Zhenhua Jiang
(, ), Chao Yan
(, ), Jian Yu
(, ), Yao Li
(, )
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Efficient implementation of the \(k-{\sqrt{k}} L\) turbulence model with the discontinuous Galerkin method
We present the approaches to implementing the \(k-{\sqrt{k}} L\) turbulence model within the framework of the high-order discontinuous Galerkin (DG) method. We use the DG discretization to solve the full Reynolds-averaged Navier-Stokes equations. In order to enhance the robustness of approaches, some effective techniques are designed. The HWENO (Hermite weighted essentially non-oscillatory) limiting strategy is adopted for stabilizing the turbulence model variable k. Modifications have been made to the model equation itself by using the auxiliary variable that is always positive. The 2nd-order derivatives of velocities required in computing the von Karman length scale are evaluated in a way to maintain the compactness of DG methods. Numerical results demonstrate that the approaches have achieved the desirable accuracy for both steady and unsteady turbulent simulations.
期刊介绍:
Acta Mechanica Sinica, sponsored by the Chinese Society of Theoretical and Applied Mechanics, promotes scientific exchanges and collaboration among Chinese scientists in China and abroad. It features high quality, original papers in all aspects of mechanics and mechanical sciences.
Not only does the journal explore the classical subdivisions of theoretical and applied mechanics such as solid and fluid mechanics, it also explores recently emerging areas such as biomechanics and nanomechanics. In addition, the journal investigates analytical, computational, and experimental progresses in all areas of mechanics. Lastly, it encourages research in interdisciplinary subjects, serving as a bridge between mechanics and other branches of engineering and the sciences.
In addition to research papers, Acta Mechanica Sinica publishes reviews, notes, experimental techniques, scientific events, and other special topics of interest.
Related subjects » Classical Continuum Physics - Computational Intelligence and Complexity - Mechanics
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