Influence of the H2 proportion on NH3/H2/air combustion in hot and low-oxygen coflows

This study investigated the effect of the H2 fraction on reaction dynamics and NOx formation in a premixed NH3/H2/air jet flame within a hot coflow (JHC) through numerical simulations. We found that even a small mole fraction of H2 (e.g., XH2, F = 5%) significantly enhances the ignition of the premi...

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Published inInternational journal of hydrogen energy Vol. 63; pp. 480 - 490
Main Authors Wang, Guochang, Liu, Xiangtao, Li, Pengfei, Shi, Guodong, Si, Jicang, Liu, Zhaohui, Mi, Jianchun
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 18.04.2024
Subjects
H2 proportion
MILD combustion
NH3/H2 blends
NOx generation
Reaction characteristics
H2 proportion
NH3/H2 blends
MILD combustion
Reaction characteristics
NOx generation
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Abstract This study investigated the effect of the H2 fraction on reaction dynamics and NOx formation in a premixed NH3/H2/air jet flame within a hot coflow (JHC) through numerical simulations. We found that even a small mole fraction of H2 (e.g., XH2, F = 5%) significantly enhances the ignition of the premixed NH3/air flame. However, the presence of H2 markedly intensifies the main combustion reactions only when XH2, F ≥ 30%, resulting in a sharp increase in temperature and heat release rate. Moreover, as XH2, F increases, the NOx emission first increases until XH2, F = 75% and then decreases. Without any H2 addition, a high emission of unburned NH3 occurs in the pure NH3 JHC flame. On the other hand, when XH2, F ≥ 50%, the emissions of unburned H2 and OH increase rapidly due to extremely high temperatures. Notably, maintaining XH2, F between 5% and 20% minimizes the emissions of NOx, NH3, H2, and OH. Furthermore, the preferential diffusion of H2 plays a key role in enhancing the production of active radicals (OH, O, and H), thereby significantly boosting the initiation and combustion reactions of NH3/H2 blended fuel. [Display omitted] •Effect of H2 addition on the premixed NH3/H2/air jet flames is investigated.•A small amount of H2 (5%) in the fuel notably enhances the ignition of NH3 flame.•H2 significantly boosts major combustion reactions only when its proportion ≥30%.•Optimal H2 proportion is 5%–20% to reduce emissions of NOx, unburned NH3 and H2.•Preferential diffusion of H2 greatly enhances the ignition and combustion reactions.
AbstractList This study investigated the effect of the H2 fraction on reaction dynamics and NOx formation in a premixed NH3/H2/air jet flame within a hot coflow (JHC) through numerical simulations. We found that even a small mole fraction of H2 (e.g., XH2, F = 5%) significantly enhances the ignition of the premixed NH3/air flame. However, the presence of H2 markedly intensifies the main combustion reactions only when XH2, F ≥ 30%, resulting in a sharp increase in temperature and heat release rate. Moreover, as XH2, F increases, the NOx emission first increases until XH2, F = 75% and then decreases. Without any H2 addition, a high emission of unburned NH3 occurs in the pure NH3 JHC flame. On the other hand, when XH2, F ≥ 50%, the emissions of unburned H2 and OH increase rapidly due to extremely high temperatures. Notably, maintaining XH2, F between 5% and 20% minimizes the emissions of NOx, NH3, H2, and OH. Furthermore, the preferential diffusion of H2 plays a key role in enhancing the production of active radicals (OH, O, and H), thereby significantly boosting the initiation and combustion reactions of NH3/H2 blended fuel. [Display omitted] •Effect of H2 addition on the premixed NH3/H2/air jet flames is investigated.•A small amount of H2 (5%) in the fuel notably enhances the ignition of NH3 flame.•H2 significantly boosts major combustion reactions only when its proportion ≥30%.•Optimal H2 proportion is 5%–20% to reduce emissions of NOx, unburned NH3 and H2.•Preferential diffusion of H2 greatly enhances the ignition and combustion reactions.
Author Liu, Zhaohui
Liu, Xiangtao
Si, Jicang
Shi, Guodong
Mi, Jianchun
Li, Pengfei
Wang, Guochang
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Keywords H2 proportion
NH3/H2 blends
MILD combustion
Reaction characteristics
NOx generation
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  year: 2004
  ident: 10.1016/j.ijhydene.2024.03.212_bib18
  article-title: Mild combustion
  publication-title: Prog Energy Combust Sci
  doi: 10.1016/j.pecs.2004.02.003
– volume: 24
  start-page: 6275
  year: 2010
  ident: 10.1016/j.ijhydene.2024.03.212_bib39
  article-title: New weighted sum of gray gases model applicable to computational fluid dynamics (CFD) modeling of Oxy−Fuel combustion: derivation, validation, and implementation
  publication-title: Energy Fuels
  doi: 10.1021/ef101211p
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Snippet This study investigated the effect of the H2 fraction on reaction dynamics and NOx formation in a premixed NH3/H2/air jet flame within a hot coflow (JHC)...
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SubjectTerms H2 proportion
MILD combustion
NH3/H2 blends
NOx generation
Reaction characteristics
Title Influence of the H2 proportion on NH3/H2/air combustion in hot and low-oxygen coflows
URI https://dx.doi.org/10.1016/j.ijhydene.2024.03.212
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