An experimental study on the carbon conversion efficiency and emission indices of air and steam co-flow diffusion jet flames

[Display omitted] •Gas flaring has notable contributions to global warming and local air pollution.•A systematic study was done using air and steam co-flow diffusion jet flames.•Carbon conversion efficiency and emission indices of soot and NOx were measured.•Adding assisting fluids had non-monatomic...

Full description

Saved in:
Bibliographic Details
Published inFuel (Guildford) Vol. 287; p. 119534
Main Authors Zamani, M., Abbasi-Atibeh, E., Mobaseri, S., Ahsan, H., Ahsan, A., Olfert, J.S., Kostiuk, L.W.
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 01.03.2021
Elsevier BV
Subjects
Air pollution
Assisted flare
Atmospheric chemistry
Black carbon
Carbon
Carbon conversion efficiency
Carbon dioxide
Carbon dioxide emissions
Co-flow diffusion flame
Composition effects
Critical flow
Diluents
Efficiency
Emission analysis
Emission index
Emissions
Flow rates
Flow velocity
Fluid dynamics
Fluid flow
Gases
Hydrodynamics
Inert gases
Jet flow
Nitrogen
Nitrogen oxides
Oxides
Photochemicals
Pollutants
Rare gases
Steam
Tubes
Assisted flare
Co-flow diffusion flame
Carbon conversion efficiency
Emission index
Online AccessGet full text

Cover

More Information
Summary:[Display omitted] •Gas flaring has notable contributions to global warming and local air pollution.•A systematic study was done using air and steam co-flow diffusion jet flames.•Carbon conversion efficiency and emission indices of soot and NOx were measured.•Adding assisting fluids had non-monatomic response on emissions of diffusion flames.•Useful flow conditions existed that optimized soot, NOx, and fuel emissions Industrial flaring is a notable global contributor to carbon dioxide emissions and other key pollutants. Introducing a separate assisting fluid near the base of these flames affects their hydrodynamics, thermodynamics, and chemistry, which in turn affects their efficiency and emissions. In this study, a burner constructed of two concentric tubes allowed for various generic burner geometries, where different fuels (methane or propane) and co-flow assisting fluids (air, steam, or inert gases) flowed through the annular space and the center tube, respectively. The effects of the composition and flow rate of the fuel and assisting fluid, as well as the burner head geometry, were investigated in terms of carbon conversion efficiency (CCE) and emission indices of black carbon and oxides of nitrogen. The CCE was observed to be essentially 100% for unassisted flames and remained at that level when assisting fluid, irrespective of composition, was added. However, at some critical flow rate of assisting fluid, the CCE collapsed, and the main flame blew off. In general, the CCE collapse occurred at considerably more mass of air compared to that of steam. Furthermore, adding the assisting fluid co-flow monotonically reduced the black carbon emission by orders of magnitude. On the other hand, the emission of oxides of nitrogen rose slightly with increasing air co-flow flow rate and dropped when steam or other diluents were added. These results showed that there was a range of assisting fluid flow rates, where the CCE was approximately 100%, while the emission of black carbon and nitrogen oxides were highly suppressed.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2020.119534