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In this paper, results of experimental and numerical investigations of stratified exhaust gas recirculation in a single-cylinder gasoline engine are presented. The engine was operated in spray guided direct injection mode. The radial exhaust gas stratification was achieved by a spatial and temporal separated intake of exhaust gas and fresh air. The spatial separation of both fluids was realized by specially shaped baffles in the inlet ports, which prevent an early mixing up to the inlet valves. The temporally separation was performed by impulse charge valves, with one for the fresh air and one for the exhaust gas. From various possible strategies for time-dependent intake of fresh air and exhaust gas, four different strategies for the exhaust gas stratification were examined.

This paper introduces a new measuring and analyzing method for the investigation of the spatial flame propagation in IC engines. Three optical high-speed measuring devices are connected and synchronized in order to detect the flame radiation from different perspectives via fiberoptical endoscopes. The resulting two-dimensional images provide a starting basis for the subsequent reconstruction of the three-dimensional flame geometry. The reconstruction is carried out by a newly developed software tool. The capability of the new methodology has been proven in a first test series. A one-cylinder SI engine with direct-injection is operated in both homogeneous and spray-guided stratified injection mode. Intake flow conditions and air/fuel ratio are varied in order to investigate the effects on flame spread. The volumetric flame developments are analyzed as well as the location of the combustion center in absolute coordinates.