期刊
COMBUSTION AND FLAME
卷 238, 期 -, 页码 -出版社
ELSEVIER SCIENCE INC
DOI: 10.1016/j.combustflame.2021.111756
关键词
Multiple mapping conditioning; Large eddy simulation; Supersonic combustion; Lifted flame; Lagrangian particle; Chemical explosive mode analysis
类别
资金
- MOE Tier 1 grant [R-265-0 0 0- 653-114]
- USyd-NUS Partnership Collaboration Award
- National Natural Science Foundation of China [52025062]
The study successfully simulated the multiple features of a supersonic lifted hydrogen jet flame using the MMC-LES approach, accurately predicting flame structure and characteristics. The importance of pressure work and viscous heating in autoignition induction and flame stabilization was highlighted in this research.
The Multiple Mapping Conditioning / Large Eddy Simulation (MMC-LES) approach is used to simulate a supersonic lifted hydrogen jet flame, which features shock-induced autoignition, shock-flame interaction, lifted flame stabilization, and finite-rate chemistry effects. The shocks and expansion waves, shock-reaction interactions and overall flame characteristics are accurately reproduced by the model. Predictions are compared with the detailed experimental data for the mean axial velocity, mean and root-mean-square temperature, species mole fractions, and mixture fraction at various locations. The predicted and experimentally observed flame structures are compared through scatter plots of species mole fractions and temperature against mixture fraction. Unlike most past MMC-LES which has been applied to low-Mach flames, in this supersonic flame case pressure work and viscous heating are included in the stochastic FDF equations. Analysis indicates that the pressure work plays an important role in autoignition induction and flame stabilization, whereas viscous heating is only significant in shear layers (but still negligibly small compared to the pressure work). The evolutions of particle information subject to local gas dynamics are extracted through trajectory analysis on representative fuel and oxidizer particles. The particles intermittently enter the extinction region and may be deviated from the full burning or mixing lines under the effects of shocks, expansion waves and viscous heating. The chemical explosive mode analysis performed on the Lagrangian particles shows that temperature, the H and OH radicals contribute dominantly to CEM respectively in the central fuel jet, fuel-rich and fuel-lean sides. The pronounced particle Damkohler numbers first occur in the fuel jet / coflow shear layer, enhanced at the first shock intersection point and peak around the flame stabilization point.(c) 2021 The Combustion Institute. Published by Elsevier Inc. All rights reserved.
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