Assessment of Two Streamline Curvature Correction Methods for an Elliptic Blending Turbulence Model

Using two different methods, a previously developed elliptic blending model (the original STT k-ω-φ-α model) is modified for sensitization to streamline curvature. One method involves modifying the dissipation term in the turbulent dissipation equation, while the other constructs a new formulation f...

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Bibliographic Details
Published in:Applied sciences 2022-08, Vol.12 (15), p.7899
Main Authors: Yang, Xianglong, Liao, Zhenhao, Yang, Lei
Format: Article
Language:English
Subjects:
Blending
Curvature
curved boundary
Direct numerical simulation
Dissipation
elliptic blending
Energy
Kinetic energy
Large eddy simulation
Mathematical models
Serpentine
Shear strain
streamline curvature correction
turbulence model
Turbulence models
Two dimensional flow
Viscosity
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Summary:Using two different methods, a previously developed elliptic blending model (the original STT k-ω-φ-α model) is modified for sensitization to streamline curvature. One method involves modifying the dissipation term in the turbulent dissipation equation, while the other constructs a new formulation for the turbulent kinetic energy production term based on an explicit algebraic stress model. The capabilities of the proposed models are evaluated by applying them to three flows with curved surfaces; namely, the two-dimensional (2D) infinite serpentine passage flow, the 2D U-turn duct flow, and the 2D periodic hill flow. The STT k-ω model with rotation and curvature correction (the STT k-ω-CC model) is also used for comparison. The computed results are compared with the relevant direct numerical simulation, experimental, and large eddy simulation data from the literature. It is found that the two proposed models significantly improve upon the original STT k-ω-φ-α model. Compared with the STT k-ω-CC model, the two proposed models produce better results in the 2D infinite serpentine passage flow and the 2D periodic hill flow. The proposed models are similarly competitive with the STT k-ω-CC model in the 2D U-turn duct flow.
ISSN:2076-3417
2076-3417
DOI:10.3390/app12157899