Effect of injection timing on knock combustion and pollutant emission of heavy-duty diesel engines at low temperatures

The knock combustion and pollutant emission of heavy-duty diesel engines at low temperatures are still unclear, especially under different injection timings. Therefore, this study illustrates the above issues through CONVERGE simulation. The results show that with the start of injection (SOI) sweeps...

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Bibliographic Details
Published in:Chemosphere (Oxford) 2022-10, Vol.305, p.135519-135519, Article 135519
Main Authors: Wu, Han, Dong, Xinyi, Shi, Zhicheng, Li, Haiying, Cao, Weiren, Zhang, Lu, Bo, Yaqing, Li, Xiangrong
Format: Article
Language:English
Subjects:
Heavy-duty diesel engine
Injection timing
Knock combustion
Low temperature
Pollutant emission
Spray impingement
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Summary:The knock combustion and pollutant emission of heavy-duty diesel engines at low temperatures are still unclear, especially under different injection timings. Therefore, this study illustrates the above issues through CONVERGE simulation. The results show that with the start of injection (SOI) sweeps from −7°CA to −32°CA, a large amount of liquid-phase fuel adheres to the wall, and the wet-wall ratio of fuel at SOI = −32°CA is as high as nearly 30%. The fuel film evaporates slowly, coupled with the effect of low temperature on chemical reactions, the high-temperature ignition (HTI) is delayed seriously until the end of injection. The amount of premixed mixture formed during long ignition delay is significantly increased, but its uniformity is better and the concentration is more suitable for ignition. Once HTI is triggered, high-frequency and strong pressure oscillation occurs in the cylinder, and the maximum oscillation amplitude is as high as nearly 10 MPa, far exceeding the threshold of destructive knock combustion. Delayed fuel injection can effectively alleviate the above problems, such as the best when the SOI in this study is −17°CA. In addition, HC emissions are positively correlated with the amount of fuel film, but the trend of CO quantity with injection timing shows the opposite result. NOx emission increases as the injection timing advances, while soot is the opposite, because the mixture concentration is leaner at the earlier SOI and the expanded high-temperature region leads to an accelerated oxidation rate of soot. [Display omitted] •With the advance of injection timing, the wet wall rate increases rapidly, up to 30%.•Strong pressure shock occurs under early injection, with maximum amplitude of 10 MPa.•Proper delay of fuel injection can effectively alleviate knock at low temperature.•HC emission is positively correlated with fuel film quantity, but CO is not.•NOx emissions increase as injection timing advances, soot does the opposite.
ISSN:0045-6535
1879-1298
DOI:10.1016/j.chemosphere.2022.135519