论文信息 - Modelling characteristics of gasoline wall films in the intake port of port fuel injection engines

Modelling characteristics of gasoline wall films in the intake port of port fuel injection engines

Abstract Models were developed to describe the vaporization of well-mixed wall films of multi-component engine fuels based on continuous thermodynamics and applied to describing multi-component fuel spray-wall interactions. All the models were implemented into the KIVA3V Release 2.0 code. Validation calculations were conducted for pulsed injection cases and compared with experimental wall film thickness data under different air-fuel ratios and inflow conditions in an inclined pipe, which simulates an intake port of port fuel injection engines. Calculations with single-component iso-octane fuel were also conducted for comparison. The influence of wall temperature, inflow-air velocity and injection angle on the gasoline wall film characteristics was studied. The results indicate that the multi-component fuel film is composed of increasingly heavy species as the vaporization proceeds. The fuel-film structure which results from spray-pipe-wall interaction is greatly different from that resulting from spray-plane-wall interaction. An increase in the wall temperature significantly decreases both the film thickness and the film area. The injection angle significantly changes the wall film structure. Although the inflow velocity enhances the fuel vaporization rate, it has a relatively small effect on the fuel film movement along the pipe wall.

[1] R. Reitz,et al. MODELING HEAT TRANSFER TO IMPINGING FUEL SPRAYS IN DIRECT-INJECTION ENGINES , 1995 .

[2] Zhiyu Han,et al. Spray/wall interaction models for multidimensional engine simulation , 2000 .

[3] C. Tropea,et al. Droplet-wall collisions: Experimental studies of the deformation and breakup process , 1995 .

[4] A. Yarin,et al. Impact of drops on solid surfaces: self-similar capillary waves, and splashing as a new type of kinematic discontinuity , 1995, Journal of Fluid Mechanics.

[5] Rolf D. Reitz,et al. Characteristics of Vaporizing Continuous Multi-Component Fuel Sprays in a Port Fuel Injection Gasoline Engine , 2001 .

[6] Rolf D. Reitz,et al. A model for high-pressure vaporization of droplets of complex liquid mixtures using continuous thermodynamics , 2002 .

[7] J. Prausnitz,et al. Phase equilibria for mixtures containing very many components. development and application of continuous thermodynamics for chemical process design , 1985 .

[8] L. Wachters,et al. The heat transfer from a hot wall to impinging water drops in the spheroidal state , 1966 .

[9] Noureddine Guerrassi,et al. EXPERIMENTAL STUDY AND MODELING OF DIESEL SPRAY/WALL IMPINGEMENT , 1996 .

[10] W. Hallett,et al. A continuous thermodynamics model for multicomponent droplet vaporization , 1995 .