A numerical investigation of high pressure, counterflow methane-air partially premixed flames (PPFs) is presented to characterize the effect of pressure on flame structure. Four different mechanisms, namely GRI-2.11, GRI-3.0, the San Diego, and the C{sub}2 mechanisms have been examined. The mechanisms have been validated by comparing the predicted laminar flame speeds with experimental data. While there is excellent agreement between the measured and predicted laminar flame speeds based on these mechanisms, there are noticeable discrepancies amongst the mechanisms for the prediction of high-pressure PPFs. The GRI 3.0 mechanism is used to examine the detailed PPF structure at elevated pressures. At low pressures, the PPF exhibits a typical double flame structure that consists of rich premixed and nonpremixed reaction zones, and the separation distance between the reaction zones decreases with increasing pressure. However, for pressure above 10 atm, the separation distance becomes nearly independent of pressure. In addition, a critical pressure is observed, above which the PPF structure exhibits anomalous behavior, characterized by the presence of endothermic reactions and the production of CO in the region between the two reaction zones. A rate of production analysis revealed that the anomalous behavior is attributable to the following reactions: H + H{sub}2O → OH + H{sub}2 and CH{sub}2CO + M → CH{sub}2 + CO + M.
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机译:提出了高压,逆流甲烷 - 空气部分预混火焰(PPFS)的数值研究,以表征压力对火焰结构的影响。已经检查了四种不同的机制,即GRI-2.11,GRI-3.0,SAN Diego和C {Sub} 2机制。通过将预测的层流火焰速度与实验数据进行比较,已经验证了该机制。虽然基于这些机制,测量和预测的层状火焰速度之间存在很好的一致性,但是在预测高压PPFS的机制中存在明显的差异。 GRI 3.0机构用于检查升高压力下的详细PPF结构。在低压下,PPF呈现出典型的双火焰结构,该结构由富含预混和非增速的反应区组成,并且反应区之间的分离距离随着压力的增加而降低。然而,对于高于10atm的压力,分离距离变得几乎与压力无关。此外,观察到临界压力,上述PPF结构表现出异常行为,其特征在于存在吸热反应和两种反应区之间的区域中的CO的产生。生产分析速率揭示了异常行为可归因于以下反应:H + H {Sub} 2O→OH + H {SUB} 2和CH {SUB} 2CO + M→CH {SUB} 2 + CO + M 。
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