Experimental and modeling study on ignition delay of ammonia/methane fuels

Summary Ammonia mixed with methane is a potential clean fuel for engine applications toward a low carbon economy. Studies are scarce on ignition phenomenon for ammonia/methane fuels in literature. In the present study, the ignition characteristics for ammonia–methane–air mixtures have been investiga...

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Veröffentlicht in:International journal of energy research 2020-06, Vol.44 (8), p.6939-6949
Hauptverfasser: Xiao, Hua, Lai, Shini, Valera‐Medina, Agustin, Li, Juying, Liu, Jinyuan, Fu, Huide
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Sprache:eng
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Zusammenfassung:Summary Ammonia mixed with methane is a potential clean fuel for engine applications toward a low carbon economy. Studies are scarce on ignition phenomenon for ammonia/methane fuels in literature. In the present study, the ignition characteristics for ammonia–methane–air mixtures have been investigated by both experimental measurements and numerical simulations. Ignition processes of a 60%ammonia/40%methane (mol%) fuel blend were investigated with shock‐tube experiments. Measurements of the ignition delay times were performed behind reflected shock waves for such fuel/air mixtures with different equivalence ratios of 0.5, 1, and 2, at pressures around 2 and 5 atm within the temperature range of 1369 to 1804 K. Experimental results were then compared with numerical prediction results employing detailed kinetic mechanism, which showed satisfactory agreement within most of the range of the temperatures, equivalence ratios, and pressures investigated. Within the temperature range of 1300 to 1900 K, pressure range of 1 to 10 atm, equivalence ratio range of 0.5 to 2, and methane proportion range of 0% to 50% in fuel blends, the impacts of temperature, pressure, equivalence ratio, and methane additive were simulated on the ignition delay times of the fuel blends based upon the numerical model. It was found that the improvement of ammonia/methane ignition is significant with the increase of temperature, pressure, and methane additive while it is relatively not sensitive to equivalence ratio within the studied conditions. This suggests a promising potential of such fuel blends in real engine application. In addition to the calculations, reaction sensitivity analyses were also performed to have a deep insight into the observed differences between ammonia/methane/air ignition delay times with variation of conditions. As ammonia mixed with methane is a promising fuel to reduce carbon emissions, a comprehensive study was performed on its combustion characteristics under various conditions. Ammonia/methane fuels were investigated with shock tube experiments and numerical simulations, providing fundamental database on such fuels. Results show the improvement on ammonia/methane ignition is significant with the increase of pressure and methane addition while it is not sensitive to equivalence ratio condition, suggesting a good potential using such fuels under real engine conditions.
ISSN:0363-907X
1099-114X
DOI:10.1002/er.5460