Combustion of eucalyptus charcoals and coals of similar volatile yields aiming at blast furnace injection in a CO2 mitigation environment

Reduction of CO2 emissions due to partial substitution of coal by a renewable fuel, like woody biomass, is a subject of increasing interest in the ironmaking process. Additionally, the combination of biomass combustion with CO2 capture technologies, such as oxy-fuel, could allow a negative CO2 balan...

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Published inJournal of cleaner production Vol. 129; pp. 1 - 11
Main Authors Pohlmann, Juliana G., Borrego, Angeles G., Osório, Eduardo, Diez, Maria Antonia, Vilela, Antônio C.F.
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 15.08.2016
Subjects
Biomass
Blast
carbon dioxide
Carbonization
cell walls
charcoal
CO2 mitigation
coal
combustion
Eucalyptus
Furnace injection
furnaces
greenhouse gas emissions
microscopy
oxygen
renewable energy sources
sorption isotherms
temperature
Torrefaction
Carbonization
CO2 mitigation
Torrefaction
Biomass
Blast
Furnace injection
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Abstract Reduction of CO2 emissions due to partial substitution of coal by a renewable fuel, like woody biomass, is a subject of increasing interest in the ironmaking process. Additionally, the combination of biomass combustion with CO2 capture technologies, such as oxy-fuel, could allow a negative CO2 balance for industrial processes. This study aims to investigate the combustibility of eucalyptus densified at different temperatures compared to coals of similar volatile matter contents typically used for Pulverized Coal Injection (PCI) in blast furnace. Combustion at different O2/N2 (conventional combustion) and O2/CO2 (oxy-fuel combustion) concentrations of pulverized samples was carried out in a Drop Tube Furnace (DTF) at 1300 °C. The characteristics of the chars were evaluated by their reactivity to CO2 in thermobalance, optical microscopy and adsorption isotherms techniques. The conversion of thermally-treated biomasses in the DTF was greater than that of the coals with similar volatile matter contents and combustion under oxy-fuel (O2/CO2) conditions appeared to be favored compared with conventional combustion (O2/N2) at the same oxygen concentration. The low volatile biomasses yielded isotropic char particles with cellular structure whereas the high volatile biomasses generated swollen particles with vacuolated cell walls which approach in appearance to those of low rank coal chars. The biomass yielded chars with higher micro- and mesopore surface areas than the coal chars of equivalent volatile yields, and greater surface areas at oxy-fuel conditions compared to conventional combustion chars. About 7–10% in average higher conversions were observed for the most reactive biomass and coal chars when combusted under oxy-fuel conditions in DTF. The higher combustibility and reactivity of biomass-chars compared to coal-chars in both O2/N2 and O2/CO2 environments could be positive to its incorporation in PCI providing a high reactivity fuel whose volatile matter could be adjusted depending on the needs to maintain the volatile stability in the blast furnace. •Combustion in a drop tube furnace of thermally-treated eucalyptus has been assessed.•Results are compared with those of coals with similar volatile matter yields.•Both conventional (O2/N2) and oxy-combustion (O2/CO2) atmospheres were tested.•Oxy-chars chars had higher reactivity and surface area than conventional chars.•Biomass chars were more reactive than coal chars from similar volatile yield fuels.
AbstractList Reduction of CO2 emissions due to partial substitution of coal by a renewable fuel, like woody biomass, is a subject of increasing interest in the ironmaking process. Additionally, the combination of biomass combustion with CO2 capture technologies, such as oxy-fuel, could allow a negative CO2 balance for industrial processes. This study aims to investigate the combustibility of eucalyptus densified at different temperatures compared to coals of similar volatile matter contents typically used for Pulverized Coal Injection (PCI) in blast furnace. Combustion at different O2/N2 (conventional combustion) and O2/CO2 (oxy-fuel combustion) concentrations of pulverized samples was carried out in a Drop Tube Furnace (DTF) at 1300 °C. The characteristics of the chars were evaluated by their reactivity to CO2 in thermobalance, optical microscopy and adsorption isotherms techniques. The conversion of thermally-treated biomasses in the DTF was greater than that of the coals with similar volatile matter contents and combustion under oxy-fuel (O2/CO2) conditions appeared to be favored compared with conventional combustion (O2/N2) at the same oxygen concentration. The low volatile biomasses yielded isotropic char particles with cellular structure whereas the high volatile biomasses generated swollen particles with vacuolated cell walls which approach in appearance to those of low rank coal chars. The biomass yielded chars with higher micro- and mesopore surface areas than the coal chars of equivalent volatile yields, and greater surface areas at oxy-fuel conditions compared to conventional combustion chars. About 7–10% in average higher conversions were observed for the most reactive biomass and coal chars when combusted under oxy-fuel conditions in DTF. The higher combustibility and reactivity of biomass-chars compared to coal-chars in both O2/N2 and O2/CO2 environments could be positive to its incorporation in PCI providing a high reactivity fuel whose volatile matter could be adjusted depending on the needs to maintain the volatile stability in the blast furnace.
Reduction of CO2 emissions due to partial substitution of coal by a renewable fuel, like woody biomass, is a subject of increasing interest in the ironmaking process. Additionally, the combination of biomass combustion with CO2 capture technologies, such as oxy-fuel, could allow a negative CO2 balance for industrial processes. This study aims to investigate the combustibility of eucalyptus densified at different temperatures compared to coals of similar volatile matter contents typically used for Pulverized Coal Injection (PCI) in blast furnace. Combustion at different O2/N2 (conventional combustion) and O2/CO2 (oxy-fuel combustion) concentrations of pulverized samples was carried out in a Drop Tube Furnace (DTF) at 1300 °C. The characteristics of the chars were evaluated by their reactivity to CO2 in thermobalance, optical microscopy and adsorption isotherms techniques. The conversion of thermally-treated biomasses in the DTF was greater than that of the coals with similar volatile matter contents and combustion under oxy-fuel (O2/CO2) conditions appeared to be favored compared with conventional combustion (O2/N2) at the same oxygen concentration. The low volatile biomasses yielded isotropic char particles with cellular structure whereas the high volatile biomasses generated swollen particles with vacuolated cell walls which approach in appearance to those of low rank coal chars. The biomass yielded chars with higher micro- and mesopore surface areas than the coal chars of equivalent volatile yields, and greater surface areas at oxy-fuel conditions compared to conventional combustion chars. About 7–10% in average higher conversions were observed for the most reactive biomass and coal chars when combusted under oxy-fuel conditions in DTF. The higher combustibility and reactivity of biomass-chars compared to coal-chars in both O2/N2 and O2/CO2 environments could be positive to its incorporation in PCI providing a high reactivity fuel whose volatile matter could be adjusted depending on the needs to maintain the volatile stability in the blast furnace. •Combustion in a drop tube furnace of thermally-treated eucalyptus has been assessed.•Results are compared with those of coals with similar volatile matter yields.•Both conventional (O2/N2) and oxy-combustion (O2/CO2) atmospheres were tested.•Oxy-chars chars had higher reactivity and surface area than conventional chars.•Biomass chars were more reactive than coal chars from similar volatile yield fuels.
Author Pohlmann, Juliana G.
Vilela, Antônio C.F.
Borrego, Angeles G.
Osório, Eduardo
Diez, Maria Antonia
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  organization: Federal University of Rio Grande do Sul (UFRGS), Iron and Steelmaking Laboratory (LASID), P.O. Box 15021, 91501-970 Porto Alegre, RS, Brazil
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  givenname: Angeles G.
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  givenname: Eduardo
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  organization: Federal University of Rio Grande do Sul (UFRGS), Iron and Steelmaking Laboratory (LASID), P.O. Box 15021, 91501-970 Porto Alegre, RS, Brazil
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  givenname: Maria Antonia
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  givenname: Antônio C.F.
  surname: Vilela
  fullname: Vilela, Antônio C.F.
  organization: Federal University of Rio Grande do Sul (UFRGS), Iron and Steelmaking Laboratory (LASID), P.O. Box 15021, 91501-970 Porto Alegre, RS, Brazil
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Keywords Carbonization
CO2 mitigation
Torrefaction
Biomass
Blast
Furnace injection
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Snippet Reduction of CO2 emissions due to partial substitution of coal by a renewable fuel, like woody biomass, is a subject of increasing interest in the ironmaking...
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SubjectTerms Biomass
Blast
carbon dioxide
Carbonization
cell walls
charcoal
CO2 mitigation
coal
combustion
Eucalyptus
Furnace injection
furnaces
greenhouse gas emissions
microscopy
oxygen
renewable energy sources
sorption isotherms
temperature
Torrefaction
Title Combustion of eucalyptus charcoals and coals of similar volatile yields aiming at blast furnace injection in a CO2 mitigation environment
URI https://dx.doi.org/10.1016/j.jclepro.2016.04.138
https://www.proquest.com/docview/2000294583
Volume 129
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