Experimental and Computational Study for Reduction of NOx Emissions in the Ammonia / Methane Co-Combustion in a 10 KW Furnace

Ryuichi Murai*, Ryohei Omori, Takahiro Kitano, Hidetaka Higashino, Noriaki Nakatsuka, Fumiteru Akamatsu, Osaka University, Japan; Yuya Yoshizuru, UBE Industries, Japan; Jun Hayashi, Kyoto University, Japan

15th Annual NH3 Fuel Conference, Pittsburgh, PA, October 31, 2018
NH3 Energy+ Topical Conference at the AIChE Annual Meeting


There are severe issues on increasing amount of carbon dioxide (CO2) emission in the world. Many studies are devoted to alternative fuels. One of promising candidates is the utilization of ammonia which is zero emission of CO2, a hydrogen energy carrier, and also can be burned directly as a fuel.

For direct combustion of ammonia in industrial furnaces, there were two issues which were weaker radiative heat flux and a huge amount of NOx emission compared with the combustion of methane. We already have reported [1] the solution of the former issue by using the oxygen enriched combustion.

The objective of this research is to study the reduction mechanism of NOx emissions in the ammonia / methane co-combustion in an industrial furnace both experimentally and numerically. Experimentally we measured the radiation spectra and the total radiative thermal flux under the condition of the ammonia fuel burned in a 10 kW furnace with a coaxial jet flame and additional two oxidizer inlets for the staging combustion. The spectrum measurement results show that the amount of NOx emission was in reverse proportion with the intensity of N2O spectrum in the downstream of the reaction zone in the furnace. This indicates that N2O, which is one of main intermediate species of NH3, reacts with NOx as a reduction reactant to nitrogen molecule.

Numerical simulations were performed to clarify these hypotheses. Firstly we carried out the simulation to overview the combustion in the whole area of a furnace, with the condition of three dimensions, eddy dissipation concept model in the turbulent combustion and GRI-Mech3.0 in the ammonia and methane reaction. In addition, the two dimensional simulation with Okafor mechanism [2] was conducted to research the combustion process in detail.

When the amount of NOx emission was smaller at the furnace exit, more N2O existed in the middle region of the furnace. This simulation could explain the experimental data with good agreement.

[1] R. Murai et al, The radiative characteristics of NH3/N2/O2 non-premixed flame on a 10 kW test furnace, Energy Procedia, vol. 120, August 2017, P325-332
[2] E. Okafor et al, Experimental and numerical study of the laminar burning velocity of CH4 –NH 3–air premixed flames, Combustion and Flame, vol. 187(2018), P185-198

Read the abstract at the AIChE website.


Download this presentation [not presently available to download].


2017: NH3 / N2 / O2 Non-Premixed Flame in a 10 kW Experimental Furnace – Characteristics of Radiative Heat Transfer
2017: Detailed Observation of Coal-Ammonia Co-Combustion Processes
2017: Effects of the Thickness of the Burner Rim, the Velocities of Fuel and Air on Extinction Limit of Ammonia Coaxial Jet Diffusion Flame
2014: Characteristics of Ammonia / N2 / O2 Laminar Premixed Flame in Oxygen-enriched Condition


Department of Mechanical Engineering, Osaka University
Learn more about the 2018 NH3 Fuel Conference

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