Comprehensive optimization of a diesel-E85 engine over the full operating range using the Taguchi method in intelligent charge compression ignition (ICCI) mode

Lean combustion engines have been regarded as applicable technologies meeting the stringent emission regu-lations, while control parameters of these engines have become more complex with the application of new technologies. The intelligent charge compression ignition (ICCI) engine was equipped with an additional direct injection system, further complicating the optimization process. To simplify the optimization of control pa-rameters, Taguchi design of experiment was employed based on an L18 orthogonal array. The effect degree of various parameters including engine load, speed, excess air ratio, E85 (85 % ethanol and 15 % gasoline) energy ratio, and premixed strategies were investigated, while indicated thermal efficiency (ITE), particle number (PN), and gaseous emissions as responses were discussed using the signal-to-noise (S/N) ratio and the analysis of variance. An optimized control strategy of ICCI over full operating conditions was designed based on the rules obtained by the Taguchi method. It concluded that engine load and speed had a significant influence on the upper limit of ITE while excess air ratio, E85 energy ratio, and premixed strategies had varying degrees of effect on emissions. The optimized control strategy realized that the maximum E85 substitution ratio reached 80 %, reducing CO2 emission below 500 g/kWh in most conditions. The load range of ICCI combustion reached 75 % of the original diesel engine load (21 bar IMEP) considering engine mechanical strength and noise level, while the peak ITE and the minimum NOx emissions were over 51 % and below 0.2 g/kWh respectively under conditions of low speed and high load.

Automated summary

This study investigates the impact of different parameters on the control of intelligent charge compression ignition (ICCI) engines using Taguchi experimental design. The optimized control strategy achieved improved combustion efficiency and reduced emissions, with engine load and speed having a significant influence on the upper limit of efficiency, and excess air ratio, E85 energy ratio, and premixed strategies affecting emissions to varying degrees.