Lattice-Boltzmann modeling of the quiet and unstable PRECCINSTA burner modes

Recent studies have shown that Lattice-Boltzmann methods are indeed very promising in the field of reactive flows. More work is required, however, to demonstrate its ability to tackle complex reacting cases, as no study – to the authors’ knowledge – involves simultaneously high Reynolds flows (for w...

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Bibliographic Details
Published in:Computers & fluids 2023-06, Vol.260, p.105898, Article 105898
Main Authors: Zhao, Song, Bhairapurada, Karthik, Tayyab, Muhammad, Mercier, Renaud, Boivin, Pierre
Format: Article
Language:English
Subjects:
Combustion instabilities
Fluid mechanics
Lattice-Boltzmann methods
LBM
Mechanics
Physics
PRECCINSTA
TFLES
Turbulent combustion
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Summary:Recent studies have shown that Lattice-Boltzmann methods are indeed very promising in the field of reactive flows. More work is required, however, to demonstrate its ability to tackle complex reacting cases, as no study – to the authors’ knowledge – involves simultaneously high Reynolds flows (for which the collision kernel needs specific care), complex geometries (for which models are required at the wall boundaries), and non-uniform grids (where non-conform meshes need to be addressed). The present study intends to fill that gap, by investigating the well-known PRECCINSTA burner, including (i) characteristic boundary conditions, (ii) classical turbulent combustion modeling, (iii) multi-level grid refinements. Combining these elements, numerical simulations of the PRECCINSTA burner are carried out, both for the quiet (φ=0.83) and unstable regimes (φ=0.7). In both regimes, results are consistent with those obtained with classical (Navier–Stokes) solvers, but at a much lower cost. In particular, it is the first time that successful prediction of thermoacoustic instabilities in a complex burner is shown in the framework of Lattice-Boltzmann methods. •Lattice-Boltzmann large eddy simulations of the Preccinsta burner are presented.•Results are in line with the literature for both the quiet and unstable configurations.•The study is the first thermoacoustic study of a complex burner using LBM.
ISSN:0045-7930
1879-0747
DOI:10.1016/j.compfluid.2023.105898