Comprehensive analysis of combustion phasing of multi-injection HCCI diesel engine at different speeds and loads

•Effect of engine speed and load on the combustion phasing of multi-injection HCCI DE.•Evaluation of AHRR events and periods at different load and speed.•Max. In-cylinder pressure and tempersture of HCCI DE.•New correlation for LTRD, HTRD and ZNTC with engine speed and load. Combustion in homogeneou...

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Bibliographic Details
Published in:Fuel (Guildford) 2022-04, Vol.314, p.123083, Article 123083
Main Authors: Niklawy, W., Shahin, M., Amin, Mohamed I., Elmaihy, A.
Format: Article
Language:English
Subjects:
AHRR
Burning
Burning rate
Combustion
Combustion control
Combustion phasing
Common rail
Compression
Cylinders
Diesel engines
Fuel systems
HCCI engines
Heat release rate
Heat transfer
High temperature
Injection
Low and high-temperature reactions
Superchargers
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Summary:•Effect of engine speed and load on the combustion phasing of multi-injection HCCI DE.•Evaluation of AHRR events and periods at different load and speed.•Max. In-cylinder pressure and tempersture of HCCI DE.•New correlation for LTRD, HTRD and ZNTC with engine speed and load. Combustion in homogeneous charge compression ignition engines is normally complicated, so the heat release analysis is very significant as it is beneficial for controlling combustion phasing and developing combustion models. The experimental work was carried out on a turbocharged common rail diesel engine. The engine is a water-cooled, 2.776 L, 4-cylinder, and 4-stroke with a multi-injection fuel system. The Apparent Heat Release Rate is computed from the measured in-cylinder pressure at various speeds and loads. The low- and high-temperature reaction events (start and end) and periods, calculated in-cylinder temperature and cumulative fuel burning rate are evaluated and analyzed in both engine crank-angle and time scales. A new correlation considering the effect of engine speed and load on low- and high-temperature reaction periods is proposed. A very good agreement between correlation-predicted and measured and has been achieved (R2 is greater than 0.95), which could be a useful tool in early design calculation, combustion modeling, and control.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2021.123083