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Emission characteristics of confined non-premixed ammonia–oxygen–nitrogen turbulent jet flames under oxygen-enriched conditions

Yu Xia, Yuxuan Shen, Kodai Sakai, Daichi Matsumoto, Sophie Colson, Taku Kudo, Akihiro Hayakawa, Hideaki Kobayashi

2024Proceedings of the Combustion Institute15 citationsDOIOpen Access PDF

Abstract

As a potential hydrogen energy carrier and a carbon free fuel, various applications of NH 3 are currently being considered. One way to directly use ammonia is to introduce it into industrial furnaces. However, the combustion of ammonia yields a lower flame temperature compared to hydrocarbon fuels, presenting a drawback in applications such as glass melting furnaces that demand particularly high temperatures. Therefore, oxygen-enriched combustion is considered to be used, while its NO x emission characteristics are unknow. Therefore, for the first time, this paper demonstrates the fundamental emission characteristics of confined non-premixed ammonia–oxygen–nitrogen turbulent jet flames under oxygen-enriched conditions. The emission characteristics of the flames were investigated using a Fourier Transform Infrared spectrometer in a combustor with insulated and uninsulated walls over a wide range of global equivalence ratios, ϕ Global , oxygen concentrations in the oxidizer, β O2 , and heat output conditions up to 10 kW. The results indicated that the emissions of non-premixed ammonia–oxygen–nitrogen turbulent jet flames exhibited a premixed flame characteristic, revealing a trade-off relationship between NO and unburned NH 3 . Moreover, there is a specific global equivalence ratio, ϕ optimal , at which NO and unburned NH 3 emissions are minimal. Increasing β O2 and the heat output promotes NO emission in global lean cases and reduces NH 3 emission in global rich cases, further shifting the ϕ optimal to the richer side. Besides, a heat loss by glass liner leads to a significant decrease of furnace temperature and a shift of ϕ optimal to stoichiometric condition. Furthermore, the fundamental non-premixed ammonia–oxygen–nitrogen turbulent jet flame structure was discussed based on counterflow diffusion flame. It was considered that, in applications where the entire ammonia turbulent jet diffusion flame is used, the rich-lean two-stage combustion concept can be applied for low NO x combustion in industrial furnaces even at oxygen-enriched conditions.

Topics & Concepts

OxygenJet (fluid)TurbulenceNitrogenAmmoniaMechanicsMaterials scienceChemistryEnvironmental sciencePhysicsOrganic chemistryCombustion and flame dynamicsAdvanced Combustion Engine TechnologiesAtmospheric chemistry and aerosols