CFD Analysis of the Combustion of Hydrogen Fuel on a CFM56-3 Combustor

Volume 3: Advanced Materials: Design, Processing, Characterization and Applications; Advances in Aerospace Technology Pub Date : 2022-10-30 DOI:10.1115/imece2022-95371

R. Domingues, F. Brójo, Pedro Oliveira

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Abstract

In the present work is made an overview of the use of hydrogen in aviation, the modifications needed to convert a conventional gas turbine to use hydrogen and a CFD simulation of an existent gas turbine burning hydrogen. The CFD simulation was done in a CFM56-3 combustor burning Jet A (as a reference standard) and hydrogen, with the intention of evaluate the viability of conversion of existent gas turbines to hydrogen, in a combustion point of view, by analyzing the emissions through ICAO’s LTO cycle while burning this fuel. ANSYS Fluent 2020R2 was the software used to perform the numerical study. The RSM was the viscous model used. Only the NOx emissions were assessed as pollutant once the hydrogen combustion products are reduced to water vapor and NOx. These emissions were evaluated through a detailed mechanism and the NOx model available on ANSYS to get a better concordance with the ICAO’s values. During this study, several sensibility studies were carried out for hydrogen burn, for instance, the analysis of the air flow with/without swirl in the primary zone and different inlet pressure and temperature for fuel.

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CFM56-3燃烧室氢燃料燃烧的CFD分析

本文概述了氢在航空领域的应用，将传统燃气轮机转换为氢轮机所需要的改进，并对现有燃气轮机进行了CFD模拟。CFD模拟在CFM56-3燃烧室中进行，燃烧Jet a(作为参考标准)和氢气，目的是通过分析ICAO LTO循环燃烧该燃料时的排放，从燃烧的角度评估现有燃气轮机转换为氢气的可行性。采用ANSYS Fluent 2020R2软件进行数值研究。RSM是使用的粘性模型。一旦氢燃烧产物还原为水蒸气和NOx，则仅将NOx排放评估为污染物。这些排放通过详细的机制和ANSYS上可用的NOx模型进行评估，以获得与ICAO值更好的一致性。在研究过程中，对氢气燃烧的敏感性进行了研究，例如分析了主区有/没有涡流的气流以及不同的燃料入口压力和温度。

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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Volume 3: Advanced Materials: Design, Processing, Characterization and Applications; Advances in Aerospace Technology

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