Fluctuations of the wall shear stress vector in a large-scale natural convection cell

Fluctuations of the wall shear stress vector in a large-scale natural convection cell

We report first experimental data of the wall shear stress in turbulent air flow in a large-scale Rayleigh–Bénard experiment. Using a novel, nature-inspired measurement concept [C. H. Bruecker and V. Mikulich, PLoS One 12, e0179253 (2017)], we measured the mean and fluctuating part of the two compon...

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Bibliographic Details
Published in:AIP advances Vol. 10; no. 7; pp. 075105 - 075105-10
Main Authors: du Puits, R., Bruecker, C.
Format: Journal Article
Language:English
Published: Melville American Institute of Physics 01-07-2020
AIP Publishing LLC
Subjects:
Aerodynamics
Air flow
Angular momentum
Computational fluid dynamics
Convection cells
Free convection
Local flow
Prandtl number
Precession
Shear stress
Skewed distributions
Turbulent flow
Twisting
Wall shear stresses
Weibull distribution
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Summary:We report first experimental data of the wall shear stress in turbulent air flow in a large-scale Rayleigh–Bénard experiment. Using a novel, nature-inspired measurement concept [C. H. Bruecker and V. Mikulich, PLoS One 12, e0179253 (2017)], we measured the mean and fluctuating part of the two components of the wall shear stress vector at the heated bottom plate at a Rayleigh number Ra = 1.58 × 1010 and a Prandtl number Pr = 0.7. The total sampling period of 1.5 h allowed us to capture the dynamics of the magnitude and the orientation of the vector over several orders of characteristic timescales of the large-scale circulation. We found the amplitude of short-term (turbulent) fluctuations to be following a highly skewed Weibull distribution, while the long-term fluctuations are dominated by the modulation effect of a quasi-regular angular precession of the outer flow around a constant mean, the timescale of which is coupled to the characteristic eddy turnover time of the global recirculation roll. Events of instantaneous negative streamwise wall shear occur when rapid twisting of the local flow happens. A mechanical model is used to explain the precession by tilting the spin moment of the large circulation roll and conservation of angular momentum. A slow angular drift of the mean orientation is observed in a phase of considerable weakening of mean wind magnitude.
ISSN:2158-3226
2158-3226
DOI:10.1063/5.0006610