Abstract
In this study, a two-stroke boosted uniflow scavenged direct injection gasoline (BUSDIG) engine was proposed and researched to achieve aggressive engine downsizing and downspeeding. Compared to loop or cross scavenged two-stroke engines, the BUSDIG engine can achieve excellent scavenging performance and be operated with higher boost pressure as well as the absence of air and fuel short-circuiting. As a fundamental engine geometric parameter, the bore/stroke (B/S) ratio would directly affect the scavenging process in the uniflow scavenged two-stroke engine. Three-dimensional computational fluid dynamics simulations were used to investigate the scavenging process in the BUSDIG engine with different B/S ratios. Four B/S ratios of 0.66, 0.8, 1, and 1.3 were analyzed. The results indicate that a bigger B/S ratio leads to deteriorated swirl flow motion but better delivery ratio, scavenging efficiency, and charging efficiency. In order to fulfil the potential of the BUSDIG engine with different B/S ratios, two key scavenge port angles, i.e. axis inclination angle (AIA) and swirl orientation angle (SOA), were varied from the baseline design (AIA = 90°, SOA = 20°) to study their effects on the scavenging process for each B/S ratio design. Overall, a larger AIA leads to lower swirl ratio (SR) but achieves better scavenge performance, which is crucial for a large B/S ratio design. A small SOA design leads to noticeably lower SR but superior scavenging performances for a small B/S ratio design. An intermediate SOA, e.g. 10 and 20°, is preferred to improve the scavenging for a large B/S ratio design.
Highlights
In order to reduce CO2 emissions and achieve higher engine efficiency requirements, engine downsizing and downspeeding technologies have been developed in the automotive industry
In the first part of the study, the effect of bore/ stroke (B/S) ratio on the in-cylinder flow motions and scavenging process was investigated with the baseline scavenge port design (AIA = 90°, swirl orientation angle (SOA) = 20°)
3D computational fluid dynamics (CFD) simulations were performed to understand the effect of B/S ratio and the scavenge port angles on scavenging process in a boosted uniflow scavenged direct injection gasoline (BUSDIG) engine
Summary
In order to reduce CO2 emissions and achieve higher engine efficiency requirements, engine downsizing and downspeeding technologies have been developed in the automotive industry. Amongst all types of two-stroke operations, the uniflow scavenge process is shown to be most effective in terms of scavenging performance.[2,3,4] The intake ports in the uniflow engine are integrated into the cylinder liner and controlled by the movement of the piston top while exhaust valves are placed in the cylinder head. This engine layout enables the application of variable valve timing (VVT) technology to control the hot residual gas and scavenging process under different boost pressures at various engine speeds by adjusting the exhaust valve timing. The fuel consumption of a BUSDIG engine is expected to be improved with lean/stratified charge and advanced combustion concept, e.g. homogeneous charge compression ignition (HCCI) and controlled auto-ignition (CAI).[5,6,7]
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