Optimal swirl number and equivalence ratio for minimizing the soot and NO emissions in turbulent methane combustion

The simultaneous effect of the swirl number (SN) and equivalence ratio on NO and soot emissions in turbulent methane-air combustion was numerically investigated. The realizable k-ε model has been applied for modeling turbulence and eddy dissipation (ED) and probability density function (PDF) models...

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Bibliographic Details
Published inChemical engineering communications Vol. 210; no. 5; pp. 788 - 800
Main Authors Ershadi, Ali, Rajabi Zargarabadi, Mehran
Format Journal Article
LanguageEnglish
Published Philadelphia Taylor & Francis 04.05.2023
Taylor & Francis Ltd
Subjects
Algebra
Chemical reactions
Combustion
Emission
Equivalence ratio
Flame temperature
Heat flux
Mathematical models
Methane
NO emission
Numerical models
Probability density functions
Soot
soot formation
swirl number
Temperature distribution
Turbulence
turbulent combustion
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Summary:The simultaneous effect of the swirl number (SN) and equivalence ratio on NO and soot emissions in turbulent methane-air combustion was numerically investigated. The realizable k-ε model has been applied for modeling turbulence and eddy dissipation (ED) and probability density function (PDF) models were adopted for chemical reaction. The general gradient diffusion hypothesis (GGDH), high order algebraic model (HOGGDH), and simple eddy diffusivity model have been applied for modeling the turbulent heat flux (THF) vector. The Brooke-Moss model has been employed to predict the soot particle quantities. Comparing the results of the different numerical models (PDF and EDM with algebraic THF) with available experimental data indicated that employing the second-order models significantly leads to the modification of predicting temperature distribution in EDM. However, due to the effect of the PDF model on soot modeling, the PDF model provides more accurate results. The numerical simulations have been performed for various SNs (SN = 0-1.33) and equivalence ratios (0.125-0.75). In all of equivalence ratios the flame temperature and pollutants emission (NO and soot) were strongly affected by the SN. Also, the SN has different effects on NO and soot emission. Finally, for each of NO and soot emission, a correlation relative to effective combustion factors such as SN and equivalence ratio was presented. It is found that by increasing the equivalence ratio, the NO emission increases with a power of 2.3, and soot emission decreases with a power of 8.7.
ISSN:0098-6445
1563-5201
DOI:10.1080/00986445.2022.2027766