Prediction of complex aerodynamic flows with explicit algebraic stress models | Zendy

Ridha Abid | Zendy; Joseph Morrison | Zendy; Thomas B. Gatski | Zendy; Charles G. Speziale | Zendy

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Prediction of complex aerodynamic flows with explicit algebraic stress models

Author(s) -

Ridha Abid,

Joseph Morrison,

Thomas B. Gatski,

Charles G. Speziale

Publication year - 1996

Publication title -

38th aerospace sciences meeting and exhibit

Language(s) - English

Resource type - Conference proceedings

DOI - 10.2514/6.1996-565

Subject(s) - conservative vector field , aerodynamics , non equilibrium thermodynamics , algebraic number , flow (mathematics) , turbulence , mathematics , algebraic equation , stress (linguistics) , mathematical analysis , mechanics , physics , compressibility , thermodynamics , nonlinear system , linguistics , philosophy , quantum mechanics

An explicit algebraic stress equation, developed by Gatski and Speziale, is used in the framework of K-epsilon formulation to predict complex aerodynamic turbulent flows. The nonequilibrium effects are modeled through coefficients that depend nonlinearly on both rotational and irrotational strains. The proposed model was implemented in the ISAAC Navier-Stokes code. Comparisons with the experimental data are presented which clearly demonstrate that explicit algebraic stress models can predict the correct response to nonequilibrium flow.

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