Phase composition and thermal properties of the Sakharinskoe deposit oxidized nickel ore

E. Selivanov, S. Sergeeva, R. Gulyaeva
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引用次数: 3

Abstract

X-ray diffraction, optical microscopy and X-ray microanalysis were used to determine the composition and distribution of elements in the main mineral constituents of oxidized nickel ore at the Sakhalin deposit (goethite, hematite, serpentine, talc and chlorite). The main fraction of nickel is concentrated in iron oxides, where its content reaches 2,4 %, while in magnesium silicates it does not exceed 0,4 %. The sequence and temperature intervals of transformations were established when heating ore in inert and reducing media by means of thermal analysis methods combined with mass-spectrometric analysis of gases and subsequent X-ray phase analysis of products. The temperature regimes of ore roasting for the reduction of nickel and iron from their minerals were justified. The temperature regimes of sample heating are assumed to be close to the conditions implemented in industrial units (electric furnaces) where the rate of charge heating varies within 5—15 degrees/min, up to the melting point (1450 °С) of ferronickel and slag. It is proposed to use information on material composition, thermal properties and metal forms in ore to select regimes and technologies for their pyro-or hydrometallurgical processing. Nickel and iron recovery from oxides in CO environment occurs above 800 °С, while serpentines remain stable up to 1200 °С. The use of coke as a reducing agent allows reducing iron and nickel from serpentines at temperatures above 1250 °С. The obtained data were used to substantiate the operating conditions of roaster and electric furnaces during ferronickel smelting from oxidized ores. When roasting, resulting ferronickel particles will contain 2—4 % Ni. Completing recovery processes in the electric furnace will ensure metal recovery from magnesium silicates, which will slightly increase the nickel content in ferro-nickel.
萨哈林斯克矿床氧化镍矿物相组成及热性质
采用x射线衍射、光学显微镜和x射线显微分析方法测定了库页岛镍矿氧化镍矿石主要矿物成分(针铁矿、赤铁矿、蛇纹石、滑石和绿泥石)的元素组成和分布。镍的主要组分集中在氧化铁中,其含量达到2.4%,而在硅酸镁中,其含量不超过0.4%。采用热分析方法,结合气体质谱分析和产物x射线相分析,确定了在惰性介质和还原介质中加热矿石时的相变顺序和温度区间。对从镍和铁的矿物中还原镍和铁的焙烧温度进行了论证。样品加热的温度范围被假设接近于工业装置(电炉)中实施的条件,其中电荷加热速率在5-15度/分钟内变化,直到镍铁和炉渣的熔点(1450°С)。建议利用矿石中的材料成分、热性质和金属形态的资料来选择其热法或湿法冶金处理的制度和技术。在CO环境中,镍和铁可以在800°С以上的温度下从氧化物中回收,而蛇纹石在1200°С以上保持稳定。使用焦炭作为还原剂,可以在1250°以上的温度下还原蛇纹石中的铁和镍С。用所得数据验证了焙烧炉和电炉在氧化矿石冶炼镍铁过程中的操作条件。当焙烧时,产生的镍铁颗粒将含有2 - 4%的Ni。在电炉中完成回收工艺将确保从硅酸镁中回收金属,这将略微增加镍铁中的镍含量。
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