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Autori principali: Ruggeri, Matteo, Sousa, Victor C. B., Scalo, Carlo
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2402.19354
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author Ruggeri, Matteo
Sousa, Victor C. B.
Scalo, Carlo
author_facet Ruggeri, Matteo
Sousa, Victor C. B.
Scalo, Carlo
contents A new combined sub-filter scale turbulence and shock-capturing model is developed for high-order finite volume numerics, extending previous work to unstructured solvers. Block Spectral Stresses (BSS) method relies on the spectra of the velocity gradients to estimate the subfilter scale stresses, heat-flux, and pressure-work based on the resolved field. The method is able to capture shocks with numerical order up to 25 and in a shock-vortex interaction simulation is able to capture the shock and not interfere with the vortex structure. In turbulence calculations the new method is compared with Smagorinsky, dynamic Smagorinsky, and Vreman methods adapted to a block spectral code. In the simulations of homogeneous isotropic turbulence, the new model is worse than the others when on coarse meshes and better on finer ones. Instead, for supersonic and hypersonic channel flow the case is the opposite because as expected the sub-filter terms are mostly depend on the numerical order and not the mesh resolution.
format Preprint
id arxiv_https___arxiv_org_abs_2402_19354
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Block Spectral Stresses (BSS) estimation for shock-capturing and turbulent modeling
Ruggeri, Matteo
Sousa, Victor C. B.
Scalo, Carlo
Fluid Dynamics
A new combined sub-filter scale turbulence and shock-capturing model is developed for high-order finite volume numerics, extending previous work to unstructured solvers. Block Spectral Stresses (BSS) method relies on the spectra of the velocity gradients to estimate the subfilter scale stresses, heat-flux, and pressure-work based on the resolved field. The method is able to capture shocks with numerical order up to 25 and in a shock-vortex interaction simulation is able to capture the shock and not interfere with the vortex structure. In turbulence calculations the new method is compared with Smagorinsky, dynamic Smagorinsky, and Vreman methods adapted to a block spectral code. In the simulations of homogeneous isotropic turbulence, the new model is worse than the others when on coarse meshes and better on finer ones. Instead, for supersonic and hypersonic channel flow the case is the opposite because as expected the sub-filter terms are mostly depend on the numerical order and not the mesh resolution.
title Block Spectral Stresses (BSS) estimation for shock-capturing and turbulent modeling
topic Fluid Dynamics
url https://arxiv.org/abs/2402.19354