Dead-Man Behavior in the Blast Furnace Hearth—A Brief Review

Shao, Lei; Xiao, Qilin; Zhang, Chengbo; Zou, Zhongshu; Saxén, Henrik

doi:10.3390/pr8111335

Cited by 12 publications

(7 citation statements)

References 62 publications

(106 reference statements)

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“…[ 44,45 ] Many scholars have studied the flow of molten iron in the hearth during tapping using experiments and numerical simulation. [ 29,46–49 ] Komiyama et al [ 29 ] built a three‐dimensional computational fluid dynamics model of Kembla No. 5 BF.…”

Section: Erosion Mechanism Of Hearth Refractoriesmentioning

confidence: 99%

Erosion Behavior and Longevity Technologies of Refractory Linings in Blast Furnaces for Ironmaking: A Review

Cui

Wang

et al. 2022

steel research int.

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Erosion of the refractory materials in blast furnaces (BFs) greatly limits their campaign life, which seriously reduces the economic benefits of iron and steel plants and endangers workers. Therefore, it is important to detect and monitor the erosion process of refractory materials in the BF hearth. In this review, the mechanisms of physical damage, chemical corrosion, and mechanical erosion of BF hearths during BF operation are analyzed and summarized. In addition, the effects of hearth structure, refractory type, and protective layer on hearth erosion behavior and hearth life are analyzed and discussed. Some longevity technologies of BF hearths are analyzed and compared, such as reasonable hearth structure design, refractory selection, and technologies to form protective layers. Finally, some suggestions and prospects for the future development of long campaign life BF hearths are discussed.

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Section: Erosion Mechanism Of Hearth Refractoriesmentioning

confidence: 99%

Erosion Behavior and Longevity Technologies of Refractory Linings in Blast Furnaces for Ironmaking: A Review

Cui

Wang

et al. 2022

steel research int.

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“…For continuous tapping of slag and molten metal in huge blast furnaces having many tapholes, slag, and metal discharge simultaneously [15]. The molten metal on account of higher density and lower viscosity can easily flow to the taphole through a 'coke-free' path [16] while the slag has to go through the hearth coke bed and experience additional flow resistance. This phenomenon might result in slag accumulation below the taphole area even if the taphole appears dry enough.…”

Section: Introductionmentioning

confidence: 99%

“…The slag tap-to-tap time is directly associated with slag viscosity which highlights the importance of always maintaining a slag with high fluidity for improving productivity and fuel consumption. Slag viscosity is also described as a property that links the slag flow behaviour to the reaction kinetics and the degree of reduction of the final slag [16]. The slag viscosity impacts gas permeability, heat transmission, and the reduction of SiO 2 , FeO, and other elements [18].…”

Section: Introductionmentioning

confidence: 99%

Optimization of high alumina slag practice in blast furnace ironmaking: an industrial approach (PART 1: fundamental aspects)

Hazra,

Pal,

Biswajeet

et al. 2023

Ironmaking & Steelmaking

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The productivity of the blast furnace Ironmaking process is significantly dependent on the slag chemistry. The presence of compounds like Al 2 O 3 in high quantities can make the hearth slag highly viscous and difficult to tap. The objective of part-1 of this study is to provide a comprehensive analysis of the role of high alumina (Al 2 O 3 > 15%) compositions in the blast furnace slags. Slag viscosity, liquidus temperature, activation energy, etc., are critically reviewed with respective solutions to operate under the desired conditions. Flow parameters of the slag are examined to understand the melting-softening phenomena which directly affect the slag tap-totap time. The addition of certain additives to the slag system has also been studied with the aim to improve the target properties of the slag. A range of slag compositions and their optimization techniques are discussed in this part to provide greater insight into the topic.

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“…The deadman occupies 70% of the volume of the blast furnace hearth. 3,4 The performance of hearth coke directly determines the hearth activity, production capacity, and longevity potential of the blast furnace. 5−9 Therefore, it is necessary to study the performance of the hearth coke, particularly its graphitization degree and consumption pathway.…”

Section: Introductionmentioning

confidence: 99%

“…It takes a long time for coke to be renewed in the blast furnace hearth, so the accumulation of coke for a long time leads to the formation of deadman. The deadman occupies 70% of the volume of the blast furnace hearth. , The performance of hearth coke directly determines the hearth activity, production capacity, and longevity potential of the blast furnace. − Therefore, it is necessary to study the performance of the hearth coke, particularly its graphitization degree and consumption pathway. The degree of coke graphitization and consumption pathway are influenced by the target annealing time and temperature, which can reflect the renewal time of the blast furnace.…”

Section: Introductionmentioning

confidence: 99%

Graphitization and Performance of Deadman Coke in a Large Dissected Blast Furnace

et al. 2021

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The graphitization and performance of deadman coke in the blast furnace hearth have an essential influence on the longevity of the blast furnace. In this paper, coke samples were obtained from various heights in a hearth during the overhaul of the blast furnace. The voidage, particle size, graphitization degree, microstructure, and structure evolution of multiple cokes were analyzed through digital image processing, XRD, Raman spectra, scanning electron microscopy, and energy-dispersive X-ray spectroscopy (SEM-EDS). The graphitization results were compared with feed coke, tuyere coke, cohesive zone coke, and deadman coke in reference, and the main findings were analyzed. The following results were obtained. First, the voidage of deadman coke increased and then decreased with the increase of the depth while the particle size continued to decrease. In addition, the consumption rate of coke as a carburizer, reductant, and heart source was 8.47, 30.95, and 60.58%, respectively. Second, the graphitization degree of deadman coke was extremely high and showed a trend of first increasing and then decreasing. Finally, the evolution mechanism of coke graphitization was proposed. Molten iron, alkali metal, temperature, and mineral were the crucial factors that affect the graphitization of coke. The turning point of the graphitization degree was related to the buoyancy of the hearth.

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Dead-Man Behavior in the Blast Furnace Hearth—A Brief Review

Cited by 12 publications

References 62 publications

Erosion Behavior and Longevity Technologies of Refractory Linings in Blast Furnaces for Ironmaking: A Review

Erosion Behavior and Longevity Technologies of Refractory Linings in Blast Furnaces for Ironmaking: A Review

Optimization of high alumina slag practice in blast furnace ironmaking: an industrial approach (PART 1: fundamental aspects)

Graphitization and Performance of Deadman Coke in a Large Dissected Blast Furnace

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