LES analysis on soot formation process in a high-boosted diesel engine

Abstract

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In the present study, a mixed timescale subgrid model of large eddy simulation (LES) is applied to simulate detailed mixture formation, combustion and soot formation influenced by turbulence in diesel engine combustion. The combustion model uses the direct integration approach with a fast explicit ODE solver and additionally parallelized by OpenMP. The Diesel oil surrogate mechanism was used which was developed at Chalmers University of Technology, consisting of 74 species and 320 reactions. The soot mass production within a computation cell was determined from a phenomenological soot formation model developed by Waseda University. The model was combined with the LES code mentioned above, including the following important steps: particle inception in which naphthalene grows irreversibly to form soot, surface growth with the addition of C2H2, surface oxidation with OH radical and O2 attack, and particle coagulation. Computational results are compared with experimental data from a high-boosted heavy-duty diesel engine. The predicted soot emissions are compared with experimental data under various EGR conditions. The results show that the in-cylinder pressure and the heat release rate obtained from the engine test are in good agreement with calculation data. In the soot emission calculation, the simulated results show the exponential increases with increasing EGR rate. Furthermore, the steep rise of soot mass increase with increasing EGR rate from 30% EGR is reproduced. The process and spatial distribution of soot formation in a high-boosted heavy duty engine are studied.

Keywords

• heat engine
• diesel combustion
• egr
• surpercharging
• les
• soot formation
• soot paticles