ISSN 2594-357X
Title
Authorship
DOI
Downloads
Abstract
The steel industry is under pressure to reduce its CO2 emissions, which arise from the use of fossil coal. In the long-term, the injection of pulverized particles of charcoal from biomass (biochar) through the BF tuyerees, here called Bio-PCI (Bio-Pulverized Carbon Injection), offers attractive features from the environmental and metallurgical viewpoints. Biochar presents advantages based on its carbon-neutrally and on its imparting fewer impurities to the iron than coke. The potential of Bio-PCI, has been assessed from its CO2 abatement potential and economic point of view. A cost objective function has been used to measure the impact on iron production of biochar substitution in highly fuel efficient BF among the top 9 hot metal producers; estimations are based on cost determinants in ironmaking. This contribution aims to shed light on two strategic questions: under which conditions can be economically attractive to implement Bio-PCI? And where is such a techno-economic innovation likely to be taken up earliest? Results indicate a potential CO2 mitigation of 18% – 40% with respect current emission rates; on the economic assessment findings show that biochar cannot solely on price compete with fossil coal, thus lower biochar cost or the introduction of carbon taxes are necessary to increment the competitiveness of Bio-PCI. Based on actual prices of raw materials, electricity and carbon taxes, biochar should be between 130.1 – 236.4 USD/t and carbon taxes 47.1 – 198.7 USD/t CO2 to facilitate Bio-PCI substitution in examined countries. With respect to the implementation, Brazil, followed by India, China and USA appeared to be in better position to deploy Bio-PCI.
The steel industry is under pressure to reduce its CO2 emissions, which arise from the use of fossil coal. In the long-term, the injection of pulverized particles of charcoal from biomass (biochar) through the BF tuyerees, here called Bio-PCI (Bio-Pulverized Carbon Injection), offers attractive features from the environmental and metallurgical viewpoints. Biochar presents advantages based on its carbon-neutrally and on its imparting fewer impurities to the iron than coke. The potential of Bio-PCI, has been assessed from its CO2 abatement potential and economic point of view. A cost objective function has been used to measure the impact on iron production of biochar substitution in highly fuel efficient BF among the top 9 hot metal producers; estimations are based on cost determinants in ironmaking. This contribution aims to shed light on two strategic questions: under which conditions can be economically attractive to implement Bio-PCI? And where is such a techno-economic innovation likely to be taken up earliest? Results indicate a potential CO2 mitigation of 18% – 40% with respect current emission rates; on the economic assessment findings show that biochar cannot solely on price compete with fossil coal, thus lower biochar cost or the introduction of carbon taxes are necessary to increment the competitiveness of Bio-PCI. Based on actual prices of raw materials, electricity and carbon taxes, biochar should be between 130.1 – 236.4 USD/t and carbon taxes 47.1 – 198.7 USD/t CO2 to facilitate Bio-PCI substitution in examined countries. With respect to the implementation, Brazil, followed by India, China and USA appeared to be in better position to deploy Bio-PCI.
Keywords
PCI; Biochar; Pulverized carbon injection (PCI); Sustainable ironmaking.
PCI; Biochar; Pulverized carbon injection (PCI); Sustainable ironmaking.
How to refer
Feliciano-Bruzual, Cristobal;
Mathews., John.
BIO-PCI A RENEWABLE REDUCTANT FOR BLAST FURNACES:
CO2 MITIGATION POTENTIAL AND ECONOMICAL
ASSESSMENT
,
p. 1913-1927.
In: 42º Seminário de Redução de Minério de Ferro e Matérias-primas / 13º Seminário Brasileiro de Minério de Ferro / 6th International Congress on the Science and Technology of Ironmaking,
Rio de Jabeiro,
2012.
ISSN: 2594-357X
, DOI 10.5151/2594-357X-22337