Negatively Catalyzed Gasification Characteristics of Metallurgical Coke and its Implication for Ironmaking Process

The design and control of blast furnace (BF) ironmaking must be optimized in order to be competitive and sustainable, particularly under the more and more demanding and tough economic and environmental conditions. To achieve this, it is necessary to understand the complex multiphase flow, heat and mass transfer, and global performance of a BF. In this paper injection of alternative reducing agents via lances in the tubers of blast furnaces is discussed to reduce the consumption of metallurgical coke. Besides liquid hydrocarbons and pulverized coal the injection of recycled waste plastics is possible, offering the opportunity to chemically reuse waste material and also utilize the energy contained in such remnants.

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Blast Furnace Ironmaking Process with Super-High TiO2 in the Slag: Sulfide Capacity

Metallurgical and Materials Transactions B ◽

10.1007/s11663-021-02192-9 ◽

2021 ◽

Author(s):

Jiawei Ling ◽

Zhengde Pang ◽

Yuyang Jiang ◽

Zhiming Yan ◽

Xuewei Lv

Keyword(s):

Blast Furnace ◽

Sulfide Capacity ◽

Blast Furnace Ironmaking ◽

Ironmaking Process

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Kinetic Modeling of CO2 and H2O Gasification Reactions for Metallurgical Coke Using a Distributed Activation Energy Model

ACS Omega ◽

10.1021/acsomega.1c00443 ◽

2021 ◽

Vol 6 (17) ◽

pp. 11436-11446

Author(s):

Yui Numazawa ◽

Yuki Hara ◽

Yoshiya Matsukawa ◽

Yohsuke Matsushita ◽

Hideyuki Aoki ◽

...

Keyword(s):

Activation Energy ◽

Kinetic Modeling ◽

Energy Model ◽

Metallurgical Coke ◽

Distributed Activation Energy Model

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Thermodynamic Study of Energy Consumption and Carbon Dioxide Emission in Ironmaking Process of the Reduction of Iron Oxides by Carbon

Energies ◽

10.3390/en14071999 ◽

2021 ◽

Vol 14 (7) ◽

pp. 1999

Author(s):

Guanyong Sun ◽

Bin Li ◽

Hanjie Guo ◽

Wensheng Yang ◽

Shaoying Li ◽

...

Keyword(s):

Carbon Dioxide ◽

Energy Consumption ◽

Iron Oxides ◽

Volume Fraction ◽

Minimum Energy ◽

Carbon Dioxide Emission ◽

Reduction Reactions ◽

Co2 Output ◽

Coupling Parameters ◽

Ironmaking Process

Carbon included in coke and coal was used as a reduction agent and fuel in blast furnace (BF) ironmaking processes, which released large quantities of carbon dioxide (CO2). Minimizing the carbon consumption and CO2 output has always the goal of ironmaking research. In this paper, the reduction reactions of iron oxides by carbon, the gasification reaction of carbon by CO2, and the coupling reactions were studied by thermodynamic functions, which were derived from isobaric specific heat capacity. The reaction enthalpy at 298 K could not represent the heat value at the other reaction temperature, so the certain temperature should be confirmed by Gibbs frees energy and gas partial pressure. Based on Hess’ law, the energy consumption of the ironmaking process by carbon was calculated in detail. The decrease in the reduction temperature of solid metal iron has been beneficial in reducing the sensible heat required. When the volume ratio of CO to CO2 in the top gas of the furnace was given as 1.1–1.5, the coupling parameters of carbon gasification were 1.06–1.28 for Fe2O3, 0.71–0.85 for Fe3O4, 0.35–0.43 for FeO, respectively. With the increase in the coupling parameters, the volume fraction of CO2 decreased, and energy consumption and CO2 output increased. The minimum energy consumption and CO2 output of liquid iron production were in the reduction reactions with only CO2 generated, which were 9.952 GJ/t and 1265.854 kg/t from Fe2O3, 9.761 GJ/t and 1226.799 kg/t from Fe3O4, 9.007 GJ/t and 1107.368 kg/t from FeO, respectively. Compared with the current energy consumption of 11.65 GJ/t hot metal (HM) and CO2 output of 1650 kg/tHM of BF, the energy consumption and CO2 of ironmaking by carbon could reach lower levels by decreasing the coupled gasification reactions, lowering the temperature needed to generate solid Fe and adjusting the iron oxides to improve the iron content in the raw material. This article provides a simplified calculation method to understand the limit of energy consumption and CO2 output of ironmaking by carbon reduction iron oxides.

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Effect of Coated Cow Dung on Fluidization Reduction of Fine Iron Ore particles

Processes ◽

10.3390/pr9071175 ◽

2021 ◽

Vol 9 (7) ◽

pp. 1175

Author(s):

Qiyan Xu ◽

Zhanghan Gu ◽

Ziwei Wan ◽

Mingzhu Huangfu ◽

Qingmin Meng ◽

...

Keyword(s):

Iron Ore ◽

Linear Velocity ◽

Operating Conditions ◽

Inhibition Mechanism ◽

Cow Dung ◽

Reduction Temperature ◽

Reduction Time ◽

Reducing Gas ◽

Fine Iron ◽

Ironmaking Process

The effects of reduction temperature, gas linear velocity, reduction pressure, reduction time, and reducing gas on the fluidized ironmaking process were studied for the fine iron Newman ore particles (0.154–0.178 mm) and the optimal experimental operating conditions were obtained. Under the optimal conditions, the effects of the coated cow dung on the reduction of fine iron ore particles were studied, and the inhibition mechanism of cow dung on particle adhesion in the fluidized ironmaking process was elucidated. The experimental results show that the optimal operating parameters are linear velocity of 0.6 m/s, reduction pressure of 0.2 MPa, reduction temperature of 1023 K, H2 as the reducing gas, and reduction time of 60 min. Cow dung can react with oxide in the ore powder to form a high melting point substance that can form a certain isolation layer, inhibit the growth of iron whiskers, and improve the fluidization.

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