2134/9901160.v1 Shota Akaotsu Shota Akaotsu Ryoma Ozawa Ryoma Ozawa Yohsuke Matsushita Yohsuke Matsushita Hideyuki Aoki Hideyuki Aoki Weeratunge Malalasekera Weeratunge Malalasekera Effects of infinitely fast chemistry on combustion behavior of coaxial diffusion flame predicted by large eddy simulation Loughborough University 2019 Large eddy simulation Combustion Eddy break up model Flamelet/progress variable model Flame structure 2019-09-26 09:36:49 Journal contribution https://repository.lboro.ac.uk/articles/journal_contribution/Effects_of_infinitely_fast_chemistry_on_combustion_behavior_of_coaxial_diffusion_flame_predicted_by_large_eddy_simulation/9901160 Large eddy simulations (LES) based on turbulent combustion models aid the design and optimization of combustors. Of the various combustion models available, the eddy break up (EBU) model is widely used because it assumes an infinitely fast chemistry. However, omitting the actual chemical kinetics can cause unexpected behavior, and the characteristics of the combustion models need to be elucidated. Here, the effects of an infinitely fast chemistry on the combustion behavior of a coaxial diffusion flame as predicted by an LES were analyzed. Although the EBU model captured the overall behavior of the chemical species as well as the flow field, the gas temperature and mass fractions of the combustion products in the mixing region of the fuel and oxidizer streams were overestimated. In contrast, the flamelet/progress variable (FPV) model yielded results that were in better agreement with the experimental data, because while the EBU model assumes an infinitely fast chemistry, the look-up tables used in the FPV model are based on the actual chemical kinetics. As these models can be used for the CFD simulations of coal and spray combustion, the results of this study should be useful for efficiently simulating practical combustion systems.