Quasi-equilibrium thermodynamic model with empirical equations for air–steam biomass gasification in fluidized-beds

Gasification is one of the most promising technologies for converting biomass into a fuel. This study presents a simple and practical biomass gasification model based on thermodynamic equilibrium to find effective operating conditions of the air–steam gasification system in fluidized-beds. The carbo...

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Bibliographic Details
Published in:Fuel processing technology 2014-12, Vol.128, p.199-210
Main Authors: Lim, Young-il, Lee, Uen-Do
Format: Article
Language:English
Subjects:
Air–steam biomass gasification (ASBG)
Applied sciences
Auto-thermal gasification
Biomass
Carbon
Empirical equations
Energy
Exact sciences and technology
Fluidized-bed
Fluidizing
Fuel processing. Carbochemistry and petrochemistry
Fuels
Gasification
Mathematical models
Non-equilibrium factor
Solid fuel processing (coal, coke, brown coal, peat, wood, etc.)
Thermodynamic equilibrium model
Thermodynamic models
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Summary:Gasification is one of the most promising technologies for converting biomass into a fuel. This study presents a simple and practical biomass gasification model based on thermodynamic equilibrium to find effective operating conditions of the air–steam gasification system in fluidized-beds. The carbon conversion fraction empirically obtained was involved in a global gasification reaction. Two empirical equations as the non-equilibrium factor expressing the deviation from equilibrium were derived as the function of the equivalence ratio (ER) from 43 experimental data sets of various operating conditions and different feedstocks. One energy balance was also solved for determining the gasification temperature (T). After the producer gas composition with respect to ER and steam to biomass ratio (SBR) was obtained from the air–steam biomass gasification (ASBG) model, process performances such as lower heating value, heat efficiency, net heat efficiency, and H2/CO molar ratio were evaluated. An effective operating area was suggested from the contour plot of the process performances with respect to ER and SBR in the auto-thermal gasification temperature from 700 to 830°C. [Display omitted] •A simple and practical air–steam biomass gasification (ASBG) model was developed.•Two empirical equations expressing the deviation from equilibrium were used.•Parametric study was done to examine process performance of fluidized-bed gasifiers.•Effective operating conditions were obtained in an auto-thermal gasification zone.
ISSN:0378-3820
1873-7188
DOI:10.1016/j.fuproc.2014.07.017