Advanced Catalytic Technologies for Compressed Natural Gas – Gasoline Fuelled Engines

IF 1.7 4区化学 Q4 CHEMISTRY, PHYSICAL

Johnson Matthey Technology Review Pub Date : 2022-01-01 DOI:10.1595/205651323x16669674224875

A. Wahbi, A. Tsolakis, J. Herreros, S. Zeraati-Rezaei, O. Doustdar, P. Millington, A. Raj

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Abstract

The main challenges of the CNG engine fuelling in terms of methane abatement in the aftertreatment system are addressed in this study by using different loaded PGM catalysts. A dual-fuel injection strategy of methane-gasoline was implemented where methane gas was port-injected into the intake in stoichiometric conditions at levels corresponding to 20 and 40% energy density replacement of gasoline fuel. High, medium, and low loaded Pd/Rh catalysts were used and compared to study the effect of PGM loading on the catalyst light-off activity for methane. Results indicate that increasing the Pd loading led to significantly earlier light-off temperatures achieved at relatively lower temperatures of 340, 350 and 395oC respectively. However, the benefit diminishes above Pd loading >142.5 g ft-3. The study has also demonstrated that NH3 is formed over the CNG catalyst due to steam-reforming reactions from the increased levels of methane in the exhaust with the dual-fuelling. Hence aftertreatment technologies such as SCR should be adopted to remove them. This further highlights the need to regulate the harmful NH3 emissions from future passenger cars fuelled with CNG. In addition, the benefits of the dual-fuel system in terms of lower engine output CO2, non-methane hydrocarbon (NMHC) and particulate matter (PM) emissions compared to the GDI mode alone are presented.

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压缩天然气-汽油燃料发动机的先进催化技术

本研究通过使用不同负载的PGM催化剂，解决了CNG发动机加注在后处理系统中甲烷减排方面的主要挑战。采用甲烷-汽油双燃料喷射策略，在化学计量条件下，以相当于汽油燃料20%和40%能量密度的水平向进气口喷射甲烷气体。采用高、中、低负载Pd/Rh催化剂，对比研究了PGM负载对甲烷催化剂点燃活性的影响。结果表明，在340、350和395oC的较低温度下，增加Pd负载可显著提前达到起燃温度。然而，当Pd加载量超过142.5 g ft-3时，这种效果就会减弱。该研究还表明，由于双重燃料的废气中甲烷含量增加，蒸汽重整反应会在CNG催化剂上形成NH3。因此，应采用SCR等后处理技术来去除它们。这进一步凸显了监管未来以压缩天然气为燃料的乘用车有害NH3排放的必要性。此外，与GDI模式相比，双燃料系统在降低发动机输出二氧化碳、非甲烷烃(NMHC)和颗粒物(PM)排放方面的优势也得到了体现。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Johnson Matthey Technology Review CHEMISTRY, PHYSICAL-

CiteScore

4.30

自引率

4.30%

发文量

审稿时长

12 weeks

期刊介绍： Johnson Matthey Technology Review publishes articles, reviews and short reports on science enabling cleaner air, good health and efficient use of natural resources. Areas of application and fundamental science will be considered in the fields of:Advanced materials[...]Catalysis[...][...]Characterisation[...]Electrochemistry[...]Emissions control[...]Fine and speciality chemicals[...]Historical[...]Industrial processes[...]Materials and metallurgy[...]Modelling[...]PGM and specialist metallurgy[...]Pharmaceutical and medical science[...]Surface chemistry and coatings[...]Sustainable technologies.