A numerical investigation on the effect of altering compression ratio, injection timing, and injection duration on the performance of a diesel engine fuelled with diesel-biodiesel-butanol blend

IF 2.9 4区 环境科学与生态学 Q3 ENERGY & FUELS Clean Energy Pub Date : 2024-07-10 DOI:10.1093/ce/zkae055
Abdulkarim Youssef, Amr Ibrahim
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Abstract

Using renewable fuels for diesel engines can reduce both air pollution and dependence on fossil fuels. A computer simulation was constructed to predict the performance, combustion characteristics, and NOx emission of a diesel engine fuelled with diesel-biodiesel-butanol blends. The simulation was validated by comparing the modeling results against experimental data and a good agreement between the results was found. The fuels used for the validation were diesel (B0), biodiesel (B100), diesel-biodiesel blend (B50), and two diesel-biodiesel-butanol blends with 45% diesel-45% biodiesel-10% butanol (Bu10), and 40% diesel-40% biodiesel-20% butanol (Bu20) by volume. Experimental results showed that the addition of butanol reduced NOx emissions but deteriorated the engine performance. The aim of the current work was the numerical optimization of the different parameters to enhance the engine performance while using butanol to decrease NOx emissions. The engine compression ratio (CR) varied from 14 to 24, in increments of 2. Fuel injection timing (IT) was retarded from 30° before top dead center (bTDC) to 5° bTDC in increments of 5o. Also, the fuel injection duration (IDur) was extended from 20° to 50° in increments of 10°. Results showed that the increase in CR improved engine performance for the two investigated fuels, Bu10 and Bu20. The maximum engine brake power (BP), thermal efficiency (BTE), and minimum brake-specific fuel consumption (BSFC) of 1.46 kW, 32.3%, and 0.273 kg/kWh respectively, were obtained when the Bu10 fuel was injected at the optimum conditions of 24 CR, 15°bTDC IT, and 40° injection duration (IDur). Under these optimum conditions, the BP, BTE, and BSFC improved by 3% to 3.5% for Bu10 and Bu20 fuel blends compared to the base engine conditions of CR of 22, 30° IDur, and 10° bTDC IT. The heat release rate during the premixed phase increased when the IT was advanced, while the mixing-controlled combustion phase was enhanced when the IT was retarded. NOx emissions increased with increasing the CR, while both the increase in IDur at constant IT and the retard of IT decreased engine NOx emissions. At the optimum conditions, the NOx emissions for Bu10 and Bu20 were further decreased by 2.2% and 0.9% respectively compared to the experimental results at base engine conditions. Retarding the injection timing from 15° bTDC to 5° bTDC at a CR of 24 and IDur of 40° caused the NOx emissions for Bu10 and Bu20 to decrease by 16%. When the injection duration was increased from 20° to 50° at a CR of 24 and an IT of 15°bTDC, the NOx emissions for Bu10 and Bu20 decreased by 12.3% and 11.8% respectively. The addition of butanol to the diesel-biodiesel blend at optimum conditions showed results comparable to pure diesel, with a decrease in NOx emissions.
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关于改变压缩比、喷油时间和喷油持续时间对柴油-生物柴油-丁醇混合燃料柴油发动机性能影响的数值研究
柴油发动机使用可再生燃料可以减少空气污染和对化石燃料的依赖。为了预测柴油-生物柴油-丁醇混合燃料柴油发动机的性能、燃烧特性和氮氧化物排放,我们构建了一个计算机模拟模型。通过将建模结果与实验数据进行比较,对模拟结果进行了验证,发现两者之间具有良好的一致性。用于验证的燃料包括柴油(B0)、生物柴油(B100)、柴油-生物柴油混合物(B50)以及两种柴油-生物柴油-丁醇混合物:体积百分比为 45% 的柴油-45% 的生物柴油-10% 的丁醇(Bu10)和体积百分比为 40% 的柴油-40% 的生物柴油-20% 的丁醇(Bu20)。实验结果表明,添加丁醇可减少氮氧化物的排放,但会降低发动机的性能。当前工作的目的是对不同参数进行数值优化,在使用丁醇降低氮氧化物排放的同时提高发动机性能。发动机压缩比(CR)从 14 变化到 24,增量为 2。 燃料喷射正时(IT)从顶死中心(bTDC)前 30° 延迟到顶死中心(bTDC)前 5°,增量为 5o。此外,喷油持续时间(IDur)从 20° 延长到 50°,每 10° 为一个增量。结果表明,对于 Bu10 和 Bu20 这两种研究燃料,CR 的增加改善了发动机性能。在 24 CR、15°bTDC IT 和 40° 喷射持续时间 (IDur) 的最佳条件下喷射 Bu10 燃料时,发动机的最大制动功率 (BP)、热效率 (BTE) 和最小制动油耗 (BSFC) 分别为 1.46 kW、32.3% 和 0.273 kg/kWh。在这些最佳条件下,与 CR 为 22、IDur 为 30° 和 IT 为 10° bTDC 的基本发动机条件相比,Bu10 和 Bu20 混合燃料的 BP、BTE 和 BSFC 分别提高了 3% 至 3.5%。当 IT 提前时,预混阶段的热释放率增加,而当 IT 推迟时,混合控制燃烧阶段的热释放率增加。氮氧化物排放量随着 CR 的增加而增加,而在 IT 不变的情况下增加 IDur 和延缓 IT 都会减少发动机的氮氧化物排放量。在最佳工况下,Bu10 和 Bu20 的氮氧化物排放量比发动机基本工况下的实验结果分别减少了 2.2% 和 0.9%。在 CR 为 24 和 IDur 为 40 的条件下,将喷油正时从 15° bTDC 推迟到 5° bTDC,可使 Bu10 和 Bu20 的氮氧化物排放量减少 16%。当 CR 为 24、IT 为 15°bTDC 时,喷射时间从 20° 增加到 50° 时,Bu10 和 Bu20 的氮氧化物排放量分别减少了 12.3% 和 11.8%。在最佳条件下向柴油-生物柴油混合物中添加丁醇,结果与纯柴油相当,氮氧化物排放量减少。
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
Clean Energy
Clean Energy Environmental Science-Management, Monitoring, Policy and Law
CiteScore
4.00
自引率
13.00%
发文量
55
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