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Unstructured Grid Adaptation and Solver Technology for Turbulent Flows

Abstract : Unstructured grid adaptation is a tool to control Computational Fluid Dynamics (CFD) discretization error. However, adaptive grid techniques have made limited impact on production analysis workflows where the control of discretization error is critical to obtaining reliable simulation results. Issues that prevent the use of adaptive grid methods are identified by applying unstructured grid adaptation methods to a series of benchmark cases. Once identified, these challenges to existing adaptive workflows can be addressed. Unstructured grid adaptation is evaluated for test cases described on the Turbulence Modeling Resource (TMR) web site, which documents uniform grid refinement of multiple schemes. The cases are turbulent flow over a Hemisphere Cylinder and an ONERA M6 Wing. Adaptive grid force and moment trajectories are shown for three integrated grid adaptation processes with Mach interpolation control and output error based metrics. The integrated grid adaptation process with a finite element (FE) discretization produced results consistent with uniform grid refinement of fixed grids. The integrated grid adaptation processes with finite volume schemes were slower to converge to the reference solution than the FE method. Metric conformity is documented ongrid/metric snapshots for five grid adaptation mechanics implementations. These tools produce anisotropic boundary conforming grids requested by the adaptation process.
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https://hal.inria.fr/hal-01962247
Contributor : Adrien Loseille <>
Submitted on : Thursday, December 20, 2018 - 2:52:16 PM
Last modification on : Thursday, March 11, 2021 - 9:42:02 PM

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  • HAL Id : hal-01962247, version 1

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Michael Park, Nicolas Barral, Daniel Ibanez, Dmitry Kamenetskiy, Joshua Krakos, et al.. Unstructured Grid Adaptation and Solver Technology for Turbulent Flows. 2018 AIAA Aerospace Sciences Meeting, Jan 2018, Kissimmee, United States. ⟨hal-01962247⟩

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