阴极材料及结构对电化学法水处理性能的影响
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摘要
针对工业循环冷却水的结垢问题,实验研究了不同阴极(钛板、铜板和钛网)对电化学处理后水样的总溶解性固体和电导率的影响,得出阴极材料及结构对电化学法水处理性能的影响规律。结果表明,阴极为钛板时,最佳电解电压为25 V;阴极为铜板时,水中成垢离子的去除率与电解电压呈正比;阴极为钛网时,电解电压对电化学法水处理性能影响较小;钛板作阴极时的处理性能优于铜板;阴极为钛板时的处理性能优于钛网。
In order to solve the fouling problem of industrial circulating cooling water, the effects of different cathodes(titanium plate, copper plate and titanium mesh) on the total dissolved solids and conductivity of the water samples after electrochemical treatment were studied experimentally. The influence of cathode materials and structures on the electrochemical treatment performance was obtained. The results showed that when the cathode was a titanium plate,the best electrolytic voltage was 25 V. When the cathode was a copper plate, the removal rate of scale-forming ions in the water was proportional to the electrolysis voltage. When the cathode was a titanium mesh, the electrolysis voltage had less effect on the electrochemical treatment of water. The treatment performance of titanium plate as cathode was better than that of copper plate as the cathode, the treatment performance of titanium plate as cathode was better than that of titanium mesh as the cathode.
In order to solve the fouling problem of industrial circulating cooling water, the effects of different cathodes(titanium plate, copper plate and titanium mesh) on the total dissolved solids and conductivity of the water samples after electrochemical treatment were studied experimentally. The influence of cathode materials and structures on the electrochemical treatment performance was obtained. The results showed that when the cathode was a titanium plate,the best electrolytic voltage was 25 V. When the cathode was a copper plate, the removal rate of scale-forming ions in the water was proportional to the electrolysis voltage. When the cathode was a titanium mesh, the electrolysis voltage had less effect on the electrochemical treatment of water. The treatment performance of titanium plate as cathode was better than that of copper plate as the cathode, the treatment performance of titanium plate as cathode was better than that of titanium mesh as the cathode.
引文
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[2]曲秀丽.电化学法循环水的除垢研究[D].大连:大连海事大学,2016.
[3] Hasson D,Sidorenko G,Semiat R. Calcium carbonate hardness removal by a novel electrochemical seeds system[J]. Desalination,2010,263(1/2/3):285-289.
[4] Hasson D,Lumelsky V,Greenberg G,et al. Development of the electrochemical scale removal technique for desalination applications[J].Desalination,2008,230(1/2/3):329-342.
[5] Gabrielli C,Maurin G,Francy-Chausson H,et al. Electrochemical water softening:principle and application[J]. Desalination,2006,201(1/2/3):150-163.
[6]全贞花,王春明,李兵,等.低压静电用于循环冷却水阻垢的实验研究[J].净水技术,2007,26(6):30-33.
[7]刘运洁,王春明,全贞花,等.低压电子水处理方法的阻垢特性[J].工程热物理学报,2009,30(1):153-155.
[8]李森,王海峰,郭斌.循环水垢的A电源电解法去除工艺[J].广州化工,2013,41(4):104-106.
[9]李森,王海峰.电化学法处理冷却循环水技术的应用[J].化工进展,2013,32(10):2514-2517.
[10] Ji Q H,Yu D W,Zhang G,et al. Microfluidic flow through polyaniline supported by lamellar-structured graphene for mass-transferenhanced electrocatalytic reduction of hexavalent chromium[J]. Environmental Science&Technology,2015,49(22):13534-13541.
[11] Huo Z Y,Xie X,Yu T,et al. Nanowire-modified three-dimensional electrode enabling low-voltage electroporation for water disinfection[J]. Environmental Science&Technology,2016,50(14):7641-7649.
[12] Liu Y B,Dustin Lee J H,Xia Q,et al. A graphene-based electrochemical filter for water purification[J]. Journal of Materials Chemistry A,2014,2(2):16554-16562.
[13]李晶蕊,李杨.电化学法处理污水厂反渗透装置浓水试验研究[J].工业水处理,2017,37(12):72-75.
[14]郭晨.电化学氧化法在工业废水处理中的应用研究[J].化工管理,2017(26):251.
[15]张安龙,李凯,王飞朋,等.板式电化学水处理装置在循环水处理中的应用[J].武钢技术,2011,49(2):36-38.
[16]颜会全,李静萍.电化学水处理技术发展综述[J].化工时刊,2016,30(6):42-45.
[17]凌幸福,张平根.工业循环冷却水电化学水处理器的设计与调试[J].云南冶金,2017,46(1):81-85.
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