Flue gas analysis for biomass and coal co-firing in fluidized bed: process simulation and validation

Daulet Zhakupov; Lyazzat Kulmukanova; Yerbol Sarbassov; Dhawal Shah

doi:10.1007/s40789-022-00531-y

Flue gas analysis for biomass and coal co-firing in fluidized bed: process simulation and validation

Daulet Zhakupov
, Lyazzat Kulmukanova
, Yerbol Sarbassov
, Dhawal Shah

Nazarbayev University

Research output: Contribution to journal › Article › peer-review

27 Citations (Scopus)

2 Downloads (Pure)

Abstract

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.

Original language	English
Article number	59
Journal	International Journal of Coal Science and Technology
Volume	9
Issue number	1
DOIs	https://doi.org/10.1007/s40789-022-00531-y
Publication status	Published - Dec 2022

Funding

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.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 11 Sustainable Cities and Communities
SDG 12 Responsible Consumption and Production

Keywords

Advanced process simulation
Aspen plus
Biomass cofiring
Flue-gas emissions
Fluidized-bed combustion
Fuel utilization

ASJC Scopus subject areas

Geotechnical Engineering and Engineering Geology
Energy Engineering and Power Technology

Access to Document

10.1007/s40789-022-00531-y

Flue gas analysis for biomass and coal co-firing in fluidized bed process simulation and validation 51d2e199Final published version, 1.54 MB

Cite this

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title = "Flue gas analysis for biomass and coal co-firing in fluidized bed: process simulation and validation",

abstract = "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{\textregistered} 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.",

keywords = "Advanced process simulation, Aspen plus, Biomass cofiring, Flue-gas emissions, Fluidized-bed combustion, Fuel utilization",

author = "Daulet Zhakupov and Lyazzat Kulmukanova and Yerbol Sarbassov and Dhawal Shah",

note = "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: {\textcopyright} 2022, The Author(s).",

year = "2022",

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doi = "10.1007/s40789-022-00531-y",

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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.

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KW - Flue-gas emissions

KW - Fluidized-bed combustion

KW - Fuel utilization

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SN - 2095-8293

VL - 9

JO - International Journal of Coal Science and Technology

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M1 - 59

ER -

Flue gas analysis for biomass and coal co-firing in fluidized bed: process simulation and validation

Abstract

Funding

UN SDGs

Keywords

ASJC Scopus subject areas

Access to Document

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