Experimental investigation of the stability of a turbulent diffusion flame in a gas turbine combustor

Experimental investigation of the stability of a turbulent diffusion flame in a gas turbine combustor

The stability of a turbulent diffusion flame temperature in an atmospheric gas-turbine combustor is investigated experimentally over a range of operating conditions to study the combined effect of hydrogen-enriched- methane (as fuel) and oxygen with carbon dioxide (oxy-fuel, as the oxidizer) on the...

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Bibliographic Details
Published in:Energy (Oxford) Vol. 157; pp. 904 - 913
Main Authors: Said, Syed A., Aliyu, Mansur, Nemitallah, Medhat A., Habib, Mohamed A., Mansir, Ibrahim B.
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 15-08-2018
Elsevier BV
Subjects:
Carbon dioxide
Combustion chambers
Diffusion
Eddy diffusion
Flame retardants
Flame stability
Flame temperature
Fluidized bed combustion
Fuels
Gas turbine combustor
Gas turbine engines
Gas turbines
Hydrogen
Hydrogen enrichment
Methane
Oxy-combustion
Oxy-fuel
Oxygen
Swirl effect
Turbulent diffusion
Gas turbine combustor
Flame stability
Hydrogen enrichment
Oxy-combustion
Swirl effect
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Summary:The stability of a turbulent diffusion flame temperature in an atmospheric gas-turbine combustor is investigated experimentally over a range of operating conditions to study the combined effect of hydrogen-enriched- methane (as fuel) and oxygen with carbon dioxide (oxy-fuel, as the oxidizer) on the combustion flame stability. These conditions included varying fuel and oxidizer mixture compositions, swirl angles, and equivalence ratios. The fuel (i.e. methane) is enriched with hydrogen (H2) in a ratio that ranged from zero to 50%; where the oxidizer (pure oxygen) is mixed with carbon dioxide (CO2) in a ratio that ranged from zero up to the value of flame blow-off. Different swirl vane angles corresponding to different swirl numbers were considered. The results indicated that stable regime (flame) is achieved close to stoichiometric conditions at high oxygen (O2) to CO2 ratio and high H2 (50%) enriched fuel; while the flame blow-off occurred at low O2 to CO2 ratios (20% or less). High-level flame stability with moderate flame length and temperature were observed at the highest swirl vane angle. •Combined effects of hydrogen, oxy-combustion and swirl on flame stability.•Experimental study on swirl effect on oxy-flame stability in a gas turbine.•Experimental study on oxy-combustion stabilization behavior in a gas turbine.•Experimental study on effect of hydrogen enrichment on oxy-flame stability.•Flames visualizations in terms of length, appearance and color are investigated.
ISSN:0360-5442
1873-6785
DOI:10.1016/j.energy.2018.05.177