优化 B20 发动机,减少中型压燃式发动机的温室气体排放

IF 2 Q2 ENGINEERING, MECHANICAL
Taemin Kim, A. Boehman
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引用次数: 0

摘要

与目前采用的农业和工业实践中的石油基柴油相比,以大豆为基础的生物柴油可将单位能量(即 gCO2e/MJ)从油井到车轮的温室气体(GHG)排放量减少 66%-72% 。生物柴油可减少微粒物质和一氧化碳的排放,而氮氧化物排放的增加则在可控范围内。从减少单位行驶距离的温室气体排放量(即 gCO2e/mile)的角度来看,在不调整发动机控制单元(ECU)设置的情况下,在压燃式发动机中使用 B20 无法达到 B20 可以实现的最佳碳减排效果。在全面了解 "燃料 "和 "ECU 校准 "对制动燃油转换效率和其他标准污染物排放的影响的基础上,优化发动机控制设置允许重新校准,以实现最大制动燃油转换效率(BFE)。通过优化 ECU 标定,实验测量了 B20 应用的最大温室气体减排量,从而了解了生物柴油燃料和标定对发动机性能和排放的综合影响。考虑了六种稳定的运行模式,将其结合起来可以估算出美国联邦测试程序 BFE 和联邦测试协议 (FTP) 75 周期内的排放量。结合从这 6 个 "小地图 "测试点模拟 EPA FTP 75 循环的权重系数,使用 B20 调和大豆生物柴油的最终 ECU 标定可使单位行驶距离的能量需求(即 MJ/英里)提高 0.53%,此外,按 "gCO2e/MJ "计算,使用 B20 调和大豆生物柴油的温室气体排放量减少了 12.5%,温室气体总排放量减少了 13%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Greenhouse gas reduction in a medium-duty compression ignition engine with optimization for B20
Soy-based biodiesel can reduce well-to-wheels greenhouse gas (GHG) emissions per unit energy (i.e., gCO2e/MJ) by 66%–72% as compared to the petroleum-based diesel fuel with currently adopted agricultural and industrial practices. Biodiesel can reduce particulate matter and carbon monoxide emissions with a manageable degree of increase in NOx emissions. From the perspective of GHG emissions reduction per unit travelling distance (i.e., gCO2e/mile), the application of B20 in compression ignition engines without the adjustment in engine control unit (ECU) settings will not extract the best carbon emissions reduction that B20 could achieve. Optimizing the engine control settings permits re-calibration to achieve the maximum brake fuel conversion efficiency (BFE) based on comprehensive understanding on the impact of both “fuel” and “ECU calibration” on BFE and other criteria pollutant emissions. The maximum GHG emissions reduction with B20 application is experimentally measured with the optimized ECU calibration, thus providing the understanding of the combined impact of biodiesel fuel and calibrations on engine performance and emissions. Six steady operating modes were considered, that can be combined to estimate the US federal test procedure BFE and emissions over the Federal Test Protocol (FTP) 75 cycle. Combined with the weight factors to simulate the EPA FTP 75 cycle from these 6 “mini-map” test points, 0.53% improvement in the energy requirement per unit traveling distance (i.e., MJ/mile) is achieved for B20 with the final ECU calibration, in addition to the degree of GHG emissions reduction on a “gCO2e/MJ” basis from the use of B20 blend of soy biodiesel of ∼12.5% reduction in gCO2e/MJ, for a total GHG emissions reduction of 13%.
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来源期刊
Frontiers in Mechanical Engineering
Frontiers in Mechanical Engineering Engineering-Industrial and Manufacturing Engineering
CiteScore
4.40
自引率
0.00%
发文量
115
审稿时长
14 weeks
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