使用预混高氢天然气混合物的多喷嘴燃烧器的氮氧化物排放评估

Alexander Jaeschke, Bernhard Ćosić, Dominik Wassmer, C. O. Paschereit
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引用次数: 0

摘要

燃气轮机燃烧的去碳化迫切要求为燃烧过程提供新的技术解决方案。虽然改用氢燃料可以解决碳排放和相关污染物的问题,但由于其反应活性增加,也会导致漩涡稳定燃烧器的稳定性问题。然而,利用喷射火焰燃烧器系统,即使在 100% 氢燃料的预混合燃烧中,也能以较高的轴向流速实现所需的回火安全性。然而,要开发出这样的工程解决方案,需要付出巨大的努力,才能达到当今漩涡燃烧器的成熟度。本研究考察了预混合多管喷射燃烧器在从纯天然气到纯氢燃料的体积混合范围内管理化学反应性变化的能力。在大气测试中对氮氧化物排放进行了测量和分析。排放量的变化不仅源于燃烧化学性质的改变,还源于火焰形状和湍流强度的变化。为了更深入地了解氮氧化物的形成过程,设计了一个低阶模型,并与技术燃烧和完全预混燃烧试验的实验数据进行了比较。对低阶模型进行参数变化,以评估对多喷射燃烧器氮氧化物排放产生的影响。模型所需的燃烧过程信息是通过计算和实验获得的。因此,对火焰图像进行了记录和分析。
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Nox Emissions Assessment of a Multi Jet Burner Operated with Premixed High Hydrogen Natural Gas Blends
Decarbonization of gas turbine combustion creates a pressing demand for new technical solutions for the combustion process. While switching to hydrogen fuels may solve the problem of carbon emissions and associated pollutants it can also lead to stability issues for swirl-stabilized combustors due to its increased reactivity. However, with jet flame burner systems, the required flashback safety can be achieved with high axial flow velocities even for premixed combustion of 100% hydrogen fuel. The development of such an engineering solution, however, requires significant effort to reach the maturity of today's swirl burners. This study examines the capacity of a premixed multi-tube jet burner to manage the chemical reactivity change over a range of volumetric blends from pure natural gas to pure hydrogen fuel. NOx emissions are measured and analyzed for atmospheric tests. The changes in emissions originate not only from altered combustion chemistry but also from changes in flame shape and turbulence intensity. To get a deeper understanding of the NOx formation process, a low-order model is designed and compared to the experimental data of technically and perfectly premixed combustion tests. Parameter variations of the low-order model are conducted to assess the influences on the NOx emission production of the multi jet burner. The information on the combustion process required for the model is obtained computationally and experimentally. Therefore, flame images are recorded and analyzed.
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