氨在全球能源转型中的作用：氨燃气轮机技术的机遇与挑战

IF 7.5 1区工程技术 Q2 ENERGY & FUELS

Fuel Pub Date : 2025-10-10 DOI:10.1016/j.fuel.2025.136951

Shuai Chen, Bin Guan, Lei Zhu, Zhongqi Zhuang, Xuehan Hu, Chenyu Zhu, Sikai Zhao, Junyan Chen, Junjie Gao, Kaiyou Shu, Hongtao Dang, Luyang Zhang, Tiankui Zhu, Yuan Li, Luoxin Xu, Wenbo Zeng, Linhui Wang, Can Zhu, Jiaming He, Qinghan Xian, Zhen Huang

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引用次数: 0

摘要

在全球能源需求持续激增的背景下，对化石燃料的过度依赖导致环境污染和气候问题日益严重，迫切需要推动能源可持续转型。氨作为一种具有零碳排放特性的氢能载体，以其优越的能量密度和便捷的储运优势，在发电领域和交通运输系统中具有重要的应用价值。目前，氨燃料燃气轮机技术的发展仍面临着氮氧化物（NOx）排放增加、燃烧性能差、火焰稳定性不足、材料性能退化等诸多挑战。本文系统整合了氨作为能源载体的完整技术链条——包括合成、燃烧、排放控制和材料技术，梳理了氨燃气轮机技术的发展脉络、现状和未来趋势。该技术的核心优势在于其清洁燃烧特性和与现有基础设施的兼容性；然而，诸如氮氧化物控制和燃烧稳定性等技术障碍仍需克服。创新的解决方案，包括氨-氢共燃烧、氨-甲烷共燃烧、选择性催化还原（SCR）、富贫燃烧技术、等离子体辅助燃烧和新材料的开发，有望解决这些问题。IM270氨燃气轮机项目、三菱重工示范项目等具有代表性的实际案例标志着氨燃气轮机系统商业应用取得突破性进展。展望未来，可再生能源系统与人工智能驱动系统优化的整合将显著提升氨燃气轮机技术的效率。

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The role of ammonia in the global energy transition: opportunities and challenges in ammonia gas turbine technology

Against the backdrop of the continuous global surge in energy demand, excessive reliance on fossil fuels has led to increasingly severe environmental pollution and climate issues, making the promotion of sustainable energy transition urgently needed. As a hydrogen energy carrier with zero carbon emission characteristics, ammonia demonstrates significant application value in the power generation sector and transportation systems, thanks to its superior energy density and convenient storage and transportation advantages. Currently, the development of ammonia-fueled gas turbine technology still faces numerous challenges, including increased nitrogen oxide (NO_x) emissions, poor combustion performance, insufficient flame stability, and material performance degradation. This paper systematically integrates the complete technical chain of ammonia as an energy carrier—covering synthesis, combustion, emission control, and material technologies—and sorts out the development context, current status, and future trends of ammonia gas turbine technology. The core advantages of this technology lie in its clean combustion characteristics and compatibility with existing infrastructure; however, technical barriers such as NO_x control and combustion stability still need to be overcome. Innovative solutions, including ammonia-hydrogen co-combustion, ammonia-methane co-combustion, selective catalytic reduction (SCR), rich-lean combustion technology, plasma-assisted combustion, and the development of new materials, are expected to address these issues. Representative practical cases such as the IM270 Ammonia Gas Turbine Project and the Mitsubishi Heavy Industries Demonstration Project mark breakthrough progress in the commercial application of ammonia gas turbine systems. Looking ahead, the integration of renewable energy systems and artificial intelligence-driven system optimization will significantly enhance the efficiency of ammonia gas turbine technology.

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来源期刊

Fuel 工程技术-工程：化工

CiteScore

12.80

自引率

20.30%

发文量

3506

审稿时长

64 days

期刊介绍： The exploration of energy sources remains a critical matter of study. For the past nine decades, fuel has consistently held the forefront in primary research efforts within the field of energy science. This area of investigation encompasses a wide range of subjects, with a particular emphasis on emerging concerns like environmental factors and pollution.