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Gasoline particulate filters (GPFs) are an important aftertreatment system that enables gasoline direct injection (GDI) engines to meet current emission standardsn note of GPFs may need to improonont accumulates on the GPF during engine operation. GPFs are often ‘pa during vehicle operation when the exhaust is sufficiently hot and it contains sufficient oxygen. This paper explores the effect that engine-out soot emissions and the frequency of GPF regeneration have on GPF filtration efficiency. Two GPF technologies were tested on two engine dynamometers as well as two production vehicles on a chassis dynamometer. The engines span a wide range of engine-out particle emissions (a range of almost one order of magnitude). The filtration efficiency of the GPFs were measured with a regulation-compliant particle number system (non-volatile particles > 23 nm), as well as with a particle counter with a lower cutoff of 2.5 nm, and with a differential mobility spectrometer.

The introduction of vehicle emission and fuel economy standards (CO2) accelerates the introduction of new platform and powertrain combinations into the market place. All of these combinations will require unique exhaust gas aftertreatment systems that comply with the current emission legislation. The optimization of each unique aftertreatment solution requires the proper application of catalyst technologies at the lowest PGM concentrations. The optimization process needs to be fast, reliable, realistic and cost attractive. It is arguable that performing the aftertreatment optimization on a chassis dynamometer is variable, time consuming and expensive. This work demonstrates how a synthetic gas bench (SGB) can be used to simulate stoichiometric engine emissions and aftertreatment performance. The SGB procedure duplicates the vehicle NEDC engine-out emissions and catalyst heat-up profiles.

Future emission standards will require further reduction of harmful gaseous emissions such as HC, CO and NOx as well as consideration for greenhouse gas emissions such as CO₂. Gasoline engines with lean combustion spray-guided direct fuel injection in conjunction with turbocharging have a very high potential for fuel savings. The main challenge for stratified lean GDI aftertreatment systems is the development of a catalyst system to fulfill the emission legislation requirements under low exhaust temperature operating conditions with efficient use of precious metals. In addition to the very stringent emission legislation another challenge for the introduction of lean gasoline engines in North America is the higher sulfur content of the fuel compared to Europe. In this paper exhaust gas aftertreatment requirements for stratified gasoline direct injection engines will be discussed and the latest advances in catalyst and system development will be shown.