Weijie Zhang, Quan Zhou, Jinhua Wang, Zuohua Huang
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Effects of artificial flame front thickening on intermediate minor species prediction using the LES–FGM method
Two stratified premixed Cambridge/Sandia flames SwB1 and SwB9 are modelled using the Flamelet-Generated Manifold in the context of Large-eddy Simulation. Two kinds of sub-grid closure models are adopted and systematically compared, that is, the Dynamically Thickened Flame (DTF) and the Presumed Probable Density Function (PPDF) models, in order to study the effects of artificial flame front thickening introduced by the DTF on the intermediate minor species prediction. It is found that the two methods lead to similar modelling of velocity, temperature, mixture fraction and major species (e.g. CH , O , CO and H O). However, the intermediate minor species CO and H can be over-predicted using the DTF model compared to the PPDF. A correction method proposed recently by Gruhlke et al. is validated in this work to improve the CO/H predictions of DTF. The corrected CO/H mass fractions are nearly consistent with the results of PPDF. It is examined that the Gruhlke-correction performs better if the wrinkling factor is used directly without modification. Meanwhile, the correction exhibits similar good performance with different level of flame front thickening and mixture stratification. The correction is also addressed to correct the species only in the flame front. The results are significant in high-fidelity simulation of intermediate species using the DTF model.
期刊介绍:
Combustion Theory and Modelling is a leading international journal devoted to the application of mathematical modelling, numerical simulation and experimental techniques to the study of combustion. Articles can cover a wide range of topics, such as: premixed laminar flames, laminar diffusion flames, turbulent combustion, fires, chemical kinetics, pollutant formation, microgravity, materials synthesis, chemical vapour deposition, catalysis, droplet and spray combustion, detonation dynamics, thermal explosions, ignition, energetic materials and propellants, burners and engine combustion. A diverse spectrum of mathematical methods may also be used, including large scale numerical simulation, hybrid computational schemes, front tracking, adaptive mesh refinement, optimized parallel computation, asymptotic methods and singular perturbation techniques, bifurcation theory, optimization methods, dynamical systems theory, cellular automata and discrete methods and probabilistic and statistical methods. Experimental studies that employ intrusive or nonintrusive diagnostics and are published in the Journal should be closely related to theoretical issues, by highlighting fundamental theoretical questions or by providing a sound basis for comparison with theory.
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