Combination of iron-carbon micro-electrolysis and peracetic acid for the treatment of Rhodamine B containing wastewater

doi:10.11894/1005-829x.2018.38(12).093

Abstract

Abstract: The combined method of iron-carbon micro-electrolysis and peracetic acid has been used for the treat-ment of wastewater containing Rhodamine B(RhB). The influences of iron powder dosage,iron-carbon ratio,pH and peracetic acid dosage on the treatment effect have been investigated,and the optimal reaction conditions ascertained. The results show that the optimal conditions are as follows:the dosage of iron powder is 1.8 g/L,mass ratio of Fe and C=1:1,pH 4,at room temperature,and dosage of peracetic acid(PAA) is 0.3 mmol/L. The decolorization rate can reach 92.1% and the removing rate of TOC can reach 80.6%,after the Rhodamine B wastewater has been treated for 40 min. Compared with the single iron-carbon micro-electrolysis method,the removing rate is increased obviously.

Key words: iron-carbon micro-electrolysis, peracetic acid, Rhodamine B, dyeing wastewater

摘要： 采用铁碳微电解与过氧乙酸联用的方法处理含罗丹明B（RhB）废水。研究了铁粉投加量、铁碳比、pH、过氧乙酸投加量对处理效果的影响，并确定了最佳反应条件。结果表明，室温下，铁粉投加量为1.8 g/L、m（Fe）：m（C）为1：1，初始pH为4、过氧乙酸投加量为0.3 mmol/L为最优反应条件。处理RhB废水40 min后，脱色率可达到92.1%，TOC去除率达到80.6%。与单独的铁碳微电解法相比，去除率明显增加。

关键词: 铁碳微电解, 过氧乙酸, 罗丹明B, 染料废水

CLC Number:

X703

Sun Yicai, Sun Dedong, Wang Jiaying, He Qiang, Wang Guowen, Ma Chun, Dong Xiaoli. Combination of iron-carbon micro-electrolysis and peracetic acid for the treatment of Rhodamine B containing wastewater[J]. INDUSTRIAL WATER TREATMENT, 2018, 38(12): 93-96.

孙义才, 孙德栋, 王佳莹, 何强, 王国文, 马春, 董晓丽. 铁碳微电解与过氧乙酸联用处理罗丹明B废水[J]. 工业水处理, 2018, 38(12): 93-96.

/ / Recommend / Download Citations

URL: https://www.iwt.cn/EN/10.11894/1005-829x.2018.38(12).093

https://www.iwt.cn/EN/Y2018/V38/I12/93

References

[1] Hao O J,Kim H,Chiang P C. Decolorization of wastewater[J]. Critical Review in Environmental Science and Technology,2000,30(4):449-505.
[2] 周崟,李平,吴锦华,等. 活性艳蓝KN-R染料废水的电解氧化及其毒性消减[J]. 化工环保,2009,29(1):10-13.
[3] 张滕,王勇梅,彭昌盛,等. 染料废水的处理方法及研究进展[J]. 环保科技,2016,22(1):36-40.
[4] 乔鹏,张毅,黄天寅,等. 铁碳微电解预处理强酸高盐印染中间体废水[J]. 环境工程学报,2015,9(10):4717-4723.
[5] 方俊华,任立清,刘兰,等. 铁碳微电解-Fenton法预处理苯胺基乙腈生产废水的动力学研究[J]. 环境工程学报,2014,8(4):1397-1404.
[6] 黄萌萌,买文宁,李海松. 铁炭微电解-Fe²⁺/K₂S₂O₈降解甲基橙[J]. 环境工程学报,2014,8(3):935-940.
[7] 程婷,李海松,王敏,等. 铁碳微电解/H₂O₂耦合类Fenton法深度处理制药废水[J]. 环境工程学报,2015,9(4):1752-1756.
[8] Bokare A D,Choi W Y. Review of iron-free Fenton-like systems for activating H₂O₂ in advanced oxidation processes[J]. Journal of Hazardous Materials,2014,275:121-135.
[9] Koivunen J,Heinonen-Tanski H. Peracetic acid(PAA) disinfection of primary,secondary and tertiary treated municipal wastewaters[J]. Water Research,2005,39(18):4445-4453.
[10] Zhou Fengya,Lu Chao,Yao Yuyuan,et al. Activated carbon fibers as an effective metal-free catalyst for peracetic acid activation:implications for the removal of organic pollutants[J]. Chemical Engineering Journal,2015,281:953-960.
[11] 赵进英. 零价铁/过硫酸钠体系产生硫酸根自由基氧化降解氯酚的研究[D]. 大连:大连理工大学,2010.
[12] Dellerba A,Falsanisi D,Liberti L,et al. Disinfection by-products formation during wastewater disinfection with peracetic acid[J]. Desalination,2007,215(1/2/3):177-186.
[13] 张一鸣. 芬顿工艺的影响因素及其在难降解工业废水处理中的应用[J]. 资源节约与环保,2015(11):39-40.
[14] 冯雅丽,张茜,李浩然,等. 铁炭微电解预处理高浓度高盐制药废水[J]. 环境工程学报,2012,6(11):3855-3860.
[15] 李海松,闫阳,买文宁,等. 铁碳微电解-H₂O₂耦合联用的类Fenton法处理制浆造纸废水[J]. 环境化学学报,2013,32(12):2302-2306.
[16] Rokhina E V,Makarova K,Lahtinen M,et al. Ultrasound-assisted MnO₂ catalyzed homolysis of peracetic acid for phenol degradation:the assessment of process chemistry and kinetics[J]. Chemical Engineering Journal,2013,221:476-486.
[17] Rokhina E V,Makarova K,Golovina E,et al. Free radical reaction pathway,termochemistry of peracetic acid homolysis,and its application for phenol degradation:spectroscopic study and quantum chemistry calculations[J]. Environmental Science & Technology, 2010,44(17):6815-6821.

Please choose a citation manager

Content to export