Effective measures to improve thermal efficiency of medium-sized diesel engine in practical application: Energy-exergy analysis and test verification

Haozhong Huang, Yi Wang, Chengzhong Zhou, Xiaoyu Guo, Kong Xing
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Abstract

As the fourth stage of China’s fuel consumption limits for heavy commercial approaches, engine manufacturers are facing huge challenges. Here, the impact of different strategies on brake thermal efficiency (BTE) was studied through experiments and simulations, and the main energy loss items were obtained based on energy and exergy analysis. According to experimental results, the removal of exhaust gas recirculation (EGR) mainly reduced exhaust losses, resulting in a 0.5% increase in BTE at 1200 r/min. Turbocharger scheme 2, with a high flow rate and high efficiency, was beneficial in reducing pumping losses. Owing to consistent brake power, simultaneously increasing the compression ratio and peak firing pressure can reduce the exhaust losses and combustion irreversibility. When fuel injection quantity was constant, the use of high flow injectors could advance CA50, thereby increasing output power and reducing exhaust losses. Finally, the actual development of the new engine was completed, and the test results showed that the maximum BTE reached 46.9%, and CO and soot emissions were reduced by 74.2% and 78.3%, respectively. Therefore, for medium-sized diesel engines, adopting the non-EGR route, using high flow turbochargers and injectors, and increasing compression ratio can effectively improve BTE and reduce carbon emissions.
在实际应用中提高中型柴油机热效率的有效措施:能效分析与测试验证
随着中国第四阶段重型商用车油耗限值的临近,发动机制造商面临着巨大的挑战。本文通过实验和模拟研究了不同策略对制动热效率(BTE)的影响,并根据能量和放能分析得出了主要的能量损失项目。实验结果表明,取消废气再循环(EGR)主要减少了排气损失,使 BTE 在 1200 r/min 时提高了 0.5%。高流量和高效率的涡轮增压器方案 2 有利于减少泵送损失。由于制动功率稳定,同时提高压缩比和峰值点火压力可减少排气损失和燃烧不可逆性。在燃油喷射量不变的情况下,使用大流量喷油器可使 CA50 提前,从而提高输出功率并减少排气损失。最后,新发动机的实际开发工作已经完成,测试结果表明,最大 BTE 达到 46.9%,CO 和烟尘排放量分别减少了 74.2% 和 78.3%。因此,对于中型柴油发动机而言,采用非 EGR 路线、使用大流量涡轮增压器和喷油器以及提高压缩比可以有效提高 BTE 并减少碳排放。
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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