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Coherent anti-Stokes Raman spectroscopy (CARS) temperature measurements were performed in the unburned gas in a spark ignition engine. First, as the residual gas mass fraction is one of the factor that is known to cause to autoignition, the effect of the residual gas mass fraction on the unburned gas temperature is estimated. In order to control the residual gas mass fraction, a skip fired cycle method was used., and the single cylinder test engine used in this study was fueled with gasoline (89.9 RON). The residual gas causes the unburned gas temperature to rise by approximately 55 K and it also produces a large temperature variation on the order of ±20 K when expressed as a standard deviation. Second, the unburned gas temperature of the single cylinder test engine and the 4 valve production engine was measured under steady-state engine operation in order to compare the residual gas mass fraction of the test engine with that of the production engine.

This paper presents a study of mixture formation in the combustion chamber of a direct-injection SI engine. In-cylinder flow measurement was conducted using laser Doppler velocimetry (LDV) and particle image velocimetry (PIV), and visualization of fuel vapor behavior was done using laser-induced fluorescence (LIF). Further, fast response flame ionization detector (FID) was used to measure the hydrocarbon (HC) concentrations in the vicinity of the spark plug. Thereby mixture concentrations in the vicinity of the spark plug, within the mixture distribution observed using LIF, were quantified. Results revealed that an upward flow forms near the center of the cylinder in the latter half of the compression stroke and goes from the piston crown toward the cylinder head. This upward flow is caused by the synergistic effect of the swirl motion generated in the cylinder and the cylindrical bowl provided in the piston crown eccentrically to the central axis of the cylinder.

Flow measurement by laser Doppler velocimetry and visualization of in-cylinder fuel vapor motion by laser induced fluorescence were performed for various types of intake systems that generated several different combinations of swirl and tumble ratios. The measured results indicate that certain swirl and tumble ratios are needed to achieve charge stratification in the cylinder. Performance tests were also carried out to determine the combustion characteristics of each intake system. Then, the features of combustion when the charge stratification was realized was analyzed.

In order to study the potentiality of the modification of the combustion rate for NOx formation control in the spark ignition (SI) engine, the authors first developed a new mathematical model by assuming the stepped gas temperature gradient in the cylinder. The predicted results from this new mathematical model show good coincidence with the experimental data. Second, the authors discuss the effects of the modification of the combustion rate on NOx formation using the new mathematical model. It was concluded that NOx formation in the premixed SI engine would be essentially determined by the specific fuel consumption only, regardless of any modification of the engine combustion rate.