In this work, a Large Eddy Simulation (LES) model was used to simulate the transient premixed flame-vortex interaction, which is the key phenomenon determining dynamics and consequences of gas explosions. In particular, the effect of the grid resolution on the impact of the combustion sub-model was investigated. To this end, LES computations were run, with and without the combustion sub-model, on three non-uniform unstructured grids with cell characteristic length varying in the ranges 2-3. mm, 1-2. mm and 0.5-1. mm. Numerical predictions were compared with literature experimental data. It has been found that the amount of detail explicitly resolved on the finer grid (having a resolution of the same order of magnitude as the laminar flame thickness) is such that, even without the combustion sub-model, the LES results obtained with this grid correctly match the experimental data in both quantitative (flame speed and flow velocity) and qualitative (shape and structure of the flame front) terms. © 2011 Elsevier Ltd.
Large Eddy Simulation of transient premixed flame-vortex interactions in gas explosions / Valeria Di, Sarli; DI BENEDETTO, Almerinda; Russo, Gennaro. - In: CHEMICAL ENGINEERING SCIENCE. - ISSN 0009-2509. - 71:(2012), pp. 539-551. [10.1016/j.ces.2011.11.034]
Large Eddy Simulation of transient premixed flame-vortex interactions in gas explosions
DI BENEDETTO, ALMERINDA;RUSSO, GENNARO
2012
Abstract
In this work, a Large Eddy Simulation (LES) model was used to simulate the transient premixed flame-vortex interaction, which is the key phenomenon determining dynamics and consequences of gas explosions. In particular, the effect of the grid resolution on the impact of the combustion sub-model was investigated. To this end, LES computations were run, with and without the combustion sub-model, on three non-uniform unstructured grids with cell characteristic length varying in the ranges 2-3. mm, 1-2. mm and 0.5-1. mm. Numerical predictions were compared with literature experimental data. It has been found that the amount of detail explicitly resolved on the finer grid (having a resolution of the same order of magnitude as the laminar flame thickness) is such that, even without the combustion sub-model, the LES results obtained with this grid correctly match the experimental data in both quantitative (flame speed and flow velocity) and qualitative (shape and structure of the flame front) terms. © 2011 Elsevier Ltd.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.