Solution-based adaptive mesh redistribution applied to harmonic balance solvers

Solution-based adaptive mesh redistribution applied to harmonic balance solvers

A primary source of inaccuracy in numerical simulations is due to errors that are introduced into the solution via the discretization of the continuous governing equations over the computational domain. By increasing the grid resolution in regions with high flow gradients and large curvatures using...

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Bibliographic Details
Published in:Aerospace science and technology Vol. 84; pp. 543 - 564
Main Authors: Djeddi, Reza, Ekici, Kivanc
Format: Journal Article
Language:English
Published: Elsevier Masson SAS 01-01-2019
Subjects:
Adaptive grid
Adaptive mesh redistribution (AMR)
Computational fluid dynamics (CFD)
Harmonic balance
r-Adaptive refinement
Time-spectral
Time-spectral
Adaptive grid
r-Adaptive refinement
Harmonic balance
Computational fluid dynamics (CFD)
Adaptive mesh redistribution (AMR)
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Summary:A primary source of inaccuracy in numerical simulations is due to errors that are introduced into the solution via the discretization of the continuous governing equations over the computational domain. By increasing the grid resolution in regions with high flow gradients and large curvatures using a solution-adaptive approach, these discretization errors can be reduced. In this paper, an adaptive mesh technique is presented that can efficiently cluster the grid nodes in sensitive regions by redistribution and relocation of the grid nodes. This adaptive technique is specifically important to unsteady periodic flow cases where the length scales of the flow features (such as shocks, boundary layer, and separation zones) can differ between time instances. The proposed technique is developed – for the first time in the literature – for a harmonic balance method to efficiently model unsteady periodic flows. To study the performance of the proposed technique in improving the accuracy of the flow solver, steady and unsteady flow cases are studied. Numerical results show that the adaptive mesh redistribution technique is capable of efficiently increasing the accuracy of the numerical solver with a relatively low computational overhead.
ISSN:1270-9638
1626-3219
DOI:10.1016/j.ast.2018.11.003