Dynamics and mitigation strategies of knock in hydrogen-fueled internal combustion engines

Anye Zhong
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Abstract

In the context of utilizing hydrogen as a fuel for internal combustion engines, it is crucial to address its tendency to induce knock more readily under certain conditions compared to gasoline. Knock not only reduces fuel efficiency but also has the potential to inflict detrimental effects on engine components. It is generally believed that knock is primarily caused by the spontaneous combustion of the end-gas mixture. Current research focuses on the frequency, intensity, and statistical characteristics of knock signals.This study aims to introduce two prevalent and effective methods for mitigating knock: increasing the Exhaust Gas Recirculation (EGR) ratio and water injection into the engine. Experimental observations suggest that at low rotational speeds (n=900 rpm), the amplitude spectra of knock induced by hydrogen and gasoline show similarities. However, at higher speeds (n>3000 rpm), the amplitude of hydrogen-induced knock not only exhibits a greater number of peak values but also intensifies in strength. Notably, the efficacy of increasing the EGR ratio diminishes at high speeds, potentially due to the propensity of methane to also cause knock under high-temperature conditions. In contrast, water injection, while generally effective, may adversely impact the lifespan of engine components.In summary, effective suppression of knock in hydrogen-fueled internal combustion engines is vital for accelerating the adoption of hydrogen in the power sector and making significant contributions to environmental conservation. This paper aims to delve into the analysis of these methods effectiveness and proposes directions for future research.
氢燃料内燃机爆震的动力学和缓解策略
在利用氢气作为内燃机燃料方面,关键是要解决氢气在某些条件下比汽油更容易产生爆震的问题。爆震不仅会降低燃料效率,还有可能对发动机部件造成有害影响。一般认为,爆震主要是由尾气混合物的自燃引起的。目前的研究主要集中在爆震信号的频率、强度和统计特征上。本研究旨在介绍两种普遍有效的缓解爆震的方法:提高废气再循环(EGR)比率和向发动机喷水。实验观察表明,在低转速(n=900 rpm)下,氢气和汽油诱发的爆震振幅谱显示出相似性。然而,在转速较高时(n>3000 rpm),氢气诱导的爆震振幅不仅峰值更多,而且强度也更大。值得注意的是,提高 EGR 比率的效果在高速时会减弱,这可能是由于甲烷在高温条件下也会导致爆震。总之,有效抑制氢燃料内燃机的爆震对于加快氢气在动力领域的应用以及为环境保护做出重大贡献至关重要。本文旨在深入分析这些方法的有效性,并提出未来的研究方向。
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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