某铜冶炼企业冶炼炉渣配矿浮选试验研究
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摘要
采用某铜冶炼企业的选矿现场浮选工艺流程,开展对铜冶炼产生的闪速炉渣和转炉渣性质研究,并对不同配比条件下混合炉渣进行浮选试验,研究两种炉渣不同配比对铜浮选回收率的影响。结果表明:闪速炉渣铜品位为1.51%,转炉渣中铜品位为5.92%。闪速炉渣中铜主要存在形式为硫化铜,占总铜量的82.12%,金属铜和氧化铜以及其他含量相对较少;转炉渣中铜主要存在形式为硫化铜和金属铜,硫化铜含量占总铜量的54.73%,金属铜含量占总铜量的34.80%,氧化铜以及其他铜含量相对较少。闪速炉渣与转炉渣的配比为1:4时获得较好的浮选指标,混合炉渣浮选铜回收率为94.78%,尾矿品位为0.34%。
The characteristics of flash furnace slag and converter slag produced by copper smelting were studied using the flotation process in the field of a copper smelting enterprise, and the flotation test of mixed furnace slag was carried out under different mixing ratio. The results show that the copper grade of the slag of the flash furnace is 1.51% and that of the converter slag is 5.92%. The main form of copper in flash furnace slag is copper sulfide, accounting for 82.12 % of total copper content. The main forms of copper in converter slag are copper sulphide and copper metal. The main forms of copper in converter slag are copper sulphide and copper metal. The copper sulphide content accounts for 54.73%, and the metal copper content accounts for 34.80% of the total copper content. The copper oxide content and other copper content are relatively small. Good flotation indexes were obtained when the ratio of the flash slag to the converter slag was 1:4, the recovery of copper flotation from the mixed slag was 94.78%, and the tailing grade was 0.34%.
The characteristics of flash furnace slag and converter slag produced by copper smelting were studied using the flotation process in the field of a copper smelting enterprise, and the flotation test of mixed furnace slag was carried out under different mixing ratio. The results show that the copper grade of the slag of the flash furnace is 1.51% and that of the converter slag is 5.92%. The main form of copper in flash furnace slag is copper sulfide, accounting for 82.12 % of total copper content. The main forms of copper in converter slag are copper sulphide and copper metal. The main forms of copper in converter slag are copper sulphide and copper metal. The copper sulphide content accounts for 54.73%, and the metal copper content accounts for 34.80% of the total copper content. The copper oxide content and other copper content are relatively small. Good flotation indexes were obtained when the ratio of the flash slag to the converter slag was 1:4, the recovery of copper flotation from the mixed slag was 94.78%, and the tailing grade was 0.34%.
引文
[1]郑锡联,林鸿汉.某铜冶炼渣选铜尾矿的综合利用研究[J].矿业研究与开发, 2015(6):27-29.
[2]陈淑萍,伍赠玲,蓝碧波,等.火法炼铜技术综述[J].铜业工程, 2010(4):44-49.
[3]李博,王华,胡建杭,等.从铜渣中回收有价金属技术的研究进展[J].矿冶, 2009, 18(1):44-48.
[4]王鹏,高利坤,董方,等.铜冶炼渣浮选回收铜的研究现状[J].矿产综合利用, 2017(1):16-20.
[5]汪永红.铜炉造冷却工艺的研究与应用[J].有色冶金节能,2016,6(1):14-16
[6]杨银辉,冯国刚.国内大型渣选矿缓冷场设备配置及选型探讨[J].有色设备, 2012(3):9-13.
[7]陈名洁.国内铜炉渣选矿现状及工艺流程设计探讨[J].有色冶金节能, 2013, 29(2):46-49.
[8]吴健辉.某铜冶炼高品位混合铜渣选矿工艺研究[J].有色金属:选矿部分, 2015(1):67-71.
[2]陈淑萍,伍赠玲,蓝碧波,等.火法炼铜技术综述[J].铜业工程, 2010(4):44-49.
[3]李博,王华,胡建杭,等.从铜渣中回收有价金属技术的研究进展[J].矿冶, 2009, 18(1):44-48.
[4]王鹏,高利坤,董方,等.铜冶炼渣浮选回收铜的研究现状[J].矿产综合利用, 2017(1):16-20.
[5]汪永红.铜炉造冷却工艺的研究与应用[J].有色冶金节能,2016,6(1):14-16
[6]杨银辉,冯国刚.国内大型渣选矿缓冷场设备配置及选型探讨[J].有色设备, 2012(3):9-13.
[7]陈名洁.国内铜炉渣选矿现状及工艺流程设计探讨[J].有色冶金节能, 2013, 29(2):46-49.
[8]吴健辉.某铜冶炼高品位混合铜渣选矿工艺研究[J].有色金属:选矿部分, 2015(1):67-71.
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