Intrinsic instability of lean hydrogen/ammonia premixed flames: Influence of Soret effect and pressure

Fuel Communications Pub Date : 2024-03-15 DOI:10.1016/j.jfueco.2024.100110

F. D’Alessio, C. Matteucci, P.E. Lapenna, F. Creta

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Abstract

The addition of hydrogen in ammonia/air mixtures can lead to the onset of intrinsic flame instabilities at conditions of technical relevance. The length and time scales of intrinsic instabilities can be estimated by means of linear stability analysis of planar premixed flames by evaluating the dispersion relation. In this work, we perform such linear stability analysis for hydrogen-enriched ammonia/air flames (50%H2-50%NH3 by volume) using direct numerical simulation with a detailed chemical kinetic mechanism. The impact of pressure and the inclusion of the Soret effect in the governing equations is assessed by comparing the resulting dispersion relation at atmospheric pressure and 10 atm. Our data indicate that both pressure and the Soret effects promote the onset of intrinsic instabilities. Comparisons with available numerical literature data as well as theoretical models are also discussed.

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贫氢/氨预混合火焰的内在不稳定性：索雷特效应和压力的影响

在氨气/空气混合物中加入氢气会导致火焰在技术条件下出现内在不稳定性。本征不稳定性的长度和时间尺度可以通过对平面预混合火焰进行线性稳定性分析，评估分散关系来估算。在这项工作中，我们利用详细的化学动力学机制，通过直接数值模拟对富氢氨/空气火焰（体积比为 50%H2-50%NH3 ）进行了这种线性稳定性分析。通过比较大气压和 10 atm 时的分散关系，评估了压力和将索雷特效应纳入控制方程的影响。我们的数据表明，压力和索雷特效应都会促进本征不稳定性的发生。我们还讨论了与现有数值文献数据和理论模型的比较。

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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Fuel Communications

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