Abstract
Downsized spark ignition engines coupled with a direct injection strategy are more and more attractive for car manufacturers in order to reduce pollutant emissions and increase efficiency. However, the combustion process may be affected by local heterogeneities caused by the interaction between the spray and turbulence. The aim for car manufacturers of such engine strategy is to create, for mid-to-high speeds and mid-up-high loads, a mixture which is as homogeneous as possible. However, although injection occurs during the intake phase, which favors homogeneous mixing, local heterogeneities of the equivalence ratio are still observed at the ignition time. The analysis of the mixture preparation is difficult to perform experimentally because of limited optical accesses. In this context, numerical simulation, and in particular Large Eddy Simulation (LES) are complementary tools for the understanding and analysis of unsteady phenomena. The paper presents the LES study of the impact of direct injection on the mixture preparation and combustion in a spark ignition engine. Numerical simulations are validated by comparing LES results with experimental data previously obtained at IFPEN. Two main analyses are performed. The first one focuses on the fuel mixing and the second one concerns the effect of the liquid phase on the combustion process. To highlight these phenomena, simulations with and without liquid injection are performed and compared.
Highlights
In the last decade, downsized Direct Injection Spark Ignition (DISI) engines have been developed by the majority of automotive manufacturers for their potential to significantly reduce the fuel consumption and pollutant emissions
Liquid injection is described with the GDI-model (Gaussian Disk Injection model [13]) which assumes that liquid at the nozzle exit is already in the form of a spray, omitting the dense region of the liquid jet [14, 15]
Due to the valves motion, 40 tetrahedral meshes are needed to simulate a full cycle. They contain from 3.0 to 12.4 million cells depending on the Crank Angle Degree (CAD)
Summary
In the last decade, downsized Direct Injection Spark Ignition (DISI) engines have been developed by the majority of automotive manufacturers for their potential to significantly reduce the fuel consumption and pollutant emissions. They raise a number of technical challenges such as abnormal combustion phenomena (i.e., pre-ignition or knock [1]), and particulate emissions especially during engine transient operation and cold-start. The authors showed that there is a significant increase in kinetic energy of the cyclic fluctuations with fuel injection and it provided different equivalence ratio fields around the spark plug. With previous calculations, assuming a fully homogeneous mixing, are done in order to highlight which quantities are impacted by the stratifications during the combustion
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