Structural optimization of three-dimensional electrocatalytic reactor for benzothiazole treatment

doi:10.16085/j.issn.1000-6613.2017.01.012

Abstract

Abstract: In this study,bipolar three-dimensional electrocatalytic reactor was applied to benzothiazole degradation and its structural parameters were investigated in order to improve the pollutant removal efficiency and reduce the energy consumption of electrochemistry reactor.Firstly,the electrode form was improved by comparing the degree of mineralization,mineralization current efficiency and energy consumption in the reaction system.Then response surface methodology based on Box-Behnken design was successfully applied to analyze the effect of the structural parameters and their interaction on benzothiazole degradation.The effects of three variables,impressed voltage,electrode distance and particle electrodes filling ratio upon the total organic carbon removal were evaluated and the prediction model of multivariate quadratic regression equation was acquired.The results showed that electrode distance played the most important role in total organic carbon removal,followed by impressed voltage and particle electrodes filling ratio,among which the interaction of electrode distance and the impresses voltage was remarkable.Optimized condition was obtained at 9.9V,4.2cm and 60% particle electrodes for the reactor.Under the optimal condition,98.18% of total organic carbon removal was achieved and the experimental value was in an accordance with the predicted value with 1.71% deviation.

Key words: electrochemistry, degradation, model, configuration parameters, benzothiazole, response surface methodology

摘要： 采用复极性三维电催化反应器降解苯并噻唑，通过考察三维电极反应器的结构参数，从而提高污染物处理效果的同时降低电催化反应体系的能耗。首先以反应体系的矿化率、矿化电流效率及能耗为评价指标，优化了反应器的电极型式。然后利用Design-Expert软件中的Box-Behnken响应曲面法，以外加电压、电极间距和粒子电极填充比例为自变量，TOC去除率为响应值，研究了各变量及其相互作用对TOC去除率的影响，并通过求解回归方程得到多元二次回归方程的预测模型。结果表明，电极间距和外加电压对TOC的影响最大，且电极间距和外加电压具有明显的交互性作用。预测分析最大TOC去除率为98.18%，相应的最优结构参数为：外加电压9.9V，电极间距4.2cm，粒子电极填充比60%，在最优条件下进行试验，实际值与预测值具有良好的一致性，偏差为1.71%。

关键词: 电化学, 降解, 模型, 结构参数, 苯并噻唑, 响应曲面分析法

CLC Number:

X703.1

DING Jie, SONG Zhao, SONG Dihui, LIU Xianshu. Structural optimization of three-dimensional electrocatalytic reactor for benzothiazole treatment[J]. Chemical Industry and Engineering Progree, 2017, 36(01): 91-99.

丁杰, 宋昭, 宋迪慧, 刘先树. 三维电催化处理苯并噻唑反应器结构优化[J]. 化工进展, 2017, 36(01): 91-99.

References

[1] LEWIS R J.Hawley's condensed chemical dictionary[M].12th ed.New York:Van Nostrand Reinhold,1993.
[2] WHITTAKER M H,GEBHART A M,MILLER T C,et al.Human health risk assessment of 2-mercaptobenzothiazole in drinking water[J].Toxicology and Industrial Health,2004,20(6/7/8/9/10):149-163.
[3] 刘瑞江,王华,张业旺,等.响应面分析法优化2-巯基苯并噻唑的合成[J].化工进展,2009,28(1):155-158. LIU R J,WANG H,ZHANG Y W,et al.Optimization of synthesis of 2-mercapto benzothiazole with response surface methodology[J].Chemical Industry and Engineering Process,2009,28(1):155-158.
[4] BELLAVIA V,NATANGELO M,FANELLI R,et al.Analysis of benzothiazole in Italian wines using headspace solid-phase microextraction and gas chromatography-mass spectrometry[J].Journal of Agricultural and Food Chemistry,2000,48(4):1239-1242.
[5] 赵培亮,王福,黄伟,等.一种结构新颖的苯并噻唑硫醚类化合物的合成及杀菌活性[J].有机化学,2010,30(10):1567-1573. ZHAO P L,WANG F,HUANG W,et al.Synthesis and fungicidal activities of novel thioethers containing benzothiazole moiety[J].Chinese Journal of Organic Chemistry,2010,30(10):1567-1573.
[6] CESPEDES R,LACORTE S,GINEBREDA A,et al.Chemical monitoring and occurrence of alkylphenols,alkylphenol ethoxylates,alcohol ethoxylates,phthalates and benzothiazoles in sewage treatment plants and receiving waters along the Ter River basin(Catalonia,N.E.Spain)[J].Analytical and Bioanalytical Chemistry,2006,385(6):992-1000.
[7] SEO K W,PARK M,KIM J G,et al.Effects of benzothiazole on the xenobiotic metabolizing enzymes and metabolism of acetaminophen[J].Journal of Applied Toxicology,2000,20(6):427-430.
[8] LIU Y S,YING G G.Simultaneous determination of benzotriazoles and ultraviolet filters in ground water,effluent and biosolid samples using gas chromatography tandem mass spectrometry[J].Journal of Chromatography A,2011,1218(31):5328-5335.
[9] LEERDAM J A V,HOGENBOOM A C,KOOI M M V D,et al.Determination of polar 1H-benzotriazoles and benzothiazoles in water by solid-phase extraction and liquid chromatography LTQ FT Orbitrap mass spectrometry[J].International Journal of Mass Spectrometry,2009,282(3):99-107.
[10] 刘春苗,丁杰,刘先树,等.电辅助微生物反应器降解苯并噻唑效能的研究[J].环境科学,2014,35(11):4192-4197. LIU C M,DING J,LIU X S,et al.Degradation of benzothiazole in electro-assisted microbial reactor[J].Environmental Science,2014,35(11):4192-4197.
[11] GINSBERG G,TOAL B,KURLAND T.Benzothiazole Toxicity assessment in support of synthetic turf field human health risk assessment[J].Toxicology and Environmental Health,Part A:Current Issues,2011,74(17):1175-1183.
[12] 洪艳平,宋宝安,吴平,等.苯并噻唑类农药生物活性研究进展[J].安徽农业科学,2005,33(7):1254-1257. HONG Y P,SONG A B,WU P,et al.Research advances in synthesis and biological activity of benzothiazole derivatives[J].Journal of Anhui Agricultural Sciences,2005,33(7):1254-1257.
[13] BESSE P,COMBOURIEU B,BOYSE G,et al.Long-Range ¹H-¹⁵N heteronuclear shift correlation at natural abundance:a tool to study benzothiazole biodegradation by two Rhodococcus strains[J].Applied and Environmental Microbiology,2001,67:1412-1417.
[14] KLOEPFER A,JEKEL M,REETSMA T.Occurrence,sources,and fate of benzothiazoles in municipal wastewater treatment plants[J].Environmental Science & Technology,2005,39(10):3792-3798.
[15] ZHANG C,JIANG Y,LI Y,et al.Three-dimensional electrochemical process for wastewater treatment:a general review[J].Chemical Engineering Journal,2013,228(14):455-467.
[16] 吴迪.羟基自由基在电催化氧化体系中的形成规律及其在废水处理中的应用研究[D].长春:吉林大学,2007. WU D.Study on the rules of hydroxyl radicals generation in electrochemical catalytic oxidation system and its application in wastewater treatment[D].Changchun:Jilin University,2007.
[17] 魏金枝,胡琴,张少平.不同复极性粒子电极的制备及电催化氧化效能[J].化工进展,2015,34(12):4254-4258. WEI J Z,HU Q,ZHANG S P.Preparation and electro-catalytic oxidation efficiency of different bipolar particle electrodes[J].Chemical Industry and Engineering Process,2015,34(12):4254-4258.
[18] 孔令国,王玲,薛建军.负载型三维粒子电极降解甲基橙模拟废水研究[J].中国环境科学,2010,30(4):516-521. KONG L G,WANG L,XUE J J.Process of methyl orange simulated wastewater degraded by supported bipolar three-dimension particle electrodes[J].China Environmental Science,2010,30(4):516-521.
[19] 王琳娜.EG新型粒子电极的研制及其应用的研究[D].深圳:中山大学,2009. WANG L N.Research on preparation and application of new EG particle electrode[D].Shenzhen:Sun Yat-sen University,2009.
[20] 周如彬,冉二燕,孙见蕊,等.新型多孔Ti/BDD薄膜电极电化学氧化降解低浓度茜素红[J].化工进展,2014,33(1):233-237. ZHOU R B,RAN E Y,SUN J R,et al.New porous Ti/BDD film electrode for electrochemical oxidation Alizarin Red at a low concentration[J].Chemical Industry and Engineering Process,2014,33(1):233-237.
[21] 丁飞.农药生产废水的电催化氧化预处理技术研究[D].合肥:合肥工业大学,2011. DING F.Research of pretreatment for pesticide wastewater by electro-catalytic oxidation[D].Hefei:Hefei Industry University,2011.
[22] 陈剑鹏.三维电极处理头孢类制药废水的应用研究[D].深圳:中山大学,2009. CHEN J P.Applied research of three-dimensional electrode system in treating pharmaceutical wastewater of cephalosporin[D].Shenzhen:Sun Yat-sen University,2009.
[23] 徐向宏,何明珠.试验设计与Design-Expert、SPSS应用[M].北京:科学出版社,2010. XU X H,HE M Z.Test design and Design-Expert、SPSS application[M].Beijing:Science Press,2010.
[24] MURUGANANTHAN M,YOSHIHARA S,RAKUMA T,et al.Mineralization of bispheol A(BPA)by anodic oxidation with boron-doped diamond(BDD)electrode[J].Hazardous Materials,2008,154:213-220.
[25] GUINEA E,ARIAS C,CABOT P L,et al.Mineralization of salicylic acid in acidic aqueous medium by electrochemical advanced oxidation processes using platinum and boron-doped diamond as anode and cathodically generated hydrogen peroxide[J].Water Research,2008,42:499-511.
[26] 魏金枝.电催化-生物氧化组合工艺构建及处理除草剂废水研究[D].哈尔滨:哈尔滨工业大学,2011. WEI J Z.Construction electrocatalytic-biological oxidation combined process herbicides wastewater[D].Harbin:Harbin Institute of Technology,2011.
[27] 毕强.电化学处理有机废水电极材料的制备与性能研究[D].西安:西安建筑科技大学,2014. BI Q.Investigation on preparation and properties of electrode materials for electrochemical oxidation of organic[D].Xi'an:Xi'an University of Architecture and Technology,2014.
[28] 李鹏.有机污染物电催化氧化有效电流表征及其阶段反应动力学[D].北京:中国矿业大学,2015. LI P.Characterization of the effective current and the phase-reaction kinetics mechanism for organic matters electro-catalytic oxidation[D].Beijing:China University of Mining and Technology,2015.
[29] 李弘.电催化氧化法用于制药废水预处理与深度处理的实验研究[D].哈尔滨:哈尔滨工业大学,2013. LI H.Research on the pretreatment and advanced treatment of pharmaceutical wastewater by electrocatalytic oxidation[D]. Harbin:Harbin Institute of Technology,2013.
[30] SILVEIRA J E,ZAZO J A,PLIEGO G,et al.Electrochemical oxidation of landfill leachate in a flow reactor:optimization using response surface methodology[J].Environmental Science & Pollution Research International,2014,22(8):5831-5841.
[31] 高爱舫,李爱国,张莹,等.基于响应曲面法的US/UV/Fenton联合处理抗生素制药废水优化[J].安全与环境学报,2014,14(3):180-183. GAO A H,LI A G,ZHANG Y,et al.Based on response surface method in the US/UV/Fenton combined antibiotic pharmaceutical wastewater treatment optimization[J].Journal of Safety and Environment,2014,14(3):180-183.
[32] 方俊涛.响应曲面方法中试验设计与模型估计的比较研究[D].天津:天津大学,2011. FANG J T.Comparison for experimental designs and modeling in response surface methodology[D].Tianjin:Tianjin University,2011.