Data-driven prediction of the equivalent sand-grain height in rough-wall turbulent flows

This paper investigates a long-standing question about the effect of surface roughness on turbulent flow: What is the equivalent roughness sand-grain height for a given roughness topography? Deep neural network (DNN) and Gaussian process regression (GPR) machine learning approaches are used to devel...

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Bibliographic Details
Published in:Journal of fluid mechanics 2021, Vol.912, Article A8
Main Authors: Aghaei Jouybari, Mostafa, Yuan, Junlin, Brereton, Giles J., Murillo, Michael S.
Format: Article
Language:English
Subjects:
Artificial neural networks
Computational fluid dynamics
Computer simulation
Decomposition
Direct numerical simulation
Equivalence
Gaussian process
JFM Papers
Learning algorithms
Machine learning
Neural networks
Porosity
Predictions
Reynolds number
Sand
Sea surface
Simulation
Surface roughness
Surface roughness effects
Turbulent flow
Viscosity
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Summary:This paper investigates a long-standing question about the effect of surface roughness on turbulent flow: What is the equivalent roughness sand-grain height for a given roughness topography? Deep neural network (DNN) and Gaussian process regression (GPR) machine learning approaches are used to develop a high-fidelity prediction approach of the Nikuradse equivalent sand-grain height $k_s$ for turbulent flows over a wide variety of different rough surfaces. To this end, 45 surface geometries were generated and the flow over them simulated at ${Re}_\tau =1000$ using direct numerical simulations. These surface geometries differed significantly in moments of surface height fluctuations, effective slope, average inclination, porosity and degree of randomness. Thirty of these surfaces were considered fully rough, and they were supplemented with experimental data for fully rough flows over 15 more surfaces available from previous studies. The DNN and GPR methods predicted $k_s$ with an average error of less than 10 % and a maximum error of less than 30 %, which appears to be significantly more accurate than existing prediction formulae. They also identified the surface porosity and the effective slope of roughness in the spanwise direction as important factors in drag prediction.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2020.1085