云南某钛铁矿选矿试验研究

胡渝杰; 叶国华; 唐悦; 陶媛媛

doi:10.7513/j.issn.1004-7638.2021.04.006

云南某钛铁矿选矿试验研究

doi: 10.7513/j.issn.1004-7638.2021.04.006

昆明理工大学国土资源工程学院，云南昆明 650093

详细信息

作者简介:
胡渝杰（1997−），男，重庆长寿人，硕士研究生，主要研究方向：钒钛提取，E-mail：lby1by@163.com

通讯作者:
叶国华（1981−），男，博士，副教授，E-mail：ghye581@163.com

中图分类号: TF823,TD924
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出版历程
- 收稿日期: 2021-05-19
- 刊出日期: 2021-08-10

Experimental study on beneficiation of a titaniferous iron ore in Yunnan

Faculty of Land Resource Engineering, Kunming University of Science and Technology, Kunming 650093, Yunnan, China

摘要

摘要: 以云南某低品位钛铁矿为研究对象，原矿含钛（TiO₂）仅为5.67%，大部分单独存在于钛铁矿中，占矿石中TiO₂总量的83.56%，其余部分以类质同象的形式存在于磁铁矿和辉石中，占16.44%，脉石矿物主要包括石英、绿泥石等。针对该钛铁矿开展选矿试验，目的是通过选矿试验研究，寻求合理的工艺流程，对该资源的开发提供理论依据，可以使钛矿资源得到充分利用。首先查明了该矿石的化学组分、矿物组成，其次进行了磨矿细度、弱磁磁场强度、强磁磁场强度等工艺参数条件研究。在此基础上通过“磨矿-弱磁-强磁-强磁-分级摇床重选-中矿再磨再选”联合工艺流程，最终可获得TiO₂品位为45.06%的钛精矿，回收率（对原矿）为53.73%；指标较好，实现了对目的矿物的有效回收。
- 钛铁矿 /
- 磁选 /
- 重选 /
- 品位 /
- 回收率
Abstract: A low-grade ilmenite ore in Yunnan province contains only 5.67% titanium (TiO₂), and most of Ti exists in ilmenite alone, occupying 83.56% of the total TiO₂ in the ore. The rest of 16.44% Ti exists in magnetite and pyroxene in a homogeneous form, and the vein minerals mainly include quartz and chlorite, etc. The beneficiation test for the ilmenite was carried out to seek a reasonable process flow and provide a theoretical basis for the development of this resource, which can make a sufficient use of titanium ore resources. Firstly, the chemical components and mineral compositions of the ore were identified. Then, the process parameters such as grinding fineness, weak magnetic field strength and strong magnetic field strength were studied. On this basis, the combined process of “grinding-weak magnetic separation-strong magnetic separation-strong magnetic separation-graded shaking table re-election-medium ore regrinding and re-election” was proposed. The titanium concentrate containing 45.06% TiO₂ can be finally obtained, with the recovery rate (for the original ore) of 53.73%. The proposed process realizes effective recovery of the target minerals with a well index.
- ilmenite /
- magnetic separation /
- gravity separation /
- TiO₂ grade /
- recovery rate

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图 1 钛铁矿与磁赤铁矿紧密连生

Figure 1. Microstructure of ilmenite closely associated with magnetite and hematite

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图 2 钛铁矿内部杂质

Figure 2. Impurities in ilmenite

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图 3 弱磁精矿试验结果

Figure 3. Weak magnetic concentrate test results

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图 4 磁选磨矿细度试验

Figure 4. Magnetic separation grinding fineness test results

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图 5 强磁磁场强度条件试验

Figure 5. Strong magnetic field strength test results

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图 6 全流程工艺试验

Figure 6. Full-flow process testing

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表 1 原矿破碎至−2 mm粒级筛析结果

Table 1. Results of screen analysis of raw ore crushed to −2 mm of particle size

粒级/mm	产率/%	TiO₂品位/%	回收率/%
2～1	28.49	5.48	27.79
1～0.45	21.16	5.75	21.65
0.45～0.2	18.25	7.68	24.95
0.2～0.074	7.79	8.02	11.12
0.074～0.037	9.6	6.36	10.86
0.037～0.019	5.05	2.12	1.90
0.019～0.010	2.84	1.52	0.77
0.010～0.005	0.94	1.32	0.22
−0.005	5.9	0.7	0.74
合计	100	5.67	100

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表 2 原矿主要化学成分

Table 2. Main chemical compositions of raw ore

%
TiO₂	Fe	Al₂O₃	S	P	MgO
5.67	12.36	13.69	0.009	0.18	5.33

CaO	SiO₂	V₂O₅	Na₂O	K₂O	As
9.10	45.87	0.093	1.48	0.73	<0.1

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表 3 原矿矿物含量分析

Table 3. Mineral content of raw ore

矿物	矿物含量/%	矿物中钛（TiO₂）的分布率/%
钛铁矿	8.5	83.56
磁铁矿	2.1	5.55
脉石矿物	89.4	10.89

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表 4 弱磁场强条件试验结果

Table 4. Weak magnetic field strength test results

弱磁场强/T	产品名称	产率/%	TiO₂品位/%	TiO₂回收率/%
0.15	精矿	1.79	14.65	4.58
0.15	尾矿	98.21	5.57	95.42
0.20	精矿	1.82	14.17	4.81
0.20	尾矿	98.18	5.58	95.19
0.25	精矿	2.62	15.08	6.72
0.25	尾矿	97.38	5.64	93.28
0.30	精矿	2.04	14.98	5.21
0.30	尾矿	97.96	5.67	94.79

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表 5 磁选磨矿细度试验结果

Table 5. Magnetic separation grinding fineness test results

细度/%	产品/%	产率/%	TiO₂品位/%	TiO₂回收率/%
50	强磁精矿	31.81	17.94	83.57
	强磁尾矿	68.19	1.03	16.43
	给矿	100	6.83	100

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表 6 强磁磁场强度条件试验结果

Table 6. Test results of strong magnetic field strength condition

强磁选场强/T	产品	产率/%	TiO₂品位/%	TiO₂回收率/%
1.0	强磁精矿	31.73	16.03	82.27
	强磁尾矿	68.27	0.95	17.73
	给矿	100	6.18	100

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表 7 两段强磁粗选抛尾试验结果

Table 7. Two-stage strong magnetic roughing tailing test results

产品名称	产率/%	TiO₂品位/%	TiO₂回收率/%
弱磁精矿	1.9	14.16	4.71
钛粗精矿	28.69	15.81	79.59
中矿	6.16	5.18	5.6
尾矿	63.25	0.91	10.1
给矿	100	5.7	100

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表 8 强磁粗精矿进行分摇床精选的试验结果

Table 8. Experimental results of sub-shaker selection of strong magnetic coarse concentrate

产品名称	产率/%	TiO₂品位/%	TiO₂回收率/%
精矿合计	7.02	45.14	55.54
中矿合计	16.23	7.34	20.98
尾矿	5.64	4.29	4.25
强磁粗精矿	28.89	15.92	80.77

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表 9 全流程工艺结果

Table 9. Full process test results %

样品名称	产率	TiO₂品位	TiO₂回收率
精矿合计	8.63	45.06	58.43
中矿合计	27.77	6.24	30.57
尾矿	63.6	0.98	11.00
原矿	100	5.67	100

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表 10 钛精矿化学多元素分析结果

Table 10. Chemical compositions of titanium concentrate %

Fe	Al₂O₃	S	MgO	CaO	P	SiO₂	TiO₂	K₂O	Na₂O	As
35.97	1.01	0.0096	1.85	3.05	0.014	4.08	45.06	0.049	0.049	<0.10

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参考文献(10)

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