Transition mechanisms in a boundary layer controlled by rotating wall-normal cylindrical roughness elements

Wu, Yongxiang; Römer, Tristan M.; Axtmann, Gabriel; Rist, Ulrich

doi:10.1017/jfm.2022.546

Cited by 6 publications

(1 citation statement)

References 98 publications

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“…Yet, over the past decade, the time-stepping framework has become increasingly popular and enabled the investigation of the stability properties of fully three-dimensional flows. A large body of works has focused on two configurations, namely the jet in crossflow [13,129,203] or the boundary layer flow past three-dimensional roughness elements [43,46,48,67,145,154,162,276]. The stability of lid-driven and shear-driven three-dimensional cavities with spanwise end-walls has also been investigated in [99,107,143,151,155,205].…”

Section: Introductionmentioning

confidence: 99%

Krylov methods for large-scale dynamical systems: Application in fluid dynamics

Frantz¹,

Loiseau²,

Robinet³

2023

Preprint

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In fluid dynamics, predicting and characterizing bifurcations, from the onset of unsteadiness to the transition to turbulence, is of critical importance for both academic and industrial applications. Different tools from dynamical systems theory can be used for this purpose. In this review, we present a concise theoretical and numerical framework focusing on practical aspects of the computation and stability analyses of steady and time-periodic solutions, with emphasis on high-dimensional systems such as those arising from the spatial discretization of the Navier-Stokes equations. Using a matrix-free approach based on Krylov methods, we extend the capabilities of the open-source high-performance spectral element-based time-stepper Nek5000. The numerical methods discussed are implemented in nekStab, an open-source and user-friendly add-on toolbox dedicated to the study of stability properties of flows in complex three-dimensional geometries. The performance and accuracy of the methods are illustrated and examined using standard benchmarks from the fluid mechanics literature. Thanks to its flexibility and domain-agnostic nature, the methodology presented in this work can be applied to develop similar toolboxes for other solvers, most importantly outside the field of fluid mechanics.

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Section: Introductionmentioning

confidence: 99%

Krylov methods for large-scale dynamical systems: Application in fluid dynamics

Frantz¹,

Loiseau²,

Robinet³

2023

Preprint

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Direct Numerical Simulation of Counter-Rotating Cylindrical Roughness Pairs for Laminar Flow Control

Wu,

Wenzel,

Rist

2023

Notes on Numerical Fluid Mechanics and Multidisciplinary Design

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Delay of laminar–turbulent transition by counter-rotating cylindrical roughness elements in a laminar flat plate boundary layer

Römer

Schulz

et al. 2023

Exp Fluids

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Delaying laminar–turbulent transition in boundary layers is of great interest since the skin-friction coefficient can be reduced by up to one order of magnitude. In this experimental research, it is shown that counter-rotating cylindrical roughness elements are able to delay transition under realistic flow conditions. Evidence is given by the intermittency, evaluated from hot-film measurements in a laminar water channel. An increase in rotation speed results in a delay of transition of up to $${6.5}{\%}$$ 6.5 % in the center of the plate. This trend can be explained by the streaks amplified by the rotating cylinders, resulting in a damping of the fluctuation amplitude in the boundary layer. The advantage of this method is that the transition delay can be actively controlled with conventional cylindrical roughness elements. Graphical abstract

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Transition mechanisms in a boundary layer controlled by rotating wall-normal cylindrical roughness elements

Cited by 6 publications

References 98 publications

Krylov methods for large-scale dynamical systems: Application in fluid dynamics

Krylov methods for large-scale dynamical systems: Application in fluid dynamics

Direct Numerical Simulation of Counter-Rotating Cylindrical Roughness Pairs for Laminar Flow Control

Delay of laminar–turbulent transition by counter-rotating cylindrical roughness elements in a laminar flat plate boundary layer

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