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This study investigates the effect of diesel particulate filters (DPF) on the performance of exhaust gas recirculation (EGR) coolers. EGR coolers were tested with and without the use of a DPF and their measured performances were compared. The exhaust gas was filtered using a Ni-Fe-Cr-Al metallic foam wall flow diesel particulate filter. The DPFs used in this investigation had very low Space Velocity (SV) characteristics in order to minimize the effect of filtration on the pressure drop. Two different measurement methods were employed to determine particulate matter (PM) emission levels at locations before and after the DPF. The first method involved the collection of PM on quartz filters followed by thermal analysis of the filters to monitor the removal of soot, semi-volatile organics, and sulfate across the DPF. The second method measured the time resolved PM mass in the exhaust with a Dekati Mass Monitor.

Cooled exhaust gas recirculation (EGR) is effective in the reduction of in-cylinder formation of oxides of nitrogen (NOx). However, at conventional in-cylinder high temperature diesel combustion high load operating conditions, the engine-out exhaust emissions of particulate matter, which consists of smoke, soot and soluble organic fraction, tend to increase. As the EGR is applied at medium to high loads, therefore, the small carbonaceous particles and heavy hydrocarbons can deposit on the cool surfaces of EGR coolers mainly through a complex combination of thermophoresis, condensation, diffusion and turbulent impaction. Consequently, an insulation layer develops on the cooler surfaces and deteriorates EGR cooler function. As the deposits build up, the cooler effectiveness decreases and pressure drop increases thereby increasing the intake charge temperature. Consequently, the in-cylinder formation of NOx increases.