机械力活化某铜尾矿处理模拟含铜废水试验
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摘要
为解决铜离子废水的污染问题,以湖北某碳酸盐型铜尾矿为原料,通过搅拌磨机械活化方式进行了以废治废可行性研究,并对机械活化可能引发尾矿泥化的问题和可能释放尾矿中金属离子的问题进行了论证,最后通过XRD技术分析了铜离子的去除机理。结果表明:①在机械活化作用下,湖北某碳酸盐型铜尾矿可以有效去除模拟废水中的铜离子。当尾矿添加量与铜离子(由硝酸铜提供)的质量比为18∶1、模拟废水铜离子初始浓度为100 mg/L、反应时间为60 min情况下,铜离子去除率达99.83%。该铜尾矿对硫酸铜型含铜模拟废水的处理效果明显好于硝酸铜型模拟废水。②由于机械活化与实际磨矿过程的强度存在明显差别,因此,机械活化没有造成铜尾矿粒度的明显变化;同时活化后的矿浆中金属离子的浓度非常低,因此,机械活化也不存在释放金属离子的问题。③铜尾矿处理模拟含铜废水过程中,起主要作用的是方解石,机械活化加速了方解石的溶解与电离,其产生的碳酸根离子发生水解进而引起矿浆pH值的升高,最终使铜离子发生沉淀反应。对于硫酸铜型模拟废水而言,生成的沉淀主要为一水铜蓝矾;对于硝酸铜型模拟废水而言,生成的则是无定型状态的铜矿物。
In order to solve the pollution problem of copper-containing wastewater,a kind of carbonate copper tailing in Hubei Province was used as raw material to study on the feasibility of utilizing waste for controlling pollution by means of mechanically-activated copper tailings with stirring mill. Thepossibility of sliming tailings and releasing metal ions by mechanical activation was demonstrated. Finally,the removal mechanism of copper ions was analyzed by XRD. The results showed that:①Under the mechanical activation,the carbonate copper tailings in Hubei province effectively removed copper ions from simulated wastewater. Under conditions of the mass ratio of tailings to copper ions(provided by copper nitrate)18∶1,the initial copper ions concentration of simulated wastewater 100 mg/L,and the reaction time for 60 min,the copper ions removal rate was 99.83%. The treatment effect of this copper tailing on the simulated copper sulfate wastewater was obviously better than that on the simulated copper nitrate wastewater.②Since the mechanically-activated intensity differed from the actual grinding process,the particle size of the copper tailings didn't decrease significantly. Meanwhile,the concentration of metal ions in the activated pulp was low,indicating that the mechanical activation didn't release heavy metal ions. ③The calcite played a major role in the process of wastewater treatment. Mechanical activation accelerated the dissolution and ionization of calcite,and the hydrolysis of carbonate ions caused an increase in the pH of the slurry,which ultimately caused precipitation of copper ions. For the copper sulfate type simulated wastewater,the precipitate generated was mainly posnjakite(Cu4(SO4)(OH)6·H2 O).For the copper nitrate type simulated wastewater,the precipitate was mainly composed of amorphous copper minerals.
In order to solve the pollution problem of copper-containing wastewater,a kind of carbonate copper tailing in Hubei Province was used as raw material to study on the feasibility of utilizing waste for controlling pollution by means of mechanically-activated copper tailings with stirring mill. Thepossibility of sliming tailings and releasing metal ions by mechanical activation was demonstrated. Finally,the removal mechanism of copper ions was analyzed by XRD. The results showed that:①Under the mechanical activation,the carbonate copper tailings in Hubei province effectively removed copper ions from simulated wastewater. Under conditions of the mass ratio of tailings to copper ions(provided by copper nitrate)18∶1,the initial copper ions concentration of simulated wastewater 100 mg/L,and the reaction time for 60 min,the copper ions removal rate was 99.83%. The treatment effect of this copper tailing on the simulated copper sulfate wastewater was obviously better than that on the simulated copper nitrate wastewater.②Since the mechanically-activated intensity differed from the actual grinding process,the particle size of the copper tailings didn't decrease significantly. Meanwhile,the concentration of metal ions in the activated pulp was low,indicating that the mechanical activation didn't release heavy metal ions. ③The calcite played a major role in the process of wastewater treatment. Mechanical activation accelerated the dissolution and ionization of calcite,and the hydrolysis of carbonate ions caused an increase in the pH of the slurry,which ultimately caused precipitation of copper ions. For the copper sulfate type simulated wastewater,the precipitate generated was mainly posnjakite(Cu4(SO4)(OH)6·H2 O).For the copper nitrate type simulated wastewater,the precipitate was mainly composed of amorphous copper minerals.
引文
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[11]朱建阳,靳强.纳滤技术处理含铜废水的研究[J].水处理技术,2017(9):81-83.Zhu Jianyang,Jin Qiang.Study on copper-containing wastewater treatment by nanofiltration[J].Technology of Water Treatment,2017(9):81-83.
[12]熊英禹,付忠田,黄戊生.化学沉淀法处理模拟含铜废水的研究[J].环境保护科学,2014(2):35-38.XiongYingyu,Fu Zhongtian,Huang Wusheng.Research on treatment of simulated wastewater containing copper by chemical sedimentation method[J].Environmental Protection Science,2014(2):35-38.
[13]Hu H,Li X,Huang P,et al.Efficient removal of copper from wastewater by using mechanically activated calcium carbonate[J].Journal of Environmental Management,2017,203:1-7.
[14]李学伟.机械力作用下方解石与重金属离子反应的机理及应用研究[D].武汉:武汉理工大学,2017.Li Xuewei.Study on the Mechanism and Application of the Reaction between Calcite and Heavy Metal Ions during the Mechanical Activation[D].Wuhan:Wuhan University of Technology,2017.
[15]Candal R J,Regazzoni A E,Blesa M A.Precipitation of copper(II)hydrous oxides and copper(II)basic salts[J].Journal of Materials Chemistry,1992(6):657.
[16]Zeppenfeld K.Prevention of CaCO3scale formation by trace amounts of copper(II)in comparison to zinc(II)[J].Desalination,2010(1/2/3):60-65.
[2]杜立宇,梁成华,刘桂琴.红透山铜尾矿重金属分布及其对土壤重金属污染的影响[J].土壤通报,2008(4):938-941.Du Liyu,Liang Chenghua,Liu Guiqin.Thedistribution ccharacteristics of heavy metals in Cu mine tailing and effect of heavy metals on pollution of soils in the areas of HongtouMountians[J].Chinese Journal of Soil Science,2008(4):938-941.
[3]袁永强,刘丛强.广西某地金属冶炼废水外溢对农田土壤的污染特征[J].环境科学,2011(11):3312-3317.Yuan Yongqiang,Liu Congqiang.Pollution of agricultural soils by a wastewater outflow from a metal smelter in guangxizhuang autonomous region[J].Environmental Science,2011(11):3312-3317.
[4]Sun L,Hu Y,Sun W,et al.Selective recovery of mushistonite from gravity tailings of copper tin minerals in tajikistan[J].Minerals,2017(12):242.
[5]Xu W,Cao P,Tian M.Strength development and microstructure evolution of cemented tailings backfill containing different binder types and contents[J].Minerals,2018(4):167.
[6]Fellet G,Marchiol L,Delle V G,et al.Application of biochar on mine tailings:effects and perspectives for land reclamation[J].Chemosphere,2011(9):1262-1267.
[7]Wang W,Zhao Y,Liu H,et al.Fabrication and mechanism of cement-based waterproof material using silicate tailings from reverse flotation[J].Powder Technology,2017,315:422-429.
[8]成四喜,黄铮铮,雷筱娱,等.离子交换树脂法处理含铜废水的研究进展[J].化工环保,2014(3):230-234.Cheng Sixi,Huang Zhengzheng,Lei Xiaoyu,et al.Research progresses in treatment of copper-containing wastewater by ion exchange resin process[J].Environmental Protection of Chemical Industry,2014(3):230-234.
[9]石万里,赵泽华,叶飞,等.酸改性凹凸棒土处理含铜废水的试验研究[J].环境工程技术学报,2018(2):169-175.Shi Wanli,Zhao Zehua,Ye Fei,et al.Experimental study on adsorption of copper containing wastewater by modified attapulgite[J].Journal of Environmental Engineering Technology,2018(2):169-175.
[10]梁敏,陶虎春,李绍峰,等.剩余污泥为底物的微生物燃料电池处理含铜废水[J].环境科学,2011(1):179-185.Liang Min,Tao Huchun,Li Shaofeng,et al.Treatment of Cu2+-containing wastewater by microbial fuel cell with excess sludge as anodic substrate[J].Environmental Science,2011(1):179-185.
[11]朱建阳,靳强.纳滤技术处理含铜废水的研究[J].水处理技术,2017(9):81-83.Zhu Jianyang,Jin Qiang.Study on copper-containing wastewater treatment by nanofiltration[J].Technology of Water Treatment,2017(9):81-83.
[12]熊英禹,付忠田,黄戊生.化学沉淀法处理模拟含铜废水的研究[J].环境保护科学,2014(2):35-38.XiongYingyu,Fu Zhongtian,Huang Wusheng.Research on treatment of simulated wastewater containing copper by chemical sedimentation method[J].Environmental Protection Science,2014(2):35-38.
[13]Hu H,Li X,Huang P,et al.Efficient removal of copper from wastewater by using mechanically activated calcium carbonate[J].Journal of Environmental Management,2017,203:1-7.
[14]李学伟.机械力作用下方解石与重金属离子反应的机理及应用研究[D].武汉:武汉理工大学,2017.Li Xuewei.Study on the Mechanism and Application of the Reaction between Calcite and Heavy Metal Ions during the Mechanical Activation[D].Wuhan:Wuhan University of Technology,2017.
[15]Candal R J,Regazzoni A E,Blesa M A.Precipitation of copper(II)hydrous oxides and copper(II)basic salts[J].Journal of Materials Chemistry,1992(6):657.
[16]Zeppenfeld K.Prevention of CaCO3scale formation by trace amounts of copper(II)in comparison to zinc(II)[J].Desalination,2010(1/2/3):60-65.
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