欢迎登录材料期刊网

材料期刊网

高级检索

提出热活化脱硅技术处理某煤系硫铁矿浮选尾矿制备铝精矿,对制备氧化铝精矿的工艺制度及脱硅机理进行研究。结果表明:该尾矿适宜的热化学活化脱硅制度为活化焙烧温度1150℃、焙烧时间15~20 min、碱浸溶硅温度125~140℃、溶出时间30 min、NaOH浓度140 g/L。在此条件下,对Al 2 O 3和SiO 2含量分别为46.22%和28.33%(质量分数)的硫铁矿浮选尾矿,焙砂SiO 2溶出率达到71.91%,所得铝精矿中Al 2 O 3含量达69.29%,铝硅比5.59。XRD结果表明:硫铁矿尾矿中伊利-蒙脱石、高岭石和叶腊石等铝硅酸矿物在焙烧过程中活化分解生成无定形SiO 2和少量莫来石,与此同时,一水硬铝石转变成α-Al 2 O 3。在焙砂的碱浸过程中,无定形SiO 2溶解于NaOH溶液被脱除,而α-Al2O3和莫来石不能溶解,同时生成的水合铝硅酸钠(Na8Al6Si6O24(OH)2(H2O)2)将导致SiO2溶出率降低。焙烧过程中尾矿中的黄铁矿转化为赤铁矿、锐钛矿部分转化成金红石,在碱浸过程中它们均不会溶解而进入铝精矿中。

Aiming at preparing alumina concentrate from coal-derived pyrite flotation tailing, a desilication technique using thermochemical activation process followed by alkali leaching was proposed, and the suitable processing parameters and desilication mechanism were investigated. The results show that the optimal thermochemical activation processing parameters are as follows: roasting temperature 1 150 ℃, roasting time 15-20 min, alkali leaching temperature 125-140 ℃, leaching time 30 min and NaOH concentration 140 g/L. In this case, an alumina concentrate with 69.29%Al2O3 and mass ratio of alumina to silica (A/S) of 5.59 is obtained from a pyrite flotation tailing bearing 46.22%Al 2 O 3 and 28.33%SiO 2 (mass fraction), and the corresponding desilication ratio is 71.91%. XRD results show that aluminosilicates of the pyrite flotation tailing, including illite-montmorillonite, kaolinite and pyrophyllite, are decomposed into amorphous SiO 2 and small amount of mullite after thermochemical activation. Meanwhile, diaspore is transformed intoα-Al 2 O 3 . During the alkali leaching of activated materials, amorphous SiO 2 dissolves in the caustic soda, while mullite and α-Al2O3 do not dissolve, and the formation of sodium aluminosilicate hydrate (Na8Al6Si6O24(OH)2(H2O)2 ) during leaching leads to a decrease of desilication. Otherwise, rutile from thermal transformation of portion anatase, as well as hematite from oxidation, is not capable of being dissolved in alkali solution and shifted to alumina concentrate.

参考文献

[1] 叶巧明,刘建,张其春.川南煤系硫铁矿尾矿高岭土综合利用研究[J].矿产综合利用,2002(01):41-45.
[2] 刘敬勇,赵永久.硫铁矿资源开采利用过程中的环境污染问题及控制对策[J].中国矿业,2007(07):55-57.
[3] Acero P;Ayora C;Carrera J .Coupled thermal, hydraulic and geochemical evolution of pyritic tailings in unsaturated column experiments[J].Geochimica et Cosmochimica Acta: Journal of the Geochemical Society and the Meteoritical Society,2007(22):5325-5338.
[4] 刘蓉,刘媛媛.硫铁矿尾矿制造烧结墙体材料的可行性研究[J].砖瓦,2010(04):10-12.
[5] 张渊,洪秉信.川南硫铁矿尾矿的工艺性质与综合利用[J].矿产综合利用,2006(05):21-24.
[6] 李智,张其春,叶巧明.利用硫铁矿尾矿制备微晶玻璃[J].矿产综合利用,2007(01):42-45.
[7] 广东省建筑材料研究院 .一种硫铁矿选矿尾砂蒸压加气混凝土砌块及其生产工艺[P].中国,201010100862.3,2010-01-22.
[8] 厦门紫金矿冶技术有限公司 .一种从含硫铁尾矿中综合利用铁硫的方法[P].中国,200810072531.6,2008-12-29.
[9] 遵义天柱化工有限公司 .自硫铁矿尾矿中回收铝土矿的工艺方法[P].中国,201110125530.5,2011-05-16.
[10] 冯启明,王维清.川南高铁钛硫铁尾矿全组分综合利用研究[J].中国矿业,2004(06):74-76.
[11] Marina L. Kutsovskaya;Malcolm T. Hepworth;John R. McGaa .Recovery of Lime, Sulfur, and Iron from Gypsum and Pyrite Wastes[J].Industrial & Engineering Chemistry Research,1996(5):1736-1746.
[12] D. Tao;S. Chen;B. K. Parekh;M. T. Hepworth .An investigation of a thermochemical process for conversion of gypsum and pyrite wastes into useful products[J].Advances in environmental research,2001(3):277-284.
[13] 姜涛.中低品位铝土矿选矿预脱硅的新进展[J].矿冶工程,1999(02):3.
[14] 姜涛,李光辉,范晓慧,黄柱成,邱冠周.一水硬铝石型铝土矿焙烧碱浸脱硅新工艺(Ⅰ)[J].中国有色金属学报,2000(04):534.
[15] 李光辉,姜涛,范晓慧,黄柱成,邱冠周.一水硬铝石型铝土矿焙烧碱浸脱硅新工艺(Ⅲ)[J].中国有色金属学报,2000(06):899.
[16] LI Guang-hui;JIANG Tao;QIU Guan-zhou;FAN Xiao-hui;JIANG Hao .Technology and mechanism of desilication from roasted diasporic bauxite in atmosphere[J].Transactions of Nonferrous Metals Society of China,2002(1):132-136.
[17] LI Guang-hui;JIANG Tao;SUN Na;FAN Xiao-hui,QIU Guan-zhou.Desilication of bauxite ores bearing multi-aluminosilicate by thermochemical activation process[A].Seattle:TMS,2009:57-61.
[18] Tao Jiang;Guanghui Li;Guanzhou Qiu;Xiaohui Fan;Zhucheng Huang .Thermal activation and alkali dissolution of silicon from illite[J].Applied clay science,2008(1/4):81-89.
[19] 罗琳;刘永康;何伯泉 .一水硬铝石-高岭石型铝土矿焙烧脱硅热力学机理研究[J].有色金属,1999,51(01):25-30.
[20] CARIM A H;ROHRER G S;DANDO N R;TZENG S Y ROHRER C L PERROTTA A J .Conversion of diaspore to corundum:A newα-alumina transformation sequence[J].Journal of the American Ceramic Society,1997,80(10):2677-2680.
[21] 李光辉 .铝硅矿物的热行为及铝土矿石的热化学活化脱硅[D].中南大学,2002.
[22] JIANG Tao;LI Guang-hui;HUANG Zhu-cheng;FAN Xiao-hui,QIU Guan-zhou.Thermal behavior of kaolinite-diasporic bauxite and desilication from it by roasting-alkali leaching processing[A].Seattle:TMS,2002:89-94.
[23] Guanzhou Qiu;Tao Jiang;Guanghui Li .Activation and removal of silicon in kaolinite by thermochemical process[J].Scandinavian Journal of Metallurgy,2004(2):121-128.
[24] 魏存弟,马鸿文,杨殿范,张军,李益.煅烧煤系高岭石高温相变特征及火山灰活性研究[J].硅酸盐通报,2005(02):13-16.
[25] 张振禹,汪灵.叶蜡石加热相变特征的X射线粉晶衍射分析[J].硅酸盐学报,1998(05):618-623,629.
[26] 魏存弟,赵峰,马鸿文,李金洪,杨殿范,三国彰.叶蜡石加热相变及其演化特征[J].吉林大学学报(地球科学版),2005(02):150-154.
[27] 吴平霄,张惠芬,郭九皋,胡澄.蒙脱石热处理产物的微结构变化研究[J].地质科学,2000(02):185-196.
[28] Francesco Dellisanti;Vanna Minguzzi;Giovanni Valdre .Thermal and structural properties of Ca-rich Montmorillonite mechanically deformed by compaction and shear[J].Applied clay science,2006(3/4):282-289.
[29] Mukherjee S.;Borthakur PC. .Chemical demineralization/desulphurization of high sulphur coal using sodium hydroxide and acid solutions[J].Fuel,2001(14):2037-2040.
上一张 下一张
上一张 下一张
计量
  • 下载量()
  • 访问量()
文章评分
  • 您的评分:
  • 1
    0%
  • 2
    0%
  • 3
    0%
  • 4
    0%
  • 5
    0%