Experimental model study of liquid–liquid and liquid–gas interfaces during blast furnace hearth drainage

Weiqiang Liu; Lei Shao; Henrik Saxén

doi:10.3390/met10040496

Experimental model study of liquid–liquid and liquid–gas interfaces during blast furnace hearth drainage

Weiqiang Liu^*, Lei Shao, Henrik Saxén

^*Corresponding author for this work

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Abstract

The smooth drainage of produced iron and slag is a prerequisite for stable and efficient blast furnace operation. For this it is essential to understand the drainage behavior and the evolution of the liquid levels in the hearth. A two-dimensional Hele–Shaw model was used to study the liquid–liquid and liquid–gas interfaces experimentally and to clarify the effect of the initial amount of iron and slag, slag viscosity, and blast pressure on the drainage behavior. In accordance with the findings of other investigators, the gas breakthrough time increased and residual ratios for both liquids decreased with an increase of the initial levels of iron and slag, a decrease in blast pressure, and an increase in slag viscosity. The conditions under which the slag–iron interface in the end state was at the taphole and not below it were finally studied and reported.

Original language	English
Article number	496
Number of pages	21
Journal	Metals
Volume	10
Issue number	4
DOIs	https://doi.org/10.3390/met10040496
Publication status	Published - 9 Apr 2020
MoE publication type	A1 Journal article-refereed

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metals-10-00496Final published version, 5.59 MBLicence: CC BY

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title = "Experimental model study of liquid–liquid and liquid–gas interfaces during blast furnace hearth drainage",

abstract = "The smooth drainage of produced iron and slag is a prerequisite for stable and efficient blast furnace operation. For this it is essential to understand the drainage behavior and the evolution of the liquid levels in the hearth. A two-dimensional Hele–Shaw model was used to study the liquid–liquid and liquid–gas interfaces experimentally and to clarify the effect of the initial amount of iron and slag, slag viscosity, and blast pressure on the drainage behavior. In accordance with the findings of other investigators, the gas breakthrough time increased and residual ratios for both liquids decreased with an increase of the initial levels of iron and slag, a decrease in blast pressure, and an increase in slag viscosity. The conditions under which the slag–iron interface in the end state was at the taphole and not below it were finally studied and reported.",

author = "Weiqiang Liu and Lei Shao and Henrik Sax{\'e}n",

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T1 - Experimental model study of liquid–liquid and liquid–gas interfaces during blast furnace hearth drainage

AU - Liu, Weiqiang

AU - Shao, Lei

AU - Saxén, Henrik

N1 - vst

PY - 2020/4/9

Y1 - 2020/4/9

N2 - The smooth drainage of produced iron and slag is a prerequisite for stable and efficient blast furnace operation. For this it is essential to understand the drainage behavior and the evolution of the liquid levels in the hearth. A two-dimensional Hele–Shaw model was used to study the liquid–liquid and liquid–gas interfaces experimentally and to clarify the effect of the initial amount of iron and slag, slag viscosity, and blast pressure on the drainage behavior. In accordance with the findings of other investigators, the gas breakthrough time increased and residual ratios for both liquids decreased with an increase of the initial levels of iron and slag, a decrease in blast pressure, and an increase in slag viscosity. The conditions under which the slag–iron interface in the end state was at the taphole and not below it were finally studied and reported.

AB - The smooth drainage of produced iron and slag is a prerequisite for stable and efficient blast furnace operation. For this it is essential to understand the drainage behavior and the evolution of the liquid levels in the hearth. A two-dimensional Hele–Shaw model was used to study the liquid–liquid and liquid–gas interfaces experimentally and to clarify the effect of the initial amount of iron and slag, slag viscosity, and blast pressure on the drainage behavior. In accordance with the findings of other investigators, the gas breakthrough time increased and residual ratios for both liquids decreased with an increase of the initial levels of iron and slag, a decrease in blast pressure, and an increase in slag viscosity. The conditions under which the slag–iron interface in the end state was at the taphole and not below it were finally studied and reported.

U2 - 10.3390/met10040496

DO - 10.3390/met10040496

M3 - Article

SN - 2075-4701

VL - 10

JO - Metals

JF - Metals

IS - 4

M1 - 496

ER -

Experimental model study of liquid–liquid and liquid–gas interfaces during blast furnace hearth drainage

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