The Impact of Riblet Walls on the Structure of Liquid–Solid Two-Phase Turbulent Flow: Streak Structures and Burst Events

The Impact of Riblet Walls on the Structure of Liquid–Solid Two-Phase Turbulent Flow: Streak Structures and Burst Events

This study employs Particle Image Velocimetry (PIV) technology to investigate the statistical properties and flow structures of the turbulent boundary layer over smooth walls and riblet walls with yaw angles of 0, ±30° in both clear water and liquid–solid two-phase flow fields. The results indicate...

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Bibliographic Details
Main Authors: Yuchen Zhao, Jiao Sun, Nan Jiang, Jingyu Niu, Jinghang Yang, Haoyang Li, Xiaolong Wang, Pengda Yuan
Format: Article
Language:English
Published: MDPI AG 2025-07-01
Series:Applied Sciences
Subjects:
convergent and divergent riblet wall
two-phase flow
particle image velocimetry
turbulent boundary layer
streak structures
burst events
Online Access:https://www.mdpi.com/2076-3417/15/14/7977
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Summary:This study employs Particle Image Velocimetry (PIV) technology to investigate the statistical properties and flow structures of the turbulent boundary layer over smooth walls and riblet walls with yaw angles of 0, ±30° in both clear water and liquid–solid two-phase flow fields. The results indicate that, compared to the smooth wall, streamwise riblet walls and 30° divergent riblet walls can reduce the boundary layer thickness, wall friction force, comprehensive turbulence intensity, and Reynolds stress, with the divergent riblet wall being more effective. In contrast, convergent riblet walls have the opposite effect. The addition of particles leads to an increase in boundary layer thickness and a reduction in wall friction resistance, primarily by reducing turbulence fluctuations and Reynolds stress in the logarithmic region of the turbulent boundary layer. Moreover, the two types of drag-reduction riblet walls can decrease the energy content ratio of near-wall streak structures and suppress their motion in the spanwise direction. Their impact on burst events is mainly characterized by a reduction in the number of ejection events and their contribution to Reynolds shear stress. In comparison, convergent riblet walls have the complete opposite effect and also enhance the intensity of burst events. The addition of particles can fragment streak structures and suppress the intensity and number of burst events, acting similarly on drag-reduction riblet walls and further strengthening their drag reduction characteristics.
ISSN:2076-3417

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