Comparison and modification of turbulence models for active flow separation control over a flat surface

The present work studied various models for predicting turbulence in the problem of injecting a fluid microjet into the boundary layer of a turbulent flow. For this purpose, the one-equation Spalart–Allmaras (SA), two-equation k–ε and k–ω, multi-equation transition k-kL–ω, transition shear stress tr...

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Bibliographic Details
Published in:Physics of fluids (1994) 2023-06, Vol.35 (6)
Main Authors: Pour Razaghi, Mohammad Javad, Rezaei Sani, Seyed Mojtaba, Masoumi, Yasin
Format: Article
Language:English
Subjects:
Active control
Flat surfaces
Flow separation
Fluid dynamics
Fluid flow
Microjets
Performance prediction
Physics
Reynolds number
Reynolds stress
Shear stress
Turbulence models
Turbulent boundary layer
Turbulent flow
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Summary:The present work studied various models for predicting turbulence in the problem of injecting a fluid microjet into the boundary layer of a turbulent flow. For this purpose, the one-equation Spalart–Allmaras (SA), two-equation k–ε and k–ω, multi-equation transition k-kL–ω, transition shear stress transport (SST), and Reynolds stress models were used for solving the steady microjet into the turbulent boundary layer, and their results are compared with experimental results. Comparing the results indicated that the steady solution methods performed sufficiently we for this problem. Furthermore, it was found that the four-equation transition SST model was the most accurate method for predicting turbulence in this problem. This model predicted the velocity along the x-axis in near- and far-jet locations with about 1% and 5% average errors, respectively. It also outperformed the other methods in predicting Reynolds stresses, especially at the center (nearly 5% error). Moreover, the modified four-equation transition SST model has improved the system's performance in predicting the studied parameters by utilizing Sørensen correlations in predicting R e θ t (the transition momentum thickness Reynolds number), F l ength (an empirical correlation that controls the length of the transition region), and R e θ c (the critical Reynolds number where the intermittency first starts to increase in the boundary layer).
ISSN:1070-6631
1089-7666
DOI:10.1063/5.0151815