Extension of a hybrid thermal LBE scheme for Large-Eddy simulations of turbulent convective flows

van Treeck, C.; Rank, E.; Krafczyk, M.; Toelke, J.; Nachtwey, B.

van_Treeck:06_3

Autor(en):: van Treeck, C.; Rank, E.; Krafczyk, M.; Toelke, J.; Nachtwey, B.
Titel:: Extension of a hybrid thermal LBE scheme for Large-Eddy simulations of turbulent convective flows
Abstract:: Following the work of Lallemand and Luo [Phys. Rev. E 68, 036706 (2003)] we validate, apply and extend the hybrid thermal lattice Boltzmann scheme (HTLBE) by a large-eddy approach to simulate turbulent convective flows. For the mass and momentum equations, a multiple-relaxation-time LBE scheme is used while the heat equation is solved numerically by a finite difference scheme. We extend the hybrid model by a Smagorinsky subgrid scale model for both the fluid flow and the heat flux. Validation studies are presented for laminar and turbulent natural convection in a cavity at various Rayleigh numbers up to 5·1010 for «
Following the work of Lallemand and Luo [Phys. Rev. E 68, 036706 (2003)] we validate, apply and extend the hybrid thermal lattice Boltzmann scheme (HTLBE) by a large-eddy approach to simulate turbulent convective flows. For the mass and momentum equations, a multiple-relaxation-time LBE scheme is used while the heat equation is solved numerically by a finite difference scheme. We extend the hybrid model by a Smagorinsky subgrid scale model for both the fluid flow and the heat flux. Validation st... »
Stichworte:: Cavity flow, Hybrid thermal model, Lattice Boltzmann, LES, MRT, Nusselt Number, Smagorinsky subgrid model, TLBE, Turbulent natural convection
Zeitschriftentitel:: Elsevier Science (submitted to)
Jahr:: 2006
Seitenangaben Beitrag:: 863-871
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