论文信息 - An Integrated Engine Cycle Simulation Model with Species Tracking in Piping System

An Integrated Engine Cycle Simulation Model with Species Tracking in Piping System

Due to compressibility, reactivity, evaporation and mixing, the gas species concentration varies significantly along the intake and exhaust pipes of an engine. An understanding of this behavior is vital to correctly predict catalyst performance because the behavior of a catalyst very much depends on the instantaneous local species concentrations, rather than those in the cylinder. Also, knowing this behavior is more important to assess the effects of exhaust gas recirculation (EGR). The objective of this research is to develop a tool that is capable of predicting the instantaneous species concentration throughout the entire intake and exhaust system, and to lay out a foundation to model catalysts in the near future. This is done by first developing a complete engine cycle simulation model that is able to accurately predict wave dynamics in the piping system. Then, species tracking is accomplished by solving the species conservation equations. The twelve species formed due to combustion commonly seen in engine applications are studied. Comparisons with experimental data using the current model are made, and reasonable agreements are obtained.

Houshun Zhang | Stanley K. Widener

[1] Roy Douglas,et al. A Simple But Effective Catalyst Model for Two-Stroke Engines , 1992 .

[2] Yasuo Takagi,et al. Reduction in Exhaust Noise Through Exhaust Valving Modifications Achieved with a Gas Dynamics Simulation Model , 1991 .

[3] N Watson,et al. A Combustion Correlation for Diesel Engine Simulation , 1980 .

[4] G. Woschni. A Universally Applicable Equation for the Instantaneous Heat Transfer Coefficient in the Internal Combustion Engine , 1967 .

[5] John B. Heywood,et al. Internal combustion engine fundamentals , 1988 .

[6] Gordon P. Blair,et al. The Basic Design of Two Stroke Engines , 1990 .

[7] P. C. Baruah,et al. A Simulation Model for Transient Operation of Spark-Ignition Engines , 1990 .

[8] D. E. Winterbone,et al. The Accuracy of Calculating Wave Action in Engine Intake Manifolds , 1990 .

[9] Houshun Zhang,et al. Analytical Engine Design Methods: A Review , 1995 .

[10] G. Lavoie. Correlations of Combustion Data for S. I. Engine Calculations - Laminar Flame Speed, Quench Distance and Global Reaction Rates , 1978 .

[11] Dario Cundari,et al. A One-Dimensional Model for Monolithic Converter: Numerical Simulation and Experimental Verification of Conversion and Thermal Responses for Two-Stroke Engine , 1991 .