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Influence of the biogas reburning for reducing nitric oxide emissions in an alundum-tube reactor
Abstract The experimental study on reburning reduction reaction between biogas and NO is very important in de-NOx technology. The reburning experiments by the simulated biogas with different operation variables have been performed in an alundum-tube reactor. Results showed that the uppermost constituent in NO-reduction was CH4, H2 second, and NO-reduction by CO in biogas reburning was negligible at the same conditions. In the condition of oxygen-poor, H2 could promote CH4 oxidation and enhance the concentration of CH3 radicals, thereby increasing the reduction efficiency of NO accordingly. At the same temperature, with the increase of stoichiometric ratio, it would increase O radicals and decrease NO reduction efficiency. With the increase of reaction temperature, the reduction efficiency behaved a trend of first increased then decreased at the same stoichiometric ratio, and obtained the maximum value 51.38% at the condition of 1200 °C and λ = 0.6. Additionally, increasing the NO input concentration also could improve the reduction efficiency under the condition of fuel-rich.
Highlights Biogas reburning could effectively reduce NO emissions. The foremost component in NO-reduction by biogas reburning was CH4. Under a low λ, H2 could enhance the concentration of CH3 radicals, thereby increasing the reduction efficiency of NO. NO-reduction by CO in biogas reburning was negligible.
Influence of the biogas reburning for reducing nitric oxide emissions in an alundum-tube reactor
Abstract The experimental study on reburning reduction reaction between biogas and NO is very important in de-NOx technology. The reburning experiments by the simulated biogas with different operation variables have been performed in an alundum-tube reactor. Results showed that the uppermost constituent in NO-reduction was CH4, H2 second, and NO-reduction by CO in biogas reburning was negligible at the same conditions. In the condition of oxygen-poor, H2 could promote CH4 oxidation and enhance the concentration of CH3 radicals, thereby increasing the reduction efficiency of NO accordingly. At the same temperature, with the increase of stoichiometric ratio, it would increase O radicals and decrease NO reduction efficiency. With the increase of reaction temperature, the reduction efficiency behaved a trend of first increased then decreased at the same stoichiometric ratio, and obtained the maximum value 51.38% at the condition of 1200 °C and λ = 0.6. Additionally, increasing the NO input concentration also could improve the reduction efficiency under the condition of fuel-rich.
Highlights Biogas reburning could effectively reduce NO emissions. The foremost component in NO-reduction by biogas reburning was CH4. Under a low λ, H2 could enhance the concentration of CH3 radicals, thereby increasing the reduction efficiency of NO. NO-reduction by CO in biogas reburning was negligible.
Influence of the biogas reburning for reducing nitric oxide emissions in an alundum-tube reactor
Zhao, Jie (author) / Wang, Qingcheng (author) / Yu, Lihui (author) / Wu, Liyan (author)
Atmospheric Environment ; 132 ; 290-295
2016-03-02
6 pages
Article (Journal)
Electronic Resource
English
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