Effects of bluff-body cone angle on turbulence-chemistry interaction behaviors in large-scale semicoke and bituminous coal co-combustion

During large-scale semicoke and bituminous coal co-combustion, the behaviors of turbulence-chemistry interactions were experimentally and numerically used to investigate the effects of char burnout and NOx emissions in a pilot-scale bias combustor at different bluff-body cone angles (α). The results...

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Bibliographic Details
Published in:Fuel processing technology 2021-10, Vol.221, p.106915, Article 106915
Main Authors: Sun, Liutao, Yan, Yonghong, Sun, Rui, Zhu, Wenkun, Yuan, Mengfan, Qi, Hongliang, Wu, Jiangquan
Format: Article
Language:English
Subjects:
Bituminous coal
Bluff-body cone angle
Burnout
Chemical reactions
Chemistry
Cliffs
Combustion chambers
Damköhler number
Diffusion rate
Flue gas
Gasification
Large-scale semicoke co-combustion
Low NOx emissions
Nitrogen oxides
Oxidation
Reaction kinetics
Temperature profiles
Temperature uniformity
Turbulence
Turbulence-chemistry interactions
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Summary:During large-scale semicoke and bituminous coal co-combustion, the behaviors of turbulence-chemistry interactions were experimentally and numerically used to investigate the effects of char burnout and NOx emissions in a pilot-scale bias combustor at different bluff-body cone angles (α). The results show that with increasing α the main reaction zone moves upstream significantly, and a widened flame and uniform temperature profile are obtained due to enhancing the internal flue gas recirculation. An increase in α can improve the char-oxidation reaction, and further results in increased pore structures and char burnout ratios. For all cases, the Dat (homogeneous Damköhler number) maximum values are below 0.50. The Da,O2, Da,CO2 and Da,H2O (heterogeneous Damköhler numbers) values are within 0.670–1.207, 0.004–0.017 and 0.001–0.004, indicating that the char oxidation reaction is dominated by diffusion/kinetics, while the char gasification reactions are controlled by chemical kinetics. However, both reactions tend to be kinetically-controlled with increasing α. The NOx emissions decrease by 27% at the α = 34° value, because a large cone angle can enlarge the combustion reduction zone and enhance the oxygen diffusion rate. The findings can provide deep insight into the turbulence-chemistry interactions and its effect on NOx emission characteristics of semicoke co-combustion in a bluff-body tangential burner. [Display omitted] •Bluff-body with different cone angle is used for semicoke and bituminous coal large-scale co-combustion.•The behaviors of turbulence-chemistry interaction are characterized by the Damköhler number.•NOx formation can be controlled by achieving a moderate kinetic rate and preferable O2 diffusivity regime.•As the cone angle increases, more uniform and lower temperature profiles, as well as extended reduction zone are captured.
ISSN:0378-3820
1873-7188
DOI:10.1016/j.fuproc.2021.106915