Eddy viscosity modeling around curved boundaries through bifurcation approach and theory of rotating turbulence
A novel approach to curvature effects based on the bifurcation theory and rotation turbulence energy spectrum is implemented to improve the sensitivity of the k−ϵ two-equation turbulence model (Jones-Launder form) to curved surfaces. This is done by accounting for the vorticity tensor, which becomes...
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sg-ntu-dr.10356-1537482021-12-16T06:09:23Z Eddy viscosity modeling around curved boundaries through bifurcation approach and theory of rotating turbulence Toh, Yi Han Ng, Bing Feng School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Concave Surface Curvature Flow A novel approach to curvature effects based on the bifurcation theory and rotation turbulence energy spectrum is implemented to improve the sensitivity of the k−ϵ two-equation turbulence model (Jones-Launder form) to curved surfaces. This is done by accounting for the vorticity tensor, which becomes more significant in curved flows, something that the standard k−ϵ model does not originally consider. This new eddy viscosity model is based on the energy spectrum for a turbulent flow undergoing rotation and is then modeled on the bifurcation diagram in ϵ/Sk−η2/η1 phase space. The approach is demonstrated on three different test cases, 30° two-dimensional curved channel, 90° three-dimensional bend duct, and flow past cylinder, to test for the effects of convex and concave curvatures on turbulence. The results from these test cases are then contrasted against other existing eddy viscosity models as well as experimental data. The proposed approach provides better turbulence predictions along convex or concave surfaces, better memory effects, and are closer to the experimental results. For flow past cylinder, the new eddy viscosity model predicts drag coefficient that is closer to experiments with 8% difference, against 30% difference predicted by standard k−ϵ and Pettersson models. Nanyang Technological University Published version The authors would like to thank Nanyang Technological University for the internal funding 04INS000329C160 and 04INS000453C160. 2021-12-16T06:09:23Z 2021-12-16T06:09:23Z 2021 Journal Article Toh, Y. H. & Ng, B. F. (2021). Eddy viscosity modeling around curved boundaries through bifurcation approach and theory of rotating turbulence. Physics of Fluids, 33(7), 075118-. https://dx.doi.org/10.1063/5.0056680 1070-6631 https://hdl.handle.net/10356/153748 10.1063/5.0056680 2-s2.0-85111062591 7 33 075118 en 04INS000329C160 04INS000453C160 Physics of Fluids © 2021 Author(s). All rights reserved. This paper was published by AIP Publishing in Physics of Fluids and is made available with permission of Author(s). application/pdf |
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Engineering::Mechanical engineering Concave Surface Curvature Flow Toh, Yi Han Ng, Bing Feng Eddy viscosity modeling around curved boundaries through bifurcation approach and theory of rotating turbulence |
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A novel approach to curvature effects based on the bifurcation theory and rotation turbulence energy spectrum is implemented to improve the sensitivity of the k−ϵ two-equation turbulence model (Jones-Launder form) to curved surfaces. This is done by accounting for the vorticity tensor, which becomes more significant in curved flows, something that the standard k−ϵ model does not originally consider. This new eddy viscosity model is based on the energy spectrum for a turbulent flow undergoing rotation and is then modeled on the bifurcation diagram in ϵ/Sk−η2/η1 phase space. The approach is demonstrated on three different test cases, 30° two-dimensional curved channel, 90° three-dimensional bend duct, and flow past cylinder, to test for the effects of convex and concave curvatures on turbulence. The results from these test cases are then contrasted against other existing eddy viscosity models as well as experimental data. The proposed approach provides better turbulence predictions along convex or concave surfaces, better memory effects, and are closer to the experimental results. For flow past cylinder, the new eddy viscosity model predicts drag coefficient that is closer to experiments with 8% difference, against 30% difference predicted by standard k−ϵ and Pettersson models. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Toh, Yi Han Ng, Bing Feng |
| format |
Article |
| author |
Toh, Yi Han Ng, Bing Feng |
| author_sort |
Toh, Yi Han |
| title |
Eddy viscosity modeling around curved boundaries through bifurcation approach and theory of rotating turbulence |
| title_short |
Eddy viscosity modeling around curved boundaries through bifurcation approach and theory of rotating turbulence |
| title_full |
Eddy viscosity modeling around curved boundaries through bifurcation approach and theory of rotating turbulence |
| title_fullStr |
Eddy viscosity modeling around curved boundaries through bifurcation approach and theory of rotating turbulence |
| title_full_unstemmed |
Eddy viscosity modeling around curved boundaries through bifurcation approach and theory of rotating turbulence |
| title_sort |
eddy viscosity modeling around curved boundaries through bifurcation approach and theory of rotating turbulence |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/153748 |
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1720447132988604416 |