Physical Simulation Study on Influence of Iron Ore Melting Point on Cohesive Zone and Material Layer

X. Zhou, Chuan‐Yu Zhang, Song Pu, Kai Yang, Zhe Shi
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引用次数: 1

Abstract

A physical model of melting furnace for producing molten iron is established. Paraffin particles are used to simulate ores. Corn particles are used to simulate coke. The gas phase temperature in the furnace was measured with a temperature sensor. The temperature gradient analysis was used to study the effect of cohesive zone on the material layer. The study found that the higher the melting point of the experimental materials, the higher the cohesive zone temperature, resulting in the higher the overall temperature of the material layer, which is conducive to improving the utilization rate of gas. At the same time, the heat transfer process of cohesive zone will become more intense. The results presented in this paper will have certain guiding significance for the research of cohesive zone and solid layer of blast furnace.
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铁矿石熔点对粘结带和料层影响的物理模拟研究
建立了用于生产铁水的熔炼炉的物理模型。石蜡颗粒被用来模拟矿石。玉米颗粒被用来模拟焦炭。使用温度传感器测量炉中的气相温度。采用温度梯度分析法研究了粘结区对材料层的影响。研究发现,实验材料的熔点越高,粘结区温度就越高,导致材料层的整体温度越高,有利于提高气体的利用率。同时,粘结区的传热过程将变得更加强烈。本文的研究结果对高炉粘结区和固体层的研究具有一定的指导意义。
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来源期刊
Nanoscience and Nanotechnology Letters
Nanoscience and Nanotechnology Letters Physical, Chemical & Earth Sciences-MATERIALS SCIENCE, MULTIDISCIPLINARY
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审稿时长
2.6 months
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