The technologies of improving the process of air-fuel mixture combustion in spark ignition engines

A. Shaikin, I. Galiev, D. A. Pavlov, M. V. Sazonov
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Abstract

The paper considers the turbulence intensity and the fuel chemical composition impact on the flame propagation velocity at the initial and main combustion phases when changing the air-fuel mixture composition. The relevance of the study is caused by the fact that currently, the improvement of conventional engine operation characteristics is mainly achieved through the improvement of the fuel mixture combustion process. However, there are no data on the influence of chemical and gas-dynamic factors on the peculiarities of flame propagation at the initial and main combustion phases. The gas reciprocating internal combustion engine was the object of the research, and the subject of the study was the fuel combustion process. Fuel chemical composition changed due to the promoting addition of hydrogen to the natural gas and variations of the excess-air coefficient. The experiments carried out on the UIT-85 power plant (i.e. under the simulated internal combustion engine conditions) show that the promoting addition of hydrogen stronger influences the flame velocity in the initial combustion phase compared to the second combustion phase, as a combustion source in the first phase is a laminar flame bent front and depends only on chemical and thermo-physical properties of the fuel-air mixture. The analysis of experimental data showed the dual impact of turbulence intensity on the flame propagation velocity. In particular, at the beginning of the combustion process, the fluctuating velocity scarcely influences the flame propagation velocity, as opposed to the main combustion phase, where the flame propagation velocity increases at the increase of turbulence intensity.
改进火花点火发动机空气燃料混合气燃烧过程的技术
本文考虑了改变空气-燃料混合成分时,湍流强度和燃料化学成分对燃烧初期和主燃烧阶段火焰传播速度的影响。研究的相关性是由于目前常规发动机工作特性的改善主要是通过改进燃油混合气燃烧过程来实现的。然而,没有关于化学和气体动力学因素对燃烧初期和主燃烧阶段火焰传播特性影响的数据。以燃气往复式内燃机为研究对象,研究对象为燃料燃烧过程。燃料化学成分的变化是由于天然气中氢的加入和过量空气系数的变化引起的。在unit -85电厂(即在模拟内燃机条件下)进行的实验表明,由于第一阶段的燃烧源是层流火焰弯曲前缘,仅取决于燃料-空气混合物的化学和热物理性质,因此促进氢的添加对燃烧初始阶段的火焰速度的影响比第二燃烧阶段更大。对实验数据的分析表明,湍流强度对火焰传播速度有双重影响。特别是在燃烧初期,波动速度对火焰传播速度几乎没有影响,而在主燃烧阶段,随着湍流强度的增加,火焰传播速度增加。
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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