Effects of ammonia substitution on extinction limits and structure of counterflow nonpremixed hydrogen/air flames

The potential of partial ammonia substitution to improve the safety of hydrogen use was evaluated computationally, using counterflow nonpremixed ammonia/hydrogen/air flames at normal temperature and pressure. The ammonia-substituted hydrogen/air flames were considered using a recent kinetic mechanis...

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Veröffentlicht in:International journal of hydrogen energy 2011-08, Vol.36 (16), p.10117-10128
Hauptverfasser: Lee, Seungro, Kwon, Oh Chae
Format: Artikel
Sprache:eng
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Zusammenfassung:The potential of partial ammonia substitution to improve the safety of hydrogen use was evaluated computationally, using counterflow nonpremixed ammonia/hydrogen/air flames at normal temperature and pressure. The ammonia-substituted hydrogen/air flames were considered using a recent kinetic mechanism and a statistical narrow-band radiation model for a wide range of flame strain rates and the extent of ammonia substitution. The effects of ammonia substitution on the extinction limits and structure, including nitrogen oxide (NO x ) and nitrous oxide (N 2O) emissions, of nonpremixed hydrogen/air flames were investigated. Results show reduction of the high-stretch extinction (i.e., blow-off) limits, the maximum flame temperature and the concentration of light radicals (e.g., H and OH) with ammonia substitution in hydrogen/air flames, supporting the potential of ammonia as a carbon-free, clean additive for improving the safety of hydrogen use in nonpremixed hydrogen/air flames. For high-stretched flames, however, NO x and N 2O emissions substantially increase with ammonia substitution even though ammonia substitution reduces flame temperature, implying that chemical effects (rather than thermal effects) of ammonia substitution on flame structure are dominant. Radiation effects on the extinction limits and flame structure are not remarkable particularly for high-stretched flames. ► We simulate counterflow nonpremixed NH 3-substituted H 2/air flames at NTP. ► The high-stretch extinction limits are reduced with NH 3 substitution. ► Potential of NH 3 as a C-free additive for improving the safety of H 2 use is found. ► Chemical effects of NH 3 substitution on flame structure are dominant. ► Radiation effects on the extinction limits and flame structure are not remarkable.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2011.05.082