Experimental Research on an Afterburner System Fueled with Hydrogen–Methane Mixtures

Inventions Pub Date : 2024-04-24 DOI:10.3390/inventions9030046

F. Florean, A. Mangra, Marius Enache, Marius Deaconu, Razvan Ciobanu, R. Carlanescu

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Abstract

A new afterburner installation is proposed, fueled with pure hydrogen (100%H2) or hydrogen–methane mixtures (60% H2 + 40% CH4, 80% H2 + 20% CH4) for use in cogeneration applications. Two prototypes (P1 and P2) with the same expansion angle (45 degrees) were developed and tested. P1 was manufactured by the classic method and P2 by additive manufacturing. Both prototypes were manufactured from Inconel 625. During the tests, analysis of flue gas (CO2, CO, and NO concentration), PIV measurements, and noise measurements were conducted. The flue gas analysis emphasizes that the behavior of the two tested prototypes was very similar. For all three fuels used, the CO2 concentration levels were slightly lower in the case of the additive-manufactured prototype P2. The CO concentration levels were significantly higher in the case of the additive-manufactured prototype P2 when 60% H2/40% CH4 and 80% H2/20% CH4 mixtures were used as fuel. When pure H2 was used as fuel, the measured data suggest that no additional CO was produced during the combustion process, and the level of CO was similar to that from the Garrett micro gas turbine in all five measuring points. The NO emissions gradually decreased as the percentage of H2 in the fuel mixture increased. The NO concentration was significantly lower in the case of the additive-manufactured prototype (P2) in comparison with the classic manufactured prototype (P1). Examining the data obtained from the PIV measurements of the flow within the mixing region shows that the highest axial velocity component value on the centerline was measured for the P1 prototype. The acoustic measurements showed that a higher H2 concentration led to a reduction in noise of approximately 1.5 dB for both afterburner prototypes. The outcomes reveal that the examined V-gutter flame holder prototype flow was smooth, without any perpendicular oscillations, without chaotic motions or turbulent oscillations to the flow direction, across all tested conditions, keeping constant thermal power.

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以氢气-甲烷混合物为燃料的后燃烧器系统实验研究

提出了一种新的后燃烧器装置，以纯氢（100%H2）或氢-甲烷混合物（60% H2 + 40% CH4、80% H2 + 20% CH4）为燃料，用于热电联产应用。开发并测试了两个具有相同膨胀角（45 度）的原型（P1 和 P2）。P1 采用传统方法制造，P2 采用快速成型法制造。两个原型均由铬镍铁合金 625 制成。测试期间，进行了烟气分析（二氧化碳、一氧化碳和一氧化氮浓度）、PIV 测量和噪声测量。烟气分析结果表明，两个测试原型的性能非常相似。在使用的所有三种燃料中，添加剂制造的原型机 P2 的二氧化碳浓度水平略低。当使用 60% H2/40% CH4 和 80% H2/20% CH4 混合物作为燃料时，添加剂制造的原型 P2 的 CO 浓度水平明显更高。当使用纯 H2 作为燃料时，测量数据表明在燃烧过程中不会产生额外的 CO，在所有五个测量点中，CO 的水平与 Garrett 微型燃气轮机的水平相似。随着燃料混合物中 H2 比例的增加，NO 排放量逐渐减少。与传统制造的原型机（P1）相比，添加剂制造的原型机（P2）的 NO 浓度明显较低。通过对混合区域内的气流进行 PIV 测量获得的数据显示，P1 原型机在中心线上测得的轴向速度分量值最高。声学测量结果表明，在两种后燃烧器原型中，较高的 H2 浓度可使噪音降低约 1.5 分贝。结果表明，在所有测试条件下，在保持恒定热功率的情况下，所测试的 V 型沟槽火焰固定器原型流动平稳，没有任何垂直振荡，流动方向没有混乱运动或湍流振荡。

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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Inventions

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