Abstract:
To clarify the impact of the Miller cycle on the performance evolution of diesel engines under varying altitude conditions and to address the operational demands of hybrid-specific diesel engines in high-altitude environments, a one-dimensional simulation study was conducted based on a turbocharged diesel engine. The research systematically examined the effects of different altitude levels, Miller-cycle strategies (early intake valve closing(EIVC) and late intake valve closing(LIVC)) on volumetric efficiency, thermal efficiency, power, fuel consumption and NO
x emissions at different engine speeds. The results show that under plain conditions, a slight advance in intake valve closing achieves the optimal compromise between torque and fuel consumption. Between the two Miller-cycle strategies, EIVC favors air charging at 1 600 r/min, while LIVC is more beneficial at 2 400 r/min. Elevating altitude from 3 km to 4 km leads to a notable decline in engine performance. Volumetric efficiency, thermal efficiency, and power decrease by 18.05%, 18.76% and 19.56%, respectively, with a concurrent increase in fuel consumption of 24.24%. NO
x emissions exhibit a ring-shaped distribution, with the peak emission zone located around 2 km altitude and Miller-cycle ranges of the intake valve closing advance angle 40°,30°,20°,10°, the original intake value closing angle, and the intake value closing angle delay 10°,20° and 30°. Deviating from the central region, whether by altering altitudes or Miller intensities, can effectively reduce NO
x emissions, albeit through distinct mechanisms. When applying deeper Miller-cycle strategies (either EIVC or LIVC) to lower NO
x emissions, a balance between dynamic performance and fuel economy must be considered.