Studying the Compressibility of Ground Metallurgical Raw Materials

IF 0.9 4区 材料科学 Q3 MATERIALS SCIENCE, CERAMICS Powder Metallurgy and Metal Ceramics Pub Date : 2023-08-14 DOI:10.1007/s11106-023-00362-9
A. Yu. Khudyakov, S. V. Vashchenko, K. V. Baiul, Yu. S. Semenov
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Abstract

The pelletizing of fine-grained mineral raw materials for ferrous metallurgy is studied. Relationships between the compressibility of metallurgical charges and the nature of the raw materials and process factors of the pelletizing process were studied in laboratory conditions. A new measure, such as the compressibility of ground materials, was introduced to quantify and compare compression performances. A mathematical description of the relationships between the compression coefficient and the following factors was formulated through nonlinear regression analysis and experiment design theory methods: the plasticizer content (varying from 0 to 50%), moisture content of the charge (from 0 to 10%), hardness of the particles according to the mineralogical scale (from 2 to 6 units), dynamic viscosity of the binder (from 1 to 657 mPa · sec), amount of the carbon-containing component (from 10 to 90%), and particle sizes of the iron- and carbon-containing components in the charge (from 1 to 4 mm). The compaction pressure range was limited to 220 MPa. Three mathematical models were developed to establish relationships between the charge compressibility and the specified factors as polynomial dependencies and as a Lorentz function. The quality of the models was verified using standard statistical indicators, including the Cochran and Fisher tests and the average relative error. Analysis of the models involved the solution of relevant optimization problems. Extremes of the functions for metallurgical charges were identified and process recommendations were made. The results have practical implications for improving the compressibility of charges from mineral raw materials and developing optimal pelletizing methods.

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地面冶金原料的可压缩性研究
研究了冶金用细粒矿物原料的造球工艺。在实验室条件下,研究了冶金炉料压缩性与原料性质及制球过程工艺因素的关系。引入了一种新的测量方法,如地面材料的压缩性,来量化和比较压缩性能。通过非线性回归分析和实验设计理论方法,建立了压缩系数与以下因素之间关系的数学描述:增塑剂含量(0 ~ 50%)、料体含水率(0 ~ 10%)、颗粒按矿物学尺度的硬度(2 ~ 6个单位)、粘结剂的动态粘度(1 ~ 657 mPa·sec)、含碳组分的量(10 ~ 90%)、料体中含铁和含碳组分的粒度(1 ~ 4mm)。压实压力范围限定在220 MPa。建立了三个数学模型,建立了电荷可压缩性与指定因子之间的多项式依赖关系和洛伦兹函数关系。使用标准统计指标(包括Cochran和Fisher检验以及平均相对误差)验证模型的质量。对模型的分析涉及到相关优化问题的求解。确定了冶金炉料的极端功能,并提出了工艺建议。研究结果对提高矿物原料装药的可压缩性和开发最佳造球方法具有实际意义。
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来源期刊
Powder Metallurgy and Metal Ceramics
Powder Metallurgy and Metal Ceramics 工程技术-材料科学:硅酸盐
CiteScore
1.90
自引率
20.00%
发文量
43
审稿时长
6-12 weeks
期刊介绍: Powder Metallurgy and Metal Ceramics covers topics of the theory, manufacturing technology, and properties of powder; technology of forming processes; the technology of sintering, heat treatment, and thermo-chemical treatment; properties of sintered materials; and testing methods.
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