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This report describes the dynamometer testing portion of the combustion system development of a direct-injection stratified-charge gasoline engine. The engine used in this study is a single-cylinder, direct-injection engine with a newly designed cylinder head comprised of 4-valves per cylinder, an intake-side-mounted DI fuel injector and a bowl-in-piston wall-guided stratified-charge combustion system. Test results detailed in this report include evaluation of four piston designs, two combustion chamber designs, and two injector spray angles. Tests were run at stratified-charge part-load, homogeneous-charge part-load, and WOT conditions. The program had aggressive goals in improving both WOT performance and part-load fuel economy while achieving Stage IV emission requirements. Tests results showed that the engine was able to meet these program goals.

The interaction between in-cylinder flow and injected fuel spray in direct ignition spark ignition (DISI) engines have been investigated. The study shows that the major effect of intake flow on the fuel spray is that the induced flow tends to make the spray collapse. This deformation of spray will prevent the fuel spray from spreading out, evaporating, and mixing well with air and also increase fuel wetting on the wall. It has been demonstrated that the intake flow effect on the fuel spray can be alleviated by increasing the masking between the two intake ports. Swirl and tumble motion effects on the fuel air mixing and wall wetting in DISI engines were also studied. A counter-rotating vortex structure is identified in the case with tumble dominating in-cylinder flow structure. This vortex structure tends to hinder fuel air mixing and increase wall wetting. It is shown that some swirl motion is helpful to improve mixing quality and decrease the wall wetting.

Gas-phase in-cylinder mixing was examined by two different methods. The first method for observing mixing involved planar Mie scattering measurements of the instantaneous number density of silicon oil droplets which were introduced to the in-cylinder flow. The local value of the number density was assumed to be representative of the local gas concentration. Because the objective was to observe the rate in which gas concentration gradients change, to provide gradients in number density, droplets were admitted into the engine through only one of the two intake ports. Air only flowed through the other port. Three different techniques were used in analyzing the droplet images to determine the spatially dependent particle number density. Direct counting, a filtering technique, and autocorrelation were used and compared. Further, numerical experiments were performed with the autocorrelation method to check its effectiveness for determination of particle number density.