concerning the thickness of the wall layer on the inner cylinder. Model results include the Nusselt number Nu (torque required to maintain the flow) and various measures of the wall-layer thickness as a function of both the Taylor number Ta and η. These agree reasonably with experimental measurements, direct numerical simulation (DNS) and the present LES over a range of both Ta and η. In particular, the model shows that, at fixed η<1, Nu grows like Ta1/2 divided by the square of the Lambert, (or Product-Log) function of a variable proportional to Ta1/4. This cannot be represented by a power law dependence on Ta. At the same time the wall-layer thicknesses reduce slowly in relation to the cylinder gap. This suggests an asymptotic, very large Ta state consisting of constant angular momentum in the cylinder gap with uθ = 0.5\,i\,Ri2/r, where r is the radius, with vanishingly thin turbulent wall layers at the cylinder surfaces. An extension of the model to rough-wall turbulent wall flow at the inner cylinder surface is described. This shows an asymptotic, fully rough-wall state where the torque is independent of Rei/Ta, and where Nu Ta1/2.