Prediction of CO emissions in turbulent super lean premixed combustion under pressurized conditions using an LES/non-adiabatic FGM approach

K. Yunoki, T. Nishiie, R. Kurose
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引用次数: 1

Abstract

A large eddy simulation (LES) employing a non-adiabatic flamelet generated manifolds (NA-FGM) approach, which can account for the effects of heat loss, is applied to CH 4 -air super lean premixed combustion fields generated by an axisymmetric jet burner with cooled walls under pressurized conditions. In addition, the validity in predicting the CO emissions is examined. The NA-FGM approach captures the trends of CO emissions well during the experiments, in which the CO emissions increase with a decreasing equivalence ratio. It is shown that the increase in CO emissions for low equivalence ratios is not due to the increase in the CO production, but to the slow rate of CO consumption, which keeps the CO concentration high downstream. The results suggest that capturing such a sensitive reduction of CO consumption rate by heat loss is important for accurately predicting the CO emissions in developing a low-emissions gas turbine combustor at low load.
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利用LES/非绝热FGM方法预测加压条件下湍流超贫预混燃烧CO排放
采用考虑热损失影响的非绝热火焰生成歧管(NA-FGM)方法,对增压条件下由冷却壁面的轴对称射流燃烧器产生的ch4 -空气超稀薄预混燃烧场进行了大涡模拟。此外,还检验了该方法预测二氧化碳排放的有效性。NA-FGM方法较好地捕捉了实验过程中CO排放量的变化趋势,CO排放量随等效比的减小而增加。结果表明,低当量比时CO排放量的增加不是由于CO产量的增加,而是由于CO消耗速度缓慢,这使得下游的CO浓度保持在较高水平。结果表明,在开发低负荷低排放燃气轮机燃烧室时,通过热损失捕捉CO消耗率的敏感降低对于准确预测CO排放具有重要意义。
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CiteScore
1.80
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0.00%
发文量
2
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