Direct numerical simulations of Taylor–Couette turbulence: the effects of sand grain roughness

Berghout, Pieter; Zhu, Xiaojue; Chung, Daniel; Verzicco, Roberto; Stevens, Richard J. A. M.; Lohse, Detlef

doi:10.1017/jfm.2019.376

Cited by 22 publications

(30 citation statements)

References 48 publications

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“…The findings presented in figure 3 show that the presence of the roughness affects the relative turbulence statistics in the bulk of the flow, far away from the roughness sublayer region (in contrast to homogeneous roughness in TC flow (Berghout et al 2018)), reminiscent to what is found in studies of pipe and channel flow (Koeltzsch et al 2002;Chung et al 2018). Figure 3(b) shows the axial variations of the friction factor c f (z) (see section 1) on both the inner cylinder and the outer cylinder.…”

Section: Response Of the Turbulent Taylor Vorticesmentioning

confidence: 95%

Controlling secondary flow in Taylor–Couette turbulence through spanwise-varying roughness

et al. 2019

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Highly turbulent Taylor-Couette flow with spanwise-varying roughness is investigated experimentally and numerically (direct numerical simulations (DNS) with an immersed boundary method (IBM)) to determine the effects of the spacing and axial width s of the spanwise varying roughness on the total drag and on the flow structures. We apply sandgrain roughness, in the form of alternating rough and smooth bands to the inner cylinder. Numerically, the Taylor number is O(10 9 ) and the roughness width is varied between 0.47 s = s/d 1.23, where d is the gap width. Experimentally, we explore Ta = O(10 12 ) and 0.61 s 3.74. For both approaches the radius ratio is fixed at η = r i /r o = 0.716, with r i and r o the radius of the inner and outer cylinder respectively. We present how the global transport properties and the local flow structures depend on the boundary conditions set by the roughness spacings. Both numerically and experimentally, we find a maximum in the angular momentum transport as function ofs. This can be atributed to the re-arrangement of the large-scale structures triggered by the presence of the rough stripes, leading to correspondingly large-scale turbulent vortices.

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Section: Response Of the Turbulent Taylor Vorticesmentioning

confidence: 95%

Controlling secondary flow in Taylor–Couette turbulence through spanwise-varying roughness

et al. 2019

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“…The results from Fig. 3.3 hints that the presence of the roughness might have an effect on the morphology of the flow, far away from the roughness sublayer region [133], on the order of the gap width d, and reminiscent to what is found in studies of pipe and channel flow [115,117]. To gain more insight into how the roughness alters the flow, we set out to measure the velocity field in the meridional plane using PIV at multiple heights.…”

Section: Response Of the Turbulent Taylor Vorticesmentioning

confidence: 83%

“…They attribute this to a dominance of the pressure drag over the viscous drag on the cylinders. Structure in the form of grooves in the streamwise direction were studied by Very recently, [133] studied the influence of sandgrain roughness in TC flow, and found similarity of the roughness function with the same type of roughness in pipe flow [134]. We highlight that none of the works described above, reported an influence of the roughness over the axial wavelength of the rolls.…”

Section: Introductionmentioning

confidence: 89%

“…Having discussed the dynamics of the TTVs and the corresponding global response, in terms of the dimensionless torque, we now set out to study the streamwise, angular, velocity profiles (rather than the azimuthal profiles, as discussed in [140] and [133]). To allow for straightforward comparison between the respective velocity profiles, we run the DNS at constant friction Reynolds number Re τ = 690 ± 10.…”

Section: Velocity Profilesmentioning

confidence: 99%

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Towards boiling Taylor-Couette turbulence

Aparicio¹

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We provide experimental measurements for the effective scaling of the Taylor-Reynolds number within the bulk Re λ,bulk , based on local flow quantities as a function of the driving strength (expressed as the Taylor number Ta), in the ultimate regime of Taylor-Couette flow. The data are obtained through flow velocity field measurements using Particle Image Velocimetry (PIV). We estimate the value of the local dissipation rate ϵ(r) using the scaling of the second order velocity structure functions in the longitudinal and transverse direction within the inertial range-without invoking Taylor's hypothesis. We find an effective scaling of ϵ bulk /(ν 3 d −4) ∼ Ta 1.40 , (corresponding to Nu ω,bulk ∼ Ta 0.40 for the dimensionless local angular velocity transfer), which is nearly the same as for the global energy dissipation rate obtained from both torque measurements (Nu ω ∼ Ta 0.40) and Direct Numerical Simulations (Nu ω ∼ Ta 0.38). The resulting Kolmogorov length scale is then found to scale as η bulk /d ∼ Ta −0.35 and the turbulence intensity as I θ,bulk ∼ Ta −0.061. With both the local dissipation rate and the local fluctuations available we finally find that the Taylor-Reynolds number effectively scales as Re λ,bulk ∼ Ta 0.18 in the present parameter regime of 4.0 × 10 8 < Ta < 9.0 × 10 10 .

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“…They attribute this to a dominance of the pressure drag over the viscous drag on the cylinders. Structure in the form of grooves in the streamwise direction were studied by Very recently, [203] studied the influence of sandgrain roughness in TC flow, and found similarity of the roughness function with the same type of roughness in pipe flow [204]. We highlight that none of the works described above, reported an influence of the roughness over the axial wavelength of the rolls.…”

Section: Introductionmentioning

confidence: 89%

Multi-phase wall-bounded turbulence

Bakhuis¹

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Direct numerical simulations of Taylor–Couette turbulence: the effects of sand grain roughness

Cited by 22 publications

References 48 publications

Controlling secondary flow in Taylor–Couette turbulence through spanwise-varying roughness

Controlling secondary flow in Taylor–Couette turbulence through spanwise-varying roughness

Towards boiling Taylor-Couette turbulence

Multi-phase wall-bounded turbulence

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