Characteristics of Premixed Ammonia/Methane/Air Blends as an Alternative Fuel in a Swirl-Stabilized Gas Turbine Combustor Under Varying Pilot Percentage

Meghna Das Chaudhury, Abinash Sahoo, Kaushik Nonavinakere Vinod, Wesley Fisher, S. Ekkad, Venkat Narayanaswamy, Tiegang Fang
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Abstract

Alternative low carbon fuel blends are a promising way towards clean energy transition in the transportation and power generation sectors. In this work, the objective was to study the combustion characteristics of one such low carbon fuel blend (premixed Ammonia, Methane and Air) in a swirl stabilized Gas Turbine Can Combustor under varying % of pilot fuel flow (= 8 % to 10 % of the main fuel flow rate) at atmospheric pressure conditions. Pure Methane was used as the pilot flame which helped in the ignition and stabilization of the main flame and was kept on throughout the experiment. Different volume % of Ammonia and Methane blends were analyzed (starting from 10 to 50 % Ammonia in the fuel blend and the rest being Methane) at Reynolds number of the incoming air ~ 50000, and at equivalence ratio = 0.6 and 0.7. Characteristics such as Combustor liner wall heat load and flame stability were studied using the Infrared Thermography technique and High-Speed flame imaging respectively. Additionally, both carbon and NOx emission trends were estimated for selected cases using the CONVERGE CFD software under steady state conditions incorporating the RANS RNG k-ε and SAGE modeling techniques. Among all cases, wall heat load was observed to be the least for the 50 % Ammonia-50 % Methane case and for cases under reduced pilot %. Also, under reduced pilot %, flames were mostly unstable wherein the manifestation of instabilities at equivalence ratio = 0.6 and 0.7 were markedly different from one another.
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漩涡稳定燃气轮机燃烧器中作为替代燃料的预混氨/甲烷/空气混合物在不同引气比例下的特性
替代性低碳混合燃料是运输和发电行业实现清洁能源转型的一条大有可为的途径。在这项工作中,我们的目标是研究在常压条件下,在漩涡稳定燃气轮机罐式燃烧器中,不同%的先导燃料流量(=主燃料流量的 8% 至 10%)下,一种低碳混合燃料(预混合氨气、甲烷和空气)的燃烧特性。纯甲烷被用作先导火焰,它有助于主火焰的点燃和稳定,并在整个实验过程中持续燃烧。在进气雷诺数 ~ 50000 和等效比 = 0.6 和 0.7 的条件下,对不同体积百分比的氨和甲烷混合物(混合燃料中氨的比例从 10% 到 50%,其余为甲烷)进行了分析。分别使用红外热成像技术和高速火焰成像技术研究了燃烧器衬壁热负荷和火焰稳定性等特性。此外,利用 CONVERGE CFD 软件,结合 RANS RNG k-ε 和 SAGE 建模技术,在稳态条件下对选定案例的碳和氮氧化物排放趋势进行了估计。在所有情况下,观察到 50% 氨气-50% 甲烷情况下和降低先导百分比情况下的壁面热负荷最小。此外,在先导率降低的情况下,火焰大多不稳定,其中等效比 = 0.6 和 0.7 时的不稳定性表现明显不同。
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