ABSTRACT
The effect of wall temperature on the ignition of vapor-phase spray impingement has been studied extensively, but the mechanism of the liquid-phase case is not clear. Thus, the visualization experiment was conducted at wall temperatures of 363–673 K using Mie-scattering, shadowgraph, and direct photography methods in a constant volume combustion vessel. The results reveal that, compared with the vapor-phase wetting-wall, when the liquid fuel impinges on the cold wall, the threshold temperature of the autoignition increases greatly to 363 K. Furthermore, the wall temperature strongly affects the evaporation and fuel-air mixing under the liquid impingement case. As the wall temperature increases from 423 K to 573 K, the enhanced evaporation results in a significant reduction in the spray radius, height, and area. However, the evaporation is inhibited and the spray parameters increase when the wall temperature further rises to 623–673 K. This characteristic may be caused by the Leidenfrost effect, which is the main difference from the vapor-phase impingement. Too low wall temperature (below 520 K) easily leads to misfire and unstable ignition, and the threshold temperature of the autoignition is greatly increased, while a higher wall temperature exceeding the Leidenfrost temperature is also not conducive to rapid and stable ignition. With the increase of wall temperature, the ignition delay first shortens from 4.1 ms to 3.2 ms gradually and then prolongs to 3.6 ms again, while the flame area and intensity first increase and then decrease, and the transition temperature is 573 K. When liquid wetting-wall inevitably appears in a heavy-duty diesel engine operating at low temperatures, it is necessary to raise the wall temperature moderately to ensure stable ignition. However, it should not exceed the Leidenfrost temperature, otherwise, evaporation will slow down and ignition will worsen due to the Leidenfrost effect.
Highlights
Liquid fuel impingement and ignition at different wall temperatures are studied.
Evaporation varies with wall temperature non-monotonically due to Leidenfrost.
Moderate increase in wall temperature improves evaporation and ignition.
Too high wall temperature is not conducive to fast and stable ignition.
Ignition threshold greatly increases at liquid wetting compared to vapor-phase.
Acknowledgments
This material is based upon work supported by the National Science Foundation under Grant No. 51806014. Any opinions, findings, and conclusions or recommendations expressed in this publication are those of the authors and do not necessarily reflect the views of the National Science Foundation. The authors would like to thank the editors and reviewers for their valuable comments on this research.
Disclosure statement
No potential conflict of interest was reported by the author(s).