A Numerical Study of Scenarios for the Substitution of Pulverized Coal Injection by Blast Furnace Gas Enriched by Hydrogen and Oxygen Aiming at a Reduction in CO2 Emissions in the Blast Furnace Process

Castro, José Adilson de; Medeiros, Guilherme Cardoso; Silva, Leonardo Martins da; Ferreira, Itamar; Campos, Marcos Flávio de; Oliveira, Elizabeth Mendes de

doi:10.3390/met13050927

Cited by 3 publications

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References 46 publications

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“…The rational use of H 2 in the process of ironmaking has a more significant effect on reducing energy consumption and CO 2 emissions. People continue to carry out experimental research on and theoretical simulations of various iron ore products (pellets, sinter, ore powder) under various atmospheres [1][2][3][4][5][6]. It is generally believed that the reaction rate and diffusion capacity of iron ore or pellets under a CO reduction atmosphere are much lower than those under the conditions relating to H 2 [7][8][9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Comparison of Microstructures of Magnetite Reduced by H2 and CO under Microwave Field

Zhou,

Ai,

Hong

et al. 2023

Metals

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The reduction of magnetite in H2 and CO atmospheres was compared using a microwave-heating technique. The reduction of magnetite in a mixed H2 + CO atmosphere was compared with respect to the effects of a microwave field and a conventional field. Microstructural changes were observed using an electron microscope. The results show that the metallization rate and reduction degree of the H2-reduced magnetite are much higher than those of the magnetite reduced by CO at 900–1100 ℃. The Fe phase generated by H2 reduction forms a cavity structure, and the Fe phase generated by CO reduction forms a dense block. Under conventional heating conditions, the higher the H2 content in a pure CO atmosphere, the better the reduction effect. Under the effect of a microwave field, the atmosphere with the highest reduction rate was 50% H2 + 50% CO. Compared with conventional heating, the bubble holes formed by reduced iron in microwave field are larger under the same conditions.

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