X射线衍射-扫描电镜等技术研究秘鲁铜硫矿石选矿工艺矿物学特征

曾广圣; 欧乐明

doi:10.15898/j.cnki.11-2131/td.201804130042

X射线衍射-扫描电镜等技术研究秘鲁铜硫矿石选矿工艺矿物学特征

曾广圣,
欧乐明^,

中南大学资源加工与生物工程学院, 湖南长沙 410083

基金项目:
国家重点基础研究发展计划（973）项目（2014CB643402）；国家自然科学基金项目（51674291）

详细信息

作者简介: 曾广圣, 硕士, 主要从事低碱度铜硫分离试验研究。E-mail:1976530700@qq.com

通讯作者: 欧乐明, 博士, 教授, 主要从事微细粒复杂矿物分选理论、工艺与设备和矿产资源综合利用与环保研究。E-mail:olm@csu.edu.cn

中图分类号: P575.2;P575.5

收稿日期: 2018-04-13

修回日期: 2018-10-16

录用日期: 2019-01-04

Study on Mineralogical Characteristics of Peru Copper-Sulphur Ore Dressing Process by X-ray Diffraction and Scanning Electron Microscope

Guang-sheng ZENG,
Le-ming OU^,

School of Minerals Processing and Bio-Engineering, Central South University, Changsha 410083, China

More Information

Corresponding author: Le-ming OU, olm@csu.edu.cn

Received Date: 13 April 2018

Revised Date: 16 October 2018

Accepted Date: 04 January 2019

摘要

摘要: 秘鲁铜硫矿石的主要回收对象是铜和硫矿物，由于铜矿物嵌布复杂、粒度过细以及与各种脉石矿物或金属矿物交生关系紧密，利用传统工艺矿物学研究方法如化学分析、光学显微镜检测等较难准确定量其工艺矿物学参数。本文采用化学分析、X射线衍射、扫描电镜、偏光显微镜及矿物参数自动分析系统（MLA）等技术手段，研究秘鲁铜硫矿石的化学成分、矿物组成和主要矿物的嵌布特征、粒度分布及单体解离特性等，并对影响选矿指标的主要矿物学因素进行分析。结果表明：矿石中主要元素为Cu（0.65%）和S（9.53%）。矿石中黄铁矿（16.57%）含量较高，形态较为规则，与其他矿物之间的交生关系相对简单，粒度普遍偏粗，其中粒径大于0.30mm的黄铁矿占95.06%。铜矿物主要以不规则粒状、皮壳状、网脉状、纤维状、尘粒状、斑点状分布于脉石中或与黄铁矿、闪锌矿、磁铁矿等金属矿物交生紧密，粒度极不均匀，使得铜矿物解离难度加大，且矿石中云母（12.51%）、绿泥石（3.74%）、滑石（3.34%）、高岭石、蒙脱石（3.59%）等黏土质矿物含量较高，在磨矿过程中易发生泥化从而恶化分选环境。根据该类型矿石的工艺矿物学特性，本文建议采用"粗磨-部分优先浮铜-铜硫混浮-混合精矿再磨再选分离"的工艺流程，可得到质量高的铜、硫精矿。
- 矿物参数自动分析系统 /
- 铜硫矿石 /
- 工艺矿物学 /
- 黏土矿物 /
- 扫描电镜
Abstract: BACKGROUNDThe main recovered minerals of copper sulfur ores in Peru were copper minerals and sulfur minerals. Due to the complexity of the embedded copper minerals, the superfine granularity of copper minerals and their close relationship with various gangue or metal minerals, the traditional process mineralogy research methods, such as chemical analysis and optical microscope detection, were difficult to quantify their process mineralogical parameters accurately. OBJECTIVESTo systematically investigate the process mineralogy of copper-sulfur ore in Peru. METHODSBy means of chemical analysis, X-ray Diffraction, Scanning Electron Microscope, Polarizing Microscope and Mineral Liberation Analysis, the systematic process mineralogy of copper-sulfur ores including chemical composition, mineral composition, occurrences of main minerals, particle size distribution and monomer dissociation characteristics were investigated, and the main mineralogical factors affecting the mineral dressing index were analyzed. RESULTSThe main elements in the ore were Cu (0.65%) and S (9.53%). The content of pyrite (16.57%) in the ore was relatively high, and its morphology was regular. The relationship between pyrite and other minerals was relatively simple, and the particle size was generally coarse. Pyrite particle size larger than 0.30mm accounted for 95.06%. However, the copper minerals were mainly irregular granular, shell shaped, reticulated, fibrous, dust-like, and speckled in gangue minerals or intersected with pyrite, sphalerite, magnetite and other metal minerals. The uneven particle size of copper minerals makes the dissociation of copper minerals more difficult. Moreover, the contents of clay minerals such as mica (12.51%), chlorite (3.74%), talc (3.34%), kaolinite and montmorillonite (3.59%) were abundant in the ore. During grinding, mudding occurred easily, which worsened the separation environment. CONCLUSIONSThe mineral processing flowsheet of coarse grinding-partially preferred floating copper-copper sulfur mixed flotation-mixed concentrate regrinding and separation can be used in copper-sulfur ore of Peru.
- Mineral Liberation Analysis /
- copper-sulfur ore /
- process mineralogy /
- clay minerals /
- Scanning Electron Microscope

HTML全文

图 1 黄铜矿的嵌布状态(扫描电镜)

Figure 1.

下载: 全尺寸图片幻灯片

图 2 辉铜矿和铜蓝的嵌布状态(偏反光显微镜)

Figure 2.

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图 3 黄铁矿的嵌布状态(偏反光显微镜)

Figure 3.

下载: 全尺寸图片幻灯片

图 4 主要矿物的粒度特性分布

Figure 4.

下载: 全尺寸图片幻灯片

表 1 主要矿物的解离度

Table 1. Dissociation degree of main minerals

矿物	磨矿细度	单体	连生体(%)
矿物	磨矿细度	单体	>3/4	3/4~1/2	1/2~1/4	< 1/4
铜矿物	-0.074μm 50%	55.38	13.84	9.05	7.06	14.67
铜矿物	-0.074μm 65%	70.69	7.55	5.74	5.01	11.01
黄铁矿	-0.074μm 50%	87.45	10.38	1.01	0.69	0.47
黄铁矿	-0.074μm 65%	93.51	5.94	0.34	0.16	0.05

下载: 导出CSV

表 2 铜矿物和黄铁矿连生体与不同矿物嵌连的比例

Table 2. Ratio of copper minerals and pyrite associated minerals to different minerals

连生矿物	占铜矿物连生体的比例 (%)		占黄铁矿连生体的比例 (%)
连生矿物	-0.074μm 50%	-0.074μm 65%	-0.074μm 50%	-0.074μm 65%
辉钼矿	微量	微量	0.40	0.00
铜矿物	-	-	30.92	33.44
黄铁矿	36.91	44.12	-	-
石英	15.71	5.15	10.68	8.63
长石	6.12	8.39	7.41	7.70
闪石/石榴石	10.28	7.10	9.09	8.93
云母/绿泥石	11.16	15.35	14.82	17.57
滑石	3.81	5.08	4.22	7.55
高岭石/蒙脱石	6.19	6.31	3.74	3.39
磁铁矿	0.83	0.48	0.40	1.08
菱铁矿	6.52	4.85	14.66	6.63
其他	2.47	3.17	3.66	5.08
合计	100.00	100.00	100.00	100.00

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