Abstract
An on-going challenge with Gasoline direct injection (GDI) engines is achieving rapid activation of the exhaust catalyst during cold starts, in order to reduce the Nitrogen Oxide (NOx) emissions. Injecting late in the compression stroke, in the efforts to form a stratified mixture, provides the fuel insufficient time to be entrained with the surrounding charge. This results in locally fuel rich diffusion combustion and the formation of high levels of particulate matter. Employing a split injection strategy can help tackle these issues. The current study examines the effects of a split injection strategy on the spray characteristics. Varying pulse width (PW) combinations, split ratios and dwell times are investigated using a Solenoid actuated high pressure injector. The injected quantity and the droplet characteristics of a target plume are investigated. The experiments were performed in a constant volume spray chamber. The droplet velocities and sizes were measured using Phase Doppler Particle Anemometry (PDA). Short and large PWs, in the range of 0.3–0.8 ms, were investigated. The results revealed that the highest injected quantity of fuel was measured with the shortest dwell time of 2 ms, owing to increased interactions between the injection events, which led to larger Sauter mean diameters (SMDs) measured. The SMDs for the shorter PW of 0.4 ms were generally larger than 0.8 ms PW. The droplets in this case were affected by the closely spaced opening and closing events of the Solenoid valve.
Highlights
The Gasoline direct injection (GDI) engines have become the dominant powertrain for passenger cars, because of their higher power density and better fuel economy
The differences in the injection quantity at varying dwell times and the corresponding single injections are analysed
The purpose is to obtain some indication of the Solenoid valve behaviour and the interaction of the injection events for the split injection cases with varying dwell times using short pulse width (PW)
Summary
The Gasoline direct injection (GDI) engines have become the dominant powertrain for passenger cars, because of their higher power density and better fuel economy. The accompanied high in-cylinder turbulence levels serve to shorten the combustion duration. These combined effects, in conjunction with variable valve phasing and fresh air induced directly into the cylinder, during the gas exchange phase, can help remove burnt gases effectively. These features reduce the in-cylinder temperature, thereby mitigating knock and allowing operations with higher compression ratios.[1]
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