A control-oriented air-fuel ratio path model is developed to represent a spark-ignited, port-fuel-injected, twin-independent variable cam timing engine. Following a recent publication [Genç et al., SAE 2002-01-2752 (2002)] showing that cam timing not only affects the cylinder air flow but also the transient cylinder fuel flow, this paper constructs a mean value model that describes both air and fuel dynamics. While steady-state engine tests have been performed in order to identify the air path dynamics, a combination of linear and nonlinear identification methods have been used in order to identify the fuel path model including the wall-wetting dynamics. The resulting parameter-varying model has been validated with independent experimental data and can be used in powertrain controller design and development.

Issue Section:
Technical Papers
Keywords:
cams (mechanical), power transmission (mechanical), internal combustion engines, fuel systems, aerodynamics, engine cylinders, mechanical testing, automotive components, design engineering, automobile industry, control system synthesis
Topics:
Cylinders, Dynamics (Mechanics), Engines, Fuels, Transients (Dynamics), Wetting, Sensors, Air flow, Valves, Steady state, Delays
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 by American Society of Mechanical Engineers
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