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Particulate matter in the air has become the focus of increased attention due to the concern of potential health effects. Among other sources, automotive vehicles are seen as a major contributor of fine particles. At present there is limited information available relating either to the number or size distribution of automotive particle emissions and detailed evidence has still to be established. To develop an understanding in the area of automotive particulate emissions a programme was carried out concentrating on tailpipe emissions as measured at the regulated particulate sampling point in a dilution tunnel. A previous literature study by CONCAWE had identified analytical techniques considered to be suitable for this application and which are capable of measuring both mass and number size distributions. Several variations of these techniques are available in the research field and the programme aimed to assess and compare their operation and performance.

In a collaborative programme, the effects of gasoline sulphur content on regulated emissions from three-way catalyst equipped vehicles have been studied. The programme evaluated the sulphur tolerance of three different catalyst formulations on the same range of vehicles. The catalyst chemistries were chosen to be representative of typical current formulations in different markets, as follows: 1. Platinum/Rhodium (Pt/Rh) 2. Platinum/Rhodium/Nickel (Pt/Rh/Ni) 3. Palladium/Rhodium (Pd/Rh) Each vehicle/catalyst combination was tested with fuels containing sulphur at nominal levels of 50, 250 and 450 ppm weight. All fuels were produced using the low sulphur fuel as a base and doping to 250 and 450 ppm S with a mixture of nine sulphur compounds, typical of those actually occurring in European gasolines. The results show clear differences between the magnitudes of the sulphur effect with different catalyst formulations.

The effect of gasoline RVP on regulated exhaust emissions has been investigated in a fleet consisting of five current European vehicles. The effects of MTBE with changing RVP and E70 were also studied. All vehicles were equipped with the standard OEM small carbon canisters and three-way catalytic converters and the regulated emissions measured over the new European test cycle. A rigorous refuelling protocol was employed to ensure that the carbon canisters were loaded in a repeatable way before the emission tests. The results show that a reduction in RVP gave benefits in CO and NOx, but no effect on exhaust THC emissions. The benefits for CO and NOx were greater in non-oxygenated fuels. Of the five test vehicles, three showed CO emission benefits due to RVP reduction, whilst CO from the other two was insensitive to RVP changes. Four vehicles also showed NOx emission benefits due to RVP reduction whilst the NOx emissions from the other vehicle were insensitive to RVP changes.

A test programme has been conducted to study any potential long term effects of gasoline sulphur on catalyst performance, using a newly developed transient engine-bed ageing cycle. The ageing cycle, which was based on repeated European Extra Urban Drive Cycles, was chosen to ensure that the catalyst experienced a realistically wide range of temperatures and space velocities, together with transients, idle and periods of overrun. Two nominally identical platinum/rhodium catalysts (manufactured from the same batch) with matched lambda sensors, were aged for a period of 80,000 km each, one being aged using a gasoline containing 50 mg/kg (ppm wt) sulphur, the other being aged on the same fuel doped to 450 ppm wt S. The emissions performance of both catalysts was measured after 6,000, 40,000 and 80,000 km ageing, by fitting the catalysts to a test vehicle, and performing emissions tests over the European test cycle at both sulphur levels.

The effects of fuel formulation changes on vehicles meeting European Stage 1 (91/441/EEC) and Stage II (94/12/EC) emission limits have been investigated. Vehicles in the Euro Stage II fleet were advanced specification versions of the vehicle models in the Euro Stage I fleet. However, the basic engine blocks and capacity were the same. The observed improvements in emissions were attributed to changes, such as position of the catalyst and lambda sensor, improved fuel delivery systems, and to improvements in engine control strategy. These engine modifications resulted in reduced catalyst light-off times and improved AFR control. Emissions improvements, over the modified European test cycle, as a result of these changes were approximately 50% for CO and NOx and 30% for THC. A fuel matrix was designed in order to study the effect of six fuel parameters on exhaust emissions from the two levels of vehicle technology.

This paper describes how the analytical methodology for fuels and exhaust gases was selected and developed for the experimental sectors of the EPEFE study. It covers the selection of standard test methods for fuels analysis and addresses how round-robin exercises in non-standard areas of fuels analysis were designed, organised, monitored and reviewed, and then used to define the approach to (and the scope of) the speciated fuel analyses. The paper also addresses how the exhaust gas analysis was designed in relation to emissions testing methodology. The means used to evaluate and, where necessary, optimise the exhaust gas speciation capabilities of participating laboratories, and in which round-robin activities were a key element, are also explained.