高硫煤矸石中黄铁矿解离度和粒度对重选提硫效果的影响研究

doi:10. 11799/ ce202507026

摘要/Abstract

摘要：

为了高效回收高硫煤矸石中的黄铁矿资源，采用AMICS自动定量分析系统、X射线荧光光谱仪和摇床实验等测试和实验方法，结合摇床分选过程动力学分析，研究了高硫煤矸石的工艺矿物学特征以及高硫煤矸石中黄铁矿解离度对重选产品迁移规律的影响。结果表明，高硫煤矸石中黄铁矿占全硫含量的比例高达87.16%，且黄铁矿多与高岭土以板状、群体集合状或团块状等形式连生。采用摇床回收高硫煤矸石中的黄铁矿时，有效分选粒度下限为0.038mm，分选后的精矿中黄铁矿的解离情况较好，其单体解离度高达82.37%，而再选尾矿和粗选尾矿中的黄铁矿与其他矿物连生关系较为复杂，黄铁矿单体解离度较低。同时，煤矸石的粒度和单体解离度对其在摇床床面上的运动轨迹影响较大，黄铁矿单体解离度低于85%时，会造成黄铁矿不同程度地损失在尾矿中。

关键词: 高硫煤矸石 , 摇床 , 解离度 , 粒度 , 运动分析

Abstract:

In response to the complex issue regarding the influence of the liberation degree and particle size of pyrite in high-sulfur coal gangue on the sulfur recovery process through gravity separation, test and experimental methods such as the AMICS automatic quantitative analysis system, X-ray fluorescence spectrometer, and shaking table experiments, combined with the kinetic analysis of the shaking table separation process, were employed. The technological mineralogy characteristics of high-sulfur coal gangue and the influence of the liberation degree of pyrite in high-sulfur coal gangue on the migration law of gravity separation products were investigated. The results indicated that the ratio of pyrite to the total sulfur content in high sulfur coal gangue was as high as 87.16%, and pyrite was mostly associated with kaolinite in forms such as tabular, group aggregations, or lumps. When recovering pyrite from high-sulfur coal gangue using the shaking table, the lower limit of the effective separation particle size was 0.038 mm. The liberation of pyrite in the concentrate after separation was favorable, with a single liberation degree reaching as high as 82.37%. However, the pyrite in the re-election and roughing tailings had a more complex associated relationship with other minerals, and the single liberation degree of pyrite was relatively low. Meanwhile, the particle size and single liberation degree of coal gangue had a significant influence on their movement trajectories on the shaking table bed surface. When the single liberation degree of pyrite was lower than 85%, it would cause pyrite to be lost in the tailings to varying degrees.experiments, combined with the kinetic analysis of the shaking table separation process, were employed. The technological mineralogy characteristics of high-sulfur coal gangue and the influence of the dissociation degree of pyrite in high-sulfur coal gangue on the migration law of heavy separation products were investigated. The results indicated that the ratio of pyrite to the total sulfur content in high-sulfur coal gangue was as high as 87.16%, and pyrite was mostly associated with kaolinite in forms such as tabular, group aggregations, or lumps. When recovering pyrite from high-sulfur coal gangue using the shaking table, the lower limit of the effective separation particle size was 0.038 mm. The dissociation of pyrite in the concentrate after separation was favorable, with a single dissociation degree reaching as high as 82.37%. However, the pyrite in the re-election tailings and roughing tailings had a more complex associated relationship with other minerals, and the single dissociation degree of pyrite was relatively low. Meanwhile, the particle size and single dissociation degree of coal gangue had a significant influence on their movement trajectories on the shaking table bed surface. When the single dissociation degree of pyrite was lower than 85%, it would cause pyrite to be lost in the tailings to varying degrees.

中图分类号:

TD97
TD94

李大虎李大虎, 李若琦, 王鑫, 等.

高硫煤矸石中黄铁矿解离度和粒度对重选提硫效果的影响研究 [J]. 煤炭工程, 2025, 57(7): 194-202.

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