Abstract
The earlier activation of the catalytic converters in internal combustion engines is becoming highly challenging due to the reduction in exhaust gas temperature caused by the application of CO2 reduction technologies. In this context, the use of pre-turbine catalysts arises as a potential way to increase the conversion efficiency of the exhaust aftertreatment system. In this work, a small-sized oxidation catalyst consisting of a honeycomb thin-wall metallic substrate was placed upstream of the turbine to benefit from the higher temperature and pressure prior to the turbine expansion. The change in engine performance and emissions in comparison to the baseline configuration are analyzed under driving conditions. As an individual element, the pre-turbine catalyst contributed positively with a relevant increase in the overall CO and HC conversion efficiency. However, its placement produced secondary effects on the engine and baseline aftertreatment response. Although small-sized monoliths are advantageous to minimize the thermal inertia impact on the turbocharger lag, the catalyst cross-section is in trade-off with the additional pressure drop that the monolith causes. As a result, the higher exhaust manifold pressure in pre-turbine pre-catalyst configuration caused a fuel consumption increase higher than 3% while the engine-out CO and HC emissions did around 50%. These increments were not completely offset despite the high pre-turbine pre-catalyst conversion efficiency (>40%) because the partial abatement of the emissions in this device conditioned the performance of the close-coupled oxidation catalyst.
Highlights
New emission regulations applied to the ground transport in major countries are focused on the reduction of both greenhouse gases and pollutant emissions [1]
The new regulation defines zero- and low-emission vehicles (ZLEV) as those with CO2 emission below 50 g/km [3]. This ZLEV category includes battery full electric vehicles (BEV) and plug-in hybrid electric vehicles (PHEV). This strategy opens the door to original engine manufacturers to meet CO2 fleet requirements offering PHEV powered by internal combustion engines (ICEs), without the need to resort to BEV extensively [4]
The pre-diesel oxidation catalyst (DOC) consisted of a small-sized metallic monolith placed at the exhaust manifold outlet and whose diameter coincided with that of the turbine inlet
Summary
New emission regulations applied to the ground transport in major countries are focused on the reduction of both greenhouse gases and pollutant emissions [1]. If any ATS device is moved from downstream to upstream of the turbine, its pressure drop is reduced due to the higher gas density (only from certain boosting pressure so that the turbine inlet pressure offsets the higher temperature) and the fact that it is not multiplied by the turbine expansion ratio to set the engine backpressure (exhaust manifold pressure) [17] This is relevant for wall-flow monoliths, whose baseline pressure drop is high and increases as the soot is collected (while lower soot accumulation would occur in pre-turbine placement due to higher passive oxidation). Despite its small size, which was selected to reduce the thermal inertia and, the turbocharger lag, high CO and HC conversion efficiency was found in the pre-DOC Such a small size altered the flow path, deteriorating the engine performance in terms of fuel consumption and engine-out emissions.
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