Numerical one-dimensional investigations on a multi-cylinder spark ignition engine using hydrogen/ethanol, hydrogen/methanol and gasoline in dual fuel mode

IF 2.8 Q3 ENVIRONMENTAL SCIENCES
Ufaith Qadiri
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Abstract

This study enhances the application of alternative fuels—specifically hydrogen, methanol, and ethanol—in a multi-cylinder gasoline engine. Using the one-dimensional simulation software AVL Boost, the study aims to predict the performance and emission characteristics of two distinct blends: hydrogen (10%) blended with methanol (90%) and hydrogen (10%) blended with ethanol (90%), in comparison to the baseline of 100% gasoline. The multi-cylinder spark ignition engine operates at variable speed under constant load conditions. The analysis of combustion characteristics involves monitoring pressure at different crank angles for all fuels. The anticipated performance parameters include power, torque, brake specific fuel consumption (BSFC), and brake mean effective pressure (BMEP). Notably, among the blended fuels, the hydrogen/ethanol blend exhibited superior efficiency, with a 20% increase in power compared to the hydrogen/methanol blend. The 90% ethanol with 10% hydrogen blend and the 90% methanol with 10% hydrogen blend both showed improved performance and contributed to reduced emissions compared to the 100% gasoline fuel. Favourable results were observed for CO, HC, and NOx emissions. While hydrogen combustion is carbon-free, the addition of ethanol and methanol led to slight carbon-based emissions, with a marginal increase in NOx for the hydrogen/methanol blend compared to the 100% gasoline fuel.

Abstract Image

使用氢气/乙醇、氢气/甲醇和汽油双燃料模式的多缸火花点火发动机的一维数值研究
本研究加强了替代燃料(特别是氢、甲醇和乙醇)在多缸汽油发动机中的应用。该研究使用一维模拟软件 AVL Boost,旨在预测两种不同混合燃料的性能和排放特性:氢气(10%)与甲醇(90%)混合和氢气(10%)与乙醇(90%)混合,并与基准的 100% 汽油进行比较。多缸火花点火发动机在恒定负荷条件下以变速运行。燃烧特性分析包括监测所有燃料在不同曲柄角度下的压力。预期的性能参数包括功率、扭矩、制动比油耗(BSFC)和制动平均有效压力(BMEP)。值得注意的是,在混合燃料中,氢/乙醇混合燃料的效率更高,功率比氢/甲醇混合燃料提高了 20%。与 100% 的汽油燃料相比,90% 的乙醇与 10% 的氢混合燃料和 90% 的甲醇与 10% 的氢混合燃料都提高了性能,并减少了排放。在一氧化碳、碳氢化合物和氮氧化物排放方面都取得了良好的效果。虽然氢燃烧不含碳,但添加乙醇和甲醇会导致轻微的碳排放,与 100% 汽油燃料相比,氢/甲醇混合燃料的氮氧化物略有增加。
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CiteScore
2.90
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0.00%
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