Effects of Blending Ethanol with Gasoline on the Performance of Motorcycle Catalysts and Airborne Pollutant Emissions

Jiun-Horng Tsai,Ci-Min Huang,Hung-Lung Chiang,Ya-Li Ko

doi:10.4209/aaqr.2019.10.0539

Jiun-Horng Tsai, Ci-Min Huang + Show 2 more

Open Access

https://doi.org/10.4209/aaqr.2019.10.0539

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Abstract

ABSTRACT This study investigated the effects of blending ethanol with gasoline on the exhaust emissions of fuel-injected motorcycles. Regulated gasoline (RF), and 15 (E15) and 30 (E30) vol% ethanol fuel were used as test fuels. Measurements of several air pollutants (CO, HC, and NOx) and organic air pollutant groups were conducted for two new fuel-injected four-stroke motorcycles. In addition, various catalysts were inserted into the motorcycles’ tailpipes to determine the characteristics and performance of the catalysts in treating the exhaust. Compared to using RF, we found that using blended fuel potentially reduced the CO and HC emissions by 30–37% and 19–28%, respectively. New catalytic systems, in conjunction with using different fuels, reduced CO, HC, and NOx emissions in the tailpipe exhaust by 12–61%, 32–39%, and 81–85%, respectively. The CO and HC emissions were directly proportional in quantity to the running mileage of the catalyst, but the NOx emissions were unaffected by this mileage, although they increased as the catalyst aged. We also discovered that at identical running mileages for a catalyst, the fuel consumption increased by –1.7–6.5% and 4.1–15% when using E15 and E30 fuel instead of RF. Furthermore, the specific surface area and pore volume of the catalyst decreased with the aged catalyst the phosphorus and sulfur content in the catalyst increased with the catalyst’s running mileage; adding ethanol to the fuel decreased emissions of paraffins, olefins, and aromatics but increased those of carbonyls; and the ozone formation potential of volatile organic compounds (VOCs) in the tailpipe exhaust was 16.7–17.2% for paraffins, 22–33% for olefins, 26–45% for aromatics, and 4.9–25% for carbonyls.

Highlights

Because of the depletion of fossil fuels, searching for alternative fuels has become essential
This study identified the following catalyst effects: For regulated gasoline, when a new catalyst was used, the CO, HC and NOx in emissions were reduced by 33%, 32%, and 81% when compared with a non-catalyst tailpipe exhaust system; for E15 fuel, the CO, HC and NOx emissions were reduced by 12%, 39%, and 85% when a new catalyst was used when compared to a non-catalyst system
For E30 fuel, the CO, HC and NOx emissions was reduced by 61%, 38%, and 81% when using a new catalyst when compared to a non-catalyst system

Summary

Introduction

Because of the depletion of fossil fuels, searching for alternative fuels has become essential. Transportation is a major fraction of global energy consumption with an energy demand of around 25–27% (Conti et al, 2016; World Energy Council, 2016). This demand is increasing by 1.4% annually (U.S EIA, 2016a). 90% of greenhouse gas is being emitted by the use of gasoline and diesel fuels in the United States (U.S EPA, 2019). The developing countries are contributing to 94% of the growth in the transportation energy sector (de Assis Brasil Weber et al, 2019). World transport energy consumption is set to reach 3906 Mtoe in 2040 (U.S EIA, 2016a).

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