Effects of operating parameters on the performance, emission and combustion indices of a biogas fuelled HCCI engine

This study discusses the operation of a Homogeneous Charge Compression Ignition (HCCI) engine using simulated biogas and diethyl ether (DEE) as the primary and secondary fuels respectively. Performance, emission and combustion parameters are measured for various biogas flow rates (8-16 litre/min), composition (50 to 100% methane), intake temperatures (35-80 degrees C) and loads (20 to 90% of full load). A comparison of injecting DEE at the intake port (port injection) and 7 cm upstream (manifold injection) is also presented. It was demonstrated that at high flow rates and/or with high methane content, biogas can effectively substitute DEE and provide up to 60% of the total energy input. However, the use of lower biogas flow rates and methane fraction resulted in better thermal efficiency (as high as 26%) as well as lower HC emissions. HCCI operation offered simultaneously low NOx (< 0.2 g/kWh) and smoke (similar to 1%). Intake heating ensured better performance and emissions, although it increased the tendency to knock. In general, manifold injection provided superior engine output compared to port injection. The knock limit of HCCI operation could be effectively extended by employing high biogas flow rates and/or methane enrichment. ANOVA study showed that biogas flow rate had a strong influence on most engine output parameters. While methane fraction correlated well with combustion indices, engine torque had a significant effect on thermal efficiency and emissions.

Automated summary

This study investigates the operation of a HCCI engine using simulated biogas and DEE as fuels, with a focus on performance, emissions, and combustion parameters. The research reveals that high biogas flow rates or methane content can effectively substitute DEE and provide significant energy input, while lower biogas flow rates and methane fractions lead to improved thermal efficiency and reduced HC emissions. Intake heating improves engine performance and emissions, although it may increase the tendency to knock, and manifold injection shows superior engine output compared to port injection.