Study of Visualization Experiment on the Influence of Injector Nozzle Diameter on Diesel Engine Spray Ignition and Combustion Characteristics

The elementary research of spray and combustion is of great significance to the development of compactness of modern diesel engines. In this paper, three injectors with different nozzle orifice diameters (0.23 mm, 0.27 mm and 0.31 mm) were used to study the diesel spray, ignition and flame-wall impi...

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Published inEnergies (Basel) Vol. 13; no. 20; p. 5337
Main Authors Tang, Yuanzhi, Lou, Diming, Wang, Chengguan, Tan, Pi-qiang, Hu, Zhiyuan, Zhang, Yunhua, Fang, Liang
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 13.10.2020
Subjects
Cameras
Combustion
constant volume combustion vessel
Diesel
Diesel engines
Diesel fuels
Engines
evaporative spray
Experiments
flame luminosity
flame-wall impinging combustion
Fuel-air mixing
Ignition
Impingement
Injectors
Internal combustion engines
Light
Liquid fuels
Luminosity
Nozzles
Orifices
Pollutants
Soot
Visualization
visualization experiment
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Summary:The elementary research of spray and combustion is of great significance to the development of compactness of modern diesel engines. In this paper, three injectors with different nozzle orifice diameters (0.23 mm, 0.27 mm and 0.31 mm) were used to study the diesel spray, ignition and flame-wall impingement visualization experiment. This paper studied the influence of different nozzle sizes on the trends of spray, ignition and flame diffusion under the flame-wall impinging combustion and used the flame luminosity to characterize the soot generation in combustion. By analyzing the quantitative data, such as spray penetration, ignition delay, flame area and flame luminosity systematically, it was shown that the smaller nozzle benefitted diesel combustion to some extent. The 0.23 mm nozzle injector in these experiments had the best fuel-air mixing effect under 800 K. The length of the spray liquid under the 0.23 mm nozzle condition was 19% and 23% shorter than that of 0.27 and 0.31 mm, respectively. Smaller orifice size of the nozzle can help to reach the gas ignition conditions more effectively. Without liquid fuel impingement, the simple flame-wall impingement will not change the trend of the nozzle influence on combustion. The total amount of accumulated soot according to the approximate luminosity spatial integral calculation in the combustion process was reduced by 37% and 43% under 0.27 mm and 0.23 mm nozzles, respectively, which is favorable for the clean combustion of diesel engines.
ISSN:1996-1073
1996-1073
DOI:10.3390/en13205337