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Emission Control Science and Technology
Erschienen in: Emission Control Science and Technology 3-4/2022

03.10.2022

Studies on the Effect of Swirl on Nitric-Oxide Formation in Combustion—a Selected Review

verfasst von: L. X. Zhou, F. Wang, Y. Zhang

Erschienen in: Emission Control Science and Technology | Ausgabe 3-4/2022

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Abstract

Swirling gas/coal combustion are frequently encountered in combustion facilities. To reduce pollutant formation from combustion is an important problem in environment protection. Most previous studies were based on controlling the chemical reaction, air staging, or reburning. Some studies on the effect of swirl were reported, but contradictory results were obtained. This paper is a review of experimental and numerical studies on nitric-oxide formation in swirling methane-air and pulverized-coal combustion conducted by the present authors. The experimental and simulation results indicate that as the swirl number increases, the thermal NO at first increases and then decreases, whereas the total NO and fuel NO at first decrease and then increase. There is an optimal swirl number at which the total NO emission is minimal. The increase of swirl number causes at first the reduction of turbulence and then a slight increase of turbulence. It leads to at first the temperature rises and then the temperature falls in the near-inlet region. The thermal NO is more affected by the temperature and the fuel NO is more affected by the turbulent mixing. These research results are helpful for engineering application to reduce pollutant emission from combustion to surrounding environment.
Vorheriger Artikel Transient Flow Uniformity Evolution in Realistic Exhaust Gas Aftertreatment Systems Using 3D-CFD
Nächster Artikel Steady-State NOx Emission Model for Gas-Fired Heating and Hot Water Combi-Boilers with Factor Analysis and Artificial Neural Network

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Metadaten
Titel
Studies on the Effect of Swirl on Nitric-Oxide Formation in Combustion—a Selected Review
verfasst von
L. X. Zhou
F. Wang
Y. Zhang
Publikationsdatum
03.10.2022
Verlag
Springer International Publishing
Erschienen in
Emission Control Science and Technology / Ausgabe 3-4/2022
Print ISSN: 2199-3629
Elektronische ISSN: 2199-3637
DOI
https://doi.org/10.1007/s40825-022-00215-8

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