Coupling tabulated chemistry with compressible CFD solvers

This work focuses on the coupling between tabulated chemistry techniques with compressible solvers. In low Mach-number CFD solvers the coupling is straightforward because thermo-chemical quantities are directly read in a thermo-chemical database. However, because of perturbations introduced by acous...

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Veröffentlicht in:	Proceeding of the combustion Institute 2011, Vol.33 (1), p.1481-1488
Hauptverfasser:	Vicquelin, R., Fiorina, B., Payet, S., Darabiha, N., Gicquel, O.
Format:	Artikel
Sprache:	eng
Schlagworte:	Boundary conditions Characteristic boundary conditions Compressible flow Computational fluid dynamics Computer simulation Engineering Sciences Fluid mechanics Fluids mechanics Joining Mathematical analysis Mathematical models Mechanics Navier-Stokes equations Physics Reactive fluid environment Solvers Tabulated chemistry
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container_title	Proceeding of the combustion Institute
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creator	Vicquelin, R. Fiorina, B. Payet, S. Darabiha, N. Gicquel, O.
description	This work focuses on the coupling between tabulated chemistry techniques with compressible solvers. In low Mach-number CFD solvers the coupling is straightforward because thermo-chemical quantities are directly read in a thermo-chemical database. However, because of perturbations introduced by acoustics, the coupling with fully compressible Navier–Stokes equations is not straightforward. In order to be consistent with tabulated chemistry framework, a new strategy to predict temperature field from the transported energy is developed. Boundary conditions are reformulated following Navier–Stokes Characteristic Boundary Conditions (NSCBC) formalism. The method called TTC (Tabulated Thermo-chemistry for Compressible flows) is implemented in a compressible CFD code and validated by comparison with multi-component simulations. Temperature computation and characteristic boundary conditions reformulations are first validated on one-dimensional tests. A three-dimensional non-reactive case is then computed by performing a large eddy simulation of a turbulent round jet. Finally, a one-dimensional laminar flame simulation assesses the method performances.
doi_str_mv	10.1016/j.proci.2010.05.036
format	Article
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subjects	Boundary conditions Characteristic boundary conditions Compressible flow Computational fluid dynamics Computer simulation Engineering Sciences Fluid mechanics Fluids mechanics Joining Mathematical analysis Mathematical models Mechanics Navier-Stokes equations Physics Reactive fluid environment Solvers Tabulated chemistry
title	Coupling tabulated chemistry with compressible CFD solvers
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