An Innovative Argon/Miller Power Cycle for Internal Combustion Engine: Thermodynamic Analysis of its Efficiency and Power Density

IF 4.8 1区 工程技术 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC Automotive Innovation Pub Date : 2023-01-05 DOI:10.1007/s42154-022-00208-x
Chenxu Wang, Shaoye Jin, Jun Deng, Liguang Li
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引用次数: 4

Abstract

Increasing efficiency and reducing emissions are fundamental approaches to achieving peak carbon emissions and carbon neutrality for the transportation and power industries. The Argon power cycle (APC) is a novel concept for high efficiency and zero emissions. However, APC faces the challenges of severe knock and low power density at high efficiency. To elevate efficiency and power density simultaneously of APC, the Miller cycle is applied and combined with APC. The calculation method is based on a modification of the previous thermodynamic method. The mixture of hydrogen and oxygen is controlled in the stoichiometric ratio. The results indicate that to obtain a thermal conversion efficiency of 70%, in the Otto cycle, the compression ratio and the AR (argon molar ratio in the argon-oxygen mixture) could be 9 and 95%, respectively. In comparison, for the Miller cycle, these two parameters only need to be 7 and 91%. A lower compression ratio can reduce the negative effect of knock, and a reduced AR increases the power density by 66% with the same efficiency. The improvement effect is significant when the expansion-compression ratio is 1.5. Meanwhile, increasing the expansion-compression ratio is more effective in the argon-oxygen mixture than in the nitrogen–oxygen mixture. For the next-generation Argon/Miller power cycle engine, the feasible design to achieve the indicated thermal efficiency of 58.6% should be a compression ratio of 11, an expansion-compression ratio of 1.5, and an AR of 91%.

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一种创新的氩气/米勒动力循环内燃机:其效率和功率密度的热力学分析
提高效率和减少排放是交通和电力行业实现碳排放峰值和碳中和的根本途径。氩气动力循环(APC)是一种高效、零排放的新概念。然而,APC在高效率下面临严重爆震和低功率密度的挑战。为了同时提高APC的效率和功率密度,采用米勒循环并与APC相结合。该计算方法是在原有热力学方法的基础上改进而来的。氢和氧的混合物被控制在一定的化学计量比内。结果表明,为了获得70%的热转换效率,在奥托循环中,压缩比和AR(氩氧混合物中氩的摩尔比)分别为9和95%。相比之下,对于米勒周期,这两个参数只需要为7和91%。较低的压缩比可以减少爆震的负面影响,在相同的效率下,降低的AR可使功率密度提高66%。膨胀压缩比为1.5时,改善效果显著。同时,增大膨胀压缩比在氩氧混合物中比在氮氧混合物中更有效。对于下一代Argon/Miller动力循环发动机,实现58.6%的热效率的可行设计应该是压缩比为11,膨胀压缩比为1.5,AR为91%。
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来源期刊
Automotive Innovation
Automotive Innovation Engineering-Automotive Engineering
CiteScore
8.50
自引率
4.90%
发文量
36
期刊介绍: Automotive Innovation is dedicated to the publication of innovative findings in the automotive field as well as other related disciplines, covering the principles, methodologies, theoretical studies, experimental studies, product engineering and engineering application. The main topics include but are not limited to: energy-saving, electrification, intelligent and connected, new energy vehicle, safety and lightweight technologies. The journal presents the latest trend and advances of automotive technology.
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