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High Order Wall-Modeled Large-Eddy Simulation on Mixed Unstructured Meshes

Z.J. Wang

2022AIAA Journal15 citationsDOI

Abstract

In the present study, an algebraic equilibrium wall model previously developed for hexahedral elements is extended to handle mixed meshes including prismatic, tetrahedral, and pyramidal elements in the context of a discontinuous high-order method. This extension is needed for complex geometries, for which high-order mixed elements (e.g., tetrahedral and pyramidal elements) are often necessary near solid walls to avoid meshing challenges. Various design decisions are discussed to achieve the best performance on massively parallel CPU/GPU architectures for a production-level high-order large-eddy simulation solver based on the flux reconstruction/correction procedure via reconstruction method, hpMusic. The extension to other elements is first evaluated using a benchmark channel flow problem at various Reynolds numbers. After that, flow over the NASA high-lift Common Research Model (CRM-HL) from the 4th AIAA High-lift Prediction Workshop is computed to further test the new implementation. Computational results at the third- and fourth-order accuracies are compared with experimental data.

Topics & Concepts

Polygon meshHexahedronComputational scienceTetrahedronComputer scienceReynolds-averaged Navier–Stokes equationsLarge eddy simulationContext (archaeology)SolverMassively parallelComputational fluid dynamicsParallel computingGeometryMechanicsFinite element methodTurbulenceStructural engineeringEngineeringMathematicsPhysicsGeologyComputer graphics (images)PaleontologyProgramming languageFluid Dynamics and Turbulent FlowsComputational Fluid Dynamics and AerodynamicsGas Dynamics and Kinetic Theory
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