工业废水中重金属（Cu2+、Cr6+、Ni2+）的电化学处理及铜还原建模

Electrochemical treatment of heavy metals (Cu2+, Cr6+, Ni2+) from industrial effluent and modeling of copper reduction.

作者信息

Hunsom M, Pruksathorn K, Damronglerd S, Vergnes H, Duverneuil P

机构信息

Department of Chemical Technology, Faculty of Science, Chulalongkorn University, Bangkok 10330, Thailand.

出版信息

Water Res. 2005 Feb;39(4):610-6. doi: 10.1016/j.watres.2004.10.011. Epub 2004 Dec 23.

DOI:10.1016/j.watres.2004.10.011

PMID:15707634

Abstract

An electrochemical technique was tested in a laboratory scale to treat heavy metals (Cu2+, Cr6+ and Ni2+) from plating industrial effluent. The experiments were performed in a membrane reactor having a capacity of 1 l. Stainless-steel sheets with surface area of 0.011 m2 and titanium coated with ruthenium oxide were used as cathode and anode, respectively. The electrolyte was circulated at a constant flow rate (0.42 l/min) and the pH was kept constant at 1. Applied current densities were 10 and 90 A/m2. According to the experiment, it was found that a membrane reactor with plane electrode was capable for treating plating wastewater with low energy consumption (42.30 kWh/kg metal) and low operating cost (5.43 US dollars/m3). More than 99% of metal reduction was achieved and the final concentrations of copper, chromium and nickel in treated water were 0.10-0.13, 0.19-0.20 and 0.05-0.13 ppm, respectively. The brightener had no effect on copper reduction whereas hexavalent chromium had strong effect. The kinetic of copper reduction in the presence of hexavalent chromium was modeled as a two-step process with respect to copper concentration.

摘要

在实验室规模下测试了一种电化学技术，用于处理电镀工业废水中的重金属（Cu2+、Cr6+和Ni2+）。实验在一个容量为1升的膜反应器中进行。分别使用表面积为0.011平方米的不锈钢板和涂有氧化钌的钛作为阴极和阳极。电解液以恒定流速（0.42升/分钟）循环，pH值保持在1不变。施加的电流密度为10和90 A/m2。根据实验发现，带有平板电极的膜反应器能够以低能耗（42.30千瓦时/千克金属）和低运行成本（5.43美元/立方米）处理电镀废水。实现了超过99%的金属还原，处理后水中铜、铬和镍的最终浓度分别为0.10 - 0.13、0.19 - 0.20和0.05 - 0.13 ppm。光亮剂对铜的还原没有影响，而六价铬有强烈影响。在六价铬存在的情况下，铜还原的动力学相对于铜浓度被模拟为一个两步过程。

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工业废水中重金属（Cu2+、Cr6+、Ni2+）的电化学处理及铜还原建模

Electrochemical treatment of heavy metals (Cu2+, Cr6+, Ni2+) from industrial effluent and modeling of copper reduction.

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