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Aspen Plus Simulation of Biomass Gasification: a Comprehensive Model Incorporating Reaction Kinetics, Hydrodynamics and Tar Production
Energy generation from biomass through gasification has been a keen area of research for a long time. However, gasification still needs to overcome a significant number of challenges for its wider acceptability. Even though experimental works on lab-scale biomass gasifiers are available, computation...
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| Published in: | Process integration and optimization for sustainability 2023-03, Vol.7 (1-2), p.255-268 |
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| creator | K T, Abdul Azeez P, Suraj C, Muraleedharan P, Arun |
| description | Energy generation from biomass through gasification has been a keen area of research for a long time. However, gasification still needs to overcome a significant number of challenges for its wider acceptability. Even though experimental works on lab-scale biomass gasifiers are available, computational modelling and simulations are crucial in predicting the system performance. Process simulation and analysis of fluidized bed gasification using Aspen Plus software are considered in this study. Among the three Aspen Plus models developed in the present study, model 1 and model 2 are developed based on equilibrium and kinetic approach, respectively. In addition to this, reaction kinetics, gasifier geometry and bed hydrodynamics are considered in model 3. The model-predicted values are then validated against experimental data. Minimum values of mean error, root mean square error, mean absolute error and mean absolute percentage error, are observed for model 3. As model 3 realistically represents the gasification process, the impact of gasification temperature and equivalence ratio on the product gas composition, lower heating value, cold gas efficiency and carbon conversion efficiency are systematically studied using this model. The model is simulated at temperatures ranging from 680 to 800 °C and equivalence ratio of 0.24–0.32. The simulation results indicated that higher operating temperature and lower equivalence ratio enhanced the gasification process. Benzene is identified as the primary component of tar with a composition of 9.79 g/kg
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| doi_str_mv | 10.1007/s41660-022-00291-x |
| format | article |
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However, gasification still needs to overcome a significant number of challenges for its wider acceptability. Even though experimental works on lab-scale biomass gasifiers are available, computational modelling and simulations are crucial in predicting the system performance. Process simulation and analysis of fluidized bed gasification using Aspen Plus software are considered in this study. Among the three Aspen Plus models developed in the present study, model 1 and model 2 are developed based on equilibrium and kinetic approach, respectively. In addition to this, reaction kinetics, gasifier geometry and bed hydrodynamics are considered in model 3. The model-predicted values are then validated against experimental data. Minimum values of mean error, root mean square error, mean absolute error and mean absolute percentage error, are observed for model 3. As model 3 realistically represents the gasification process, the impact of gasification temperature and equivalence ratio on the product gas composition, lower heating value, cold gas efficiency and carbon conversion efficiency are systematically studied using this model. The model is simulated at temperatures ranging from 680 to 800 °C and equivalence ratio of 0.24–0.32. The simulation results indicated that higher operating temperature and lower equivalence ratio enhanced the gasification process. Benzene is identified as the primary component of tar with a composition of 9.79 g/kg
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| subjects | Benzene Biomass Biomass energy Biomass energy production Calorific value Cold gas Economics and Management Energy Policy Engineering Equilibrium Equivalence ratio Errors Fluid mechanics Fluidized bed reactors Fluidized beds Gas composition Gases Gasification Geometry Hydrocarbons Hydrodynamics Industrial and Production Engineering Industrial Chemistry/Chemical Engineering Kinetics Operating temperature Original Research Paper Performance evaluation Performance prediction Raw materials Reaction kinetics Simulation Sustainable Development Synthesis gas Temperature Waste Management/Waste Technology |
| title | Aspen Plus Simulation of Biomass Gasification: a Comprehensive Model Incorporating Reaction Kinetics, Hydrodynamics and Tar Production |
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