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International Journal of Automotive Technology

17.04.2024 | Engine and Emissions, Fuels and Lubricants

Investigations of Solid Particle Erosion on the Flow Channel Walls of a Radial Turbine for Diesel Engine Applications

verfasst von: Ma Chao, Sun Yangli, Wang Quan, Chen Gang

Erschienen in: International Journal of Automotive Technology

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Abstract

Carbon particles, a primary component of diesel engine emissions, cause persistent erosion in the exhaust piping system, inevitably leading to performance degradation. This erosion can result in reduced fuel economy and increased emissions. The effects of three key parameters including solid particle size, turbine U/C operating conditions and rotational speed on the erosion characteristics of the flow channels of a radial turbine for vehicle diesel engine applications and their impact on performance were investigated through numerical simulations in the study. The findings indicate that larger particle size and higher rotational speed can significantly lead to the higher erosion rate density of the volute channel and casing wall surfaces. Reducing U/C does not substantially affect the distribution of erosion rate density. Centrifugal force will play an important role in the variation of erosion distribution characteristics. Compared to U/C, the other two key parameters are sensitive factors affecting turbine performance degradation. Under the same condition for operating 5000 h, 10 μm particles cause a 7.5-fold increase in efficiency loss change rate compared to 0.5 μm particles. The efficiency loss at 140 krpm is 16 times greater than that at 40 krpm.

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Metadaten
Titel
Investigations of Solid Particle Erosion on the Flow Channel Walls of a Radial Turbine for Diesel Engine Applications
verfasst von
Ma Chao
Sun Yangli
Wang Quan
Chen Gang
Publikationsdatum
17.04.2024
Verlag
The Korean Society of Automotive Engineers
Erschienen in
International Journal of Automotive Technology
Print ISSN: 1229-9138
Elektronische ISSN: 1976-3832
DOI
https://doi.org/10.1007/s12239-024-00089-5

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