Study on enrichment of titanium resources by treating titanium middling ore with KOH sub molten salt
-
摘要: 采用KOH亚熔盐处理钛中矿以实现钛资源的富集,考察了反应温度、反应时间、碱浓度和钛中矿粒度等因素对钛中矿分解情况的影响,采用X射线衍射分析了产物的物相,得出下述结论:①采用KOH亚熔盐处理钛中矿可实现钛中矿的有效分解,其较佳工艺参数为搅拌速度400 r/min,碱渣质量比6∶1,反应温度为240 °C,反应时间180 min,碱浓度为80%,原料粒度70~80 μm,在此反应条件下,钛中矿中钛的转化率达99%以上,铝的转化率98%以上,硅的转化率在85%以上;②X射线衍射分析表明,亚熔盐分解产物经800 °C的高温煅烧3 h后测得的产物主要为六钛酸钾(K2Ti6O13),说明KOH可有效分解钛中矿并去除其中的铝、硅等元素。Abstract: The treatment of titanium middling ore with KOH sub molten salt was studied to realize the enrichment of titanium resources. The effects of reaction temperature, reaction time, alkali concentration and particle size on the decomposition of titanium middling ore were investigated, and the phase of the product was analyzed by X-ray diffraction. The following conclusions were drawn. Firstly, the effective decomposition can be realized by treating titanium middling ore with KOH sub molten salt. The better process parameters include stirring speed of 400 r/min, alkali residue mass ratio of 6∶1, reaction temperature of 240 ℃, reaction time of 180 min, alkali concentration of 80%, raw material particle size of 70~80 µm. Under these reaction conditions, the decomposition rate of titanium in the ore is more than 99% , while the decomposition rate of aluminum and silicon is more than 98% and 85%, respectively. Secondly, X-ray diffraction analysis shows that the decomposition product of sub molten salt is mainly potassium hexatitanate (K2Ti6O13) after calcination at 800 ℃ for 3 h, indicating that KOH can effectively decompose titanium middling ore and remove aluminum, silicon and other elements.
-
Key words:
- titanium extraction /
- titanium middling ore /
- KOH sub molten salt /
- decomposition rate
-
图 2 反应温度对钛、铝、硅转化率的影响
Figure 2. Effect of reaction temperature on conversion of Ti, Al and Si
图 4 碱浓度对钛、铝、硅转化率的影响
Figure 4. Effect of KOH concentration on conversion of Ti, Al and Si
图 5 粒度对钛、铝、硅转化率的影响
Figure 5. Effect of mineral particle size on conversion of Ti, Al and Si
图 6 碱矿质量比对钛、铝、硅转化率的影响
Figure 6. Effect of mass ratio of alkali to ore on conversion of Ti, Al and Si
图 7 搅拌速度比对钛、铝、硅转化率的影响
Figure 7. Effect of stirring speed on conversion of Ti, Al and Si
图 8 产物经 800 ℃煅烧 3 h 后的 X 射线衍射谱
Figure 8. X-ray diffraction spectrum of the product calcined at 800 ℃ for 3 h
表 1 钛中矿的化学组成
Table 1. Main chemical composition of the titanium middling ore
% TiO2 TFe FeO MgO SiO2 CaO Al2O3 29.62 33.56 30.08 4.27 8.07 2.29 2.38 
下载: 导出CSV
表 2 优化工艺条件下钛中矿的分解情况
Table 2. Decomposition of titanium middling ore under optimized process conditions
编号 转化率/% Ti Al Si 1 99.1 98.2 85.8 2 99.1 98.4 86.1 3 99.2 98.1 85.9
下载: 导出CSV
-
[1] Zhao Guojun, Zhao Qibin, Lan Jingzhi, et al. Characteristics of vanadium titanium magnetite resources and new beneficiation technology in Panxi area[J]. Modern Mining, 2017,33(7):198−200. (赵国君, 赵祺彬, 兰井志, 等. 攀西地区钒钛磁铁矿资源特点及选矿新技术[J]. 现代矿业, 2017,33(7):198−200. doi: 10.3969/j.issn.1674-6082.2017.07.060 [2] Wu Enhui, Li Jun, Hou Jing, et al. Experimental study on preparation of ilmenite concentrate by hydrochloric acid leaching of titanium middling ore at atmospheric pressure[J]. Multipurpose Utilization of Mineral Resources, 2019,12(3):48−51. (吴恩辉, 李军, 侯静, 等. 攀西地区钛中矿盐酸常压浸出制备钛精矿探索试验研究[J]. 矿产综合利用, 2019,12(3):48−51. doi: 10.3969/j.issn.1000-6532.2019.03.011 [3] Feng Hailiang, Che Xiaokui, Zheng Qi, et al. Study on beneficiation process of a refractory titanium middling ore[J]. Nonferrous Metals (Beneficiation), 2016,(3):27−32. (冯海亮, 车小奎, 郑其, 等. 某地难选钛中矿选矿工艺研究[J]. 有色金属(选矿部分), 2016,(3):27−32. [4] Zhang Yi, Huang Kun, Wang Shaona, et al. Magical sub molten salt[J]. Science and Technology Expo, 2017,(4):66−67. (张懿, 黄焜, 王少娜, 等. 神奇的亚熔盐[J]. 科技纵览, 2017,(4):66−67. doi: 10.3969/j.issn.2095-4409.2017.04.022 [5] Wang Shaona, Zheng Shili, Zhang Yi. Separation of aluminum and silicon in clean production process for potassium dichromate[J]. The Chinese Journal of Nonferrous Metals, 2007,17(7):1188−1194. (王少娜, 郑诗礼, 张懿. 铬盐清洁生产工艺中铝硅的脱除[J]. 中国有色金属学报, 2007,17(7):1188−1194. doi: 10.3321/j.issn:1004-0609.2007.07.028 [6] 张懿, 范秀英, 张微. 环保产业与高新技术[M]. 北京: 中国科学技术出版社, 2001: 134-135.Zhang Yi, Fan Xiuying, Zhang Wei. Environmental protection industry and high-tech[M]. Beijing: China Science and Technology Press, 2001: 134-135 [7] Liu Yumin, Qi Tao, Wang Lina, et al. Decomposition of ilmenite in KOH sub-molten salt[J]. The Chinese Journal of Process Engineering, 2009,(2):319−323. (刘玉民, 齐涛, 王丽娜, 等. KOH亚熔盐法分解钛铁矿[J]. 过程工程学报, 2009,(2):319−323. doi: 10.3321/j.issn:1009-606X.2009.02.020 [8] 陈敏, 肖轩, 张雪峰. 钛铁矿碳热还原动力学研究[C]//2015中国国际功能材料科技与产业高层论坛. 湘潭: 中国仪器仪表学会仪表功能材料分会, 2015: 82−82.Chen Min, Xiao Xuan, Zhang Xuefeng. Kinetics of carbothermic reduction of ilmenite[C]//2015 China (International) Functional Materials Technology and Industry Forum. Xiangtan: Instrument Functional Materials Society of China Instrument and Control Society, 2015: 82−85. [9] 马保中. 氢氧化钾体系亚熔盐法处理钛铁矿清洁工艺的应用基础研究[D]. 北京: 中国科学院过程工程研究所, 2008.Ma Baozhong. Basic research on the application of cleaning process for ilmenite treatment by potassium hydroxide system sub molten salt method[D]. Beijing: Institute of Process Engineering, Chinese Academy of Sciences, 2008. [10] Du Xinghong, Xie Bin, Lou Taiping. Research on solid reduction of vanadium-titanium magnetite[J]. Journal of Northeastern University(Natural Science Edition), 2012,33(5):685−688. (都兴红, 解斌, 娄太平. 钒钛磁铁矿固态还原的研究[J]. 东北大学学报(自然科学版), 2012,33(5):685−688. doi: 10.12068/j.issn.1005-3026.2012.05.019 -
点击查看大图
计量
- 文章访问数: 246
- HTML全文浏览量: 53
- PDF下载量: 39
- 被引次数: 0
