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This article describes a system level 1D simulation tool that has been constructed on the Quasi-steady (QS) method. By assuming that spatial changes are much greater than the temporal ones, rigorous 1D governing equations can be considerably simplified thus becoming less computationally demanding to solve and therefore suitable for control oriented modeling purposes. With the proposed tool exhaust pipe wall temperature profiles, including multiple-wall-layer configurations, are solved through a finite difference scheme. Momentum equation is included for predicting pressure losses due to frictions and geometric irregularity. Exhaust fluid properties (transport and thermodynamic) are evaluated according to NASA or JANAF polynomial thermal data basis. The proposed tool allows the consideration of an arbitrary number of chemical species and reactions in the entire system. A novel semi-automatic approach was developed to handle catalytic reaction kinetics intuitively.

The potential of fuel cells as an automotive power source is well recognized due to their high efficiency and zero tailpipe emissions. However, significant technical and economic hurdles need to be overcome in order to make this technology commercially viable. A proton-exchange membrane (PEM) fuel cell model has been developed to assess some of these technical issues. The fuel cell model can be operated in a standalone mode or it can be integrated with vehicle and fuel supply system models. A detailed thermal model of the fuel cell stack was used to identify significant design parameters that affect the performance of PEM fuel cell vehicles. The integrated vehicle model was used to explore the relative benefits of hybridization options.