Large-eddy simulation of n-dodecane spray flame: Effects of nozzle diameters on autoignition at varying ambient temperatures

In the present study, large-eddy simulations (LES) are used to identify the underlying mechanism that governs the ignition phenomena of spray flames from different nozzle diameters when the ambient temperature ( T am ) varies. Two nozzle sizes of 90 mu m and 186 mu m are chosen. They correspond to the nozzle sizes used by Spray A and Spray D, respectively, in the Engine Combustion Network. LES studies of both nozzles are performed at three T am of 800K, 900K, and 1000K. The numerical models are validated using the experimental liquid and vapor penetration, mixture fraction ( Z ) distribution, as well as ignition delay time (IDT). The ignition characteristics of both Spray A and Spray D are well predicted, with a maximum relative difference of 14% as compared to the experiments. The simulations also predict the annular ignition sites for Spray D at T am >= 900K, which is consistent with the experimental observation. It is found that the mixture with Z >= 0.2 at the spray periphery is more favorable for ignition to occur than the overly fuel-rich mixture of Z > 0.2 formed in the core of spray. This leads to the annular ignition sites at higher T am . Significantly longer IDT for Spray D is obtained at T am of 800K due to higher scalar dissipation rates ( chi) during high temperature (HT) ignition. The maximum chi during HT ignition for Spray D is larger than that in Spray A by approximately a factor of 5. In contrast, at T am = 1000 K, the chi values are similar between Spray A and Spray D. This elucidates the increase in the difference of IDT between Spray D and Spray A as T am decreases. This may explain the contradicting findings on the effects of nozzle diameters on IDT from literature. (c) 2020 The Combustion Institute. Published by Elsevier Inc. All rights reserved.

Automated summary

In this study, large-eddy simulations were used to investigate the ignition mechanisms of spray flames with different nozzle diameters at varying ambient temperatures. The simulations predicted that a mixture with Z >= 0.2 at the spray periphery is more favorable for ignition to occur. Additionally, the results showed that the difference in ignition delay time between sprays with different nozzle diameters increases as ambient temperature decreases, potentially explaining conflicting findings in the literature.