TY - JOUR
T1 - Flue gas analysis for biomass and coal co-firing in fluidized bed
T2 - process simulation and validation
AU - Zhakupov, Daulet
AU - Kulmukanova, Lyazzat
AU - Sarbassov, Yerbol
AU - Shah, Dhawal
N1 - Funding Information:
The authors gratefully acknowledge the support provided by Nazarbayev University under the project number 110119FD4535 (Project name: Co-firing of coal and biomass under air and oxy-fuel environment in fluidized bed rig: Experiments with process model development) and 11022021FD2905 (Project name: Efficient thermal valorization of municipal sewage sludge in fluidized bed systems: Advanced experiments with process modeling) for operating the pilot-scale circulating fluidized bed reactor and for the computational resources.
Publisher Copyright:
© 2022, The Author(s).
PY - 2022/12
Y1 - 2022/12
N2 - Coal-conversion technologies, although used ubiquitously, are often discredited due to high pollutant emissions, thereby emphasizing a dire need to optimize the combustion process. The co-firing of coal/biomass in a fluidized bed reactor has been an efficient way to optimize the pollutants emission. Herein, a new model has been designed in Aspen Plus® to simultaneously include detailed reaction kinetics, volatile compositions, tar combustion, and hydrodynamics of the reactor. Validation of the process model was done with variations in the fuel including high-sulfur Spanish lignite, high-ash Ekibastuz coal, wood pellets, and locally collected municipal solid waste (MSW) and the temperature ranging from 1073 to 1223 K. The composition of the exhaust gases, namely, CO/CO2/NO/SO2 were determined from the model to be within 2% of the experimental observations. Co-combustion of local MSW with Ekibastuz coal had flue gas composition ranging from 1000 to 5000 ppm of CO, 16.2%–17.2% of CO2, 200–550 ppm of NO, and 130–210 ppm of SO2. A sensitivity analysis on co-firing of local biomass and Ekibastuz coal demonstrated the optimal operating temperature for fluidized bed reactor at 1148 K with the recommended biomass-to-coal ratio is 1/4, leading to minimum emissions of CO, NO, and SO2.
AB - Coal-conversion technologies, although used ubiquitously, are often discredited due to high pollutant emissions, thereby emphasizing a dire need to optimize the combustion process. The co-firing of coal/biomass in a fluidized bed reactor has been an efficient way to optimize the pollutants emission. Herein, a new model has been designed in Aspen Plus® to simultaneously include detailed reaction kinetics, volatile compositions, tar combustion, and hydrodynamics of the reactor. Validation of the process model was done with variations in the fuel including high-sulfur Spanish lignite, high-ash Ekibastuz coal, wood pellets, and locally collected municipal solid waste (MSW) and the temperature ranging from 1073 to 1223 K. The composition of the exhaust gases, namely, CO/CO2/NO/SO2 were determined from the model to be within 2% of the experimental observations. Co-combustion of local MSW with Ekibastuz coal had flue gas composition ranging from 1000 to 5000 ppm of CO, 16.2%–17.2% of CO2, 200–550 ppm of NO, and 130–210 ppm of SO2. A sensitivity analysis on co-firing of local biomass and Ekibastuz coal demonstrated the optimal operating temperature for fluidized bed reactor at 1148 K with the recommended biomass-to-coal ratio is 1/4, leading to minimum emissions of CO, NO, and SO2.
KW - Advanced process simulation
KW - Aspen plus
KW - Biomass cofiring
KW - Flue-gas emissions
KW - Fluidized-bed combustion
KW - Fuel utilization
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U2 - 10.1007/s40789-022-00531-y
DO - 10.1007/s40789-022-00531-y
M3 - Article
AN - SCOPUS:85135863390
SN - 2095-8293
VL - 9
JO - International Journal of Coal Science and Technology
JF - International Journal of Coal Science and Technology
IS - 1
M1 - 59
ER -