Understanding the Influences of Thermal and Mixture Inhomogeneities on the Auto-Ignition Process in a Controlled Auto-Ignition (CAI) Engine Using LES

Oil & Gas Science and Technology-revue De L Institut Francais Du Petrole Pub Date : 2017-11-01 DOI:10.2516/OGST/2017025

Esra Yildar, G. Kuenne, Chao He, R. Schießl, Marc-Sebastian, Benzinger, Marius Neurohr, F. Mare, A. Sadiki, Johannes, Janicka

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引用次数: 3

Abstract

This work applies Large Eddy Simulation (LES) to the combustion process within a CAI engine. The chemical reaction is treated with a pre-tabulation approach based on homogeneous reactor simulations. At this juncture, a five-dimensional chemistry database is employed where the thermo-chemical properties are a function of the unburnt gas temperature, the air–fuel ratio, the exhaust gas ratio, the pressure, and the reaction progress variable. Statistical quantities are gathered for 20 simulated cycles and the averaged pressure curves get compared to measurements. The simulation data are then used to provide further insight into the auto-ignition process. It will be shown how thermo-chemical states are distributed within the cylinder and how the ignition quality depends on them. A statistical analysis is conducted to identify manifolds in the multi-dimensional scalar space along which the conditions leading to ignition evolve. Furthermore the strong influence in between consecutive cycles caused by the exhaust gas is investigated to identify the mechanism of cycle-to-cycle variations.

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利用LES研究热不均匀性和混合气不均匀性对自动点火发动机自动点火过程的影响

本工作将大涡模拟(LES)应用于CAI发动机内的燃烧过程。化学反应采用基于均匀反应器模拟的预制表方法进行处理。此时，采用五维化学数据库，其中热化学性质是未燃烧气体温度、空燃比、废气比、压力和反应过程变量的函数。收集了20个模拟循环的统计量，并将平均压力曲线与测量值进行了比较。然后使用模拟数据来进一步了解自动点火过程。它将显示如何热化学状态分布在气缸和如何点火质量取决于他们。通过统计分析，确定了多维标量空间中导致点火条件演变的流形。此外，还研究了废气对连续循环之间的强烈影响，以确定循环间变化的机制。

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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Oil & Gas Science and Technology-revue De L Institut Francais Du Petrole

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