Multiscale Modeling and Analysis of Pressure Drop Contributions in Catalytic Filters

Catalytic monolith filters with a honeycomb structure represent a key component of modern automotive exhaust gas aftertreatment systems. In this paper, we present and validate a multiscale modeling methodology for the prediction of filter pressure loss depending on the monolith channel geometry as well as the microscopic structure of the wall including catalytic coating. The approach is based on the combination of a 3D pore-scale model of flow through the wall reconstructed from X-ray tomography and a 1D+1D model of the filter channels. Several cordierite and SiC filter samples with varying substrate pore sizes and catalyst distributions are examined. A series of experiments are performed at different gas flow rates and filter lengths in order to validate the model predictions and to distinguish individual pressure drop contributions (inlet and outlet, channel, and wall). The predicted pressure drop shows a strong impact of the coating location and agrees well with the experiments.

Automated summary

A multiscale modeling methodology was presented and validated for predicting filter pressure loss in catalytic monolith filters with a honeycomb structure. Experimental results showed a strong impact of the coating location on the predicted pressure drop in automotive exhaust gas aftertreatment systems.