多级燃料氧化化学、烟尘辐射和真实气体性质对压缩点火发动机工作过程的影响

Valentin Y. Basevich, Sergey M. Frolov, Vladislav S. Ivanov, Fedor S. Frolov, Ilya V. Semenov
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引用次数: 0

摘要

研究的目的是揭示多级燃料氧化化学、小(亚毫米大小)燃料液滴燃烧过程中烟灰的热辐射以及真实气体效应对压缩点火发动机工作过程的影响。在零维近似中使用异辛烷的多级氧化化学,揭示了在不同压缩比下冷、蓝和热火焰的不同组合的外观,并提供了这些影响热释放函数的现象的动力学解释。冷火焰是由烷基过氧化氢分解引起的,在此过程中形成了一个非常活跃的自由基OH。蓝色火焰是由H2O2分解生成OH引起的。热火焰是由原子氢和分子氧之间的链支反应形成OH和o而引起的。所谓的“双”冷火焰对应于一个分离的冷火焰和一个低强度的蓝色火焰的顺序出现,而不是两个连续的冷火焰。利用一维燃料液滴加热、蒸发、自燃和在与压缩点火发动机相关的温度和压力下燃烧的模型表明,小液滴(亚毫米大小)燃烧过程中烟灰的热辐射微不足道,可以忽略不计。在柴油机运行过程的三维模拟中,使用了真实气体的热量和热状态方程,证明了真实气体性质对发动机压力图以及NO和烟尘排放的显著影响:真实气体效应使燃烧室最高压力和质量平均温度分别降低了约6%和9%,使自燃延迟时间增加了1.6曲柄角度,最大放热率提高了20%,使NO和烟尘的产率分别降低了2倍和4倍。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Effects of Multistage Fuel-Oxidation Chemistry, Soot Radiation, and Real Gas Properties on the Operation Process of Compression Ignition Engines
The objectives of the study are to reveal the influence of multistage fuel-oxidation chemistry, thermal radiation of soot during the combustion of a small (submillimeter size) fuel droplet, and real gas effects on the operation process of compression ignition engines. The use of the multistage oxidation chemistry of iso-octane in the zero-dimensional approximation reveals the appearance of different combinations of cool, blue, and hot flames at different compression ratios and provides a kinetic interpretation of these phenomena that affect the heat release function. Cool flames are caused by the decomposition of alkyl hydroperoxide, during which a very reactive radical, OH, is formed. Blue flames are caused by the decomposition of H2O2 with the formation of OH. Hot flames are caused by the chain branching reaction between atomic hydrogen and molecular oxygen with the formation of OH and O. So-called “double” cool flames correspond to the sequential appearance of a separated cool flame and a low-intensity blue flame rather than two successive cool flames. The use of a one-dimensional model of fuel droplet heating, evaporation, autoignition, and combustion at temperatures and pressures relevant to compression ignition engines shows that the thermal radiation of soot during the combustion of small (submillimeter size) droplets is insignificant and can be neglected. The use of real gas caloric and thermal equations of state of the matter in a three-dimensional simulation of the operation process in a diesel engine demonstrates the significant effect of real gas properties on the engine pressure diagram and on the NO and soot emissions: real gas effects reduce the maximum pressure and mass-averaged temperature in the combustion chamber by about 6 and 9%, respectively, increases the autoignition delay time by a 1.6 crank angle degree, increase the maximum heat release rate by 20%, and reduce the yields of NO and soot by a factor of 2 and 4, respectively.
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