电增强活性炭纤维吸附去除水中Cr(Ⅵ)研究
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摘要
采用电吸附法对含Cr(Ⅵ)模拟废水进行处理,考察了电极电位、极板间距、极板面积、模拟废水初始Cr(Ⅵ)含量、废水pH等因素对吸附性能的影响,对电吸附过程进行了热力学和动力学拟合,并对电极进行了再生实验。结果表明,在电极电位为1.6 V、极板间距为0.6 cm、极板面积为100 cm2、模拟废水初始Cr(Ⅵ)的质量浓度为20 mg/L、废水pH为2的优化条件下,Cr(Ⅵ)的吸附去除率达到100%;其他因素不变,仅将p H调至2.5,Cr(Ⅵ)的吸附去除率为88.0%,较开路条件下提高了10.7个百分点;电吸附过程更符合Langmuir等温线模型和准2级动力学方程;对活性炭纤维电极进行4次循环电吸附、脱附实验后,其对Cr(Ⅵ)的吸附去除率仍保持在84%以上。
The electro-adsorption method was used to treat the simulated wastewater which contained Cr(Ⅵ). The effects of electrode potential, polar plate spacing, polar plate area, initial concentration of Cr(Ⅵ) in wastewater, wastewater pH and other factors on the adsorption properties were investigated.The thermodynamic and dynamic fitting of the electro-adsorption process and the regenerated experiment was carried out on the electrode. The results showed that when the electrode potential was 1.6 V, the spacing of the polar plate was 0.6 cm, the polar plate area was 100 cm2, the initial concentration of the simulated wastewater was 20 mg/L and the wastewater pH was 2, the adsorption removal rate of Cr(Ⅵ) reached 100%. The other factors remain unchanged, only pH was adjusted to 2.5, and the adsorption removal rate of Cr(Ⅵ) was 88.0%, which was 10.7% higher than that under the open circuit condition. The electro-adsorption process was fitted well with Langmuir adsorption isotherm model and was well described by the Quasi-second-order kinetics equation. After four cycles of electroadsorption/desorption experiments on activated carbon fiber electrode, the adsorption and removal rate of Cr(Ⅵ) remained above 84%.
The electro-adsorption method was used to treat the simulated wastewater which contained Cr(Ⅵ). The effects of electrode potential, polar plate spacing, polar plate area, initial concentration of Cr(Ⅵ) in wastewater, wastewater pH and other factors on the adsorption properties were investigated.The thermodynamic and dynamic fitting of the electro-adsorption process and the regenerated experiment was carried out on the electrode. The results showed that when the electrode potential was 1.6 V, the spacing of the polar plate was 0.6 cm, the polar plate area was 100 cm2, the initial concentration of the simulated wastewater was 20 mg/L and the wastewater pH was 2, the adsorption removal rate of Cr(Ⅵ) reached 100%. The other factors remain unchanged, only pH was adjusted to 2.5, and the adsorption removal rate of Cr(Ⅵ) was 88.0%, which was 10.7% higher than that under the open circuit condition. The electro-adsorption process was fitted well with Langmuir adsorption isotherm model and was well described by the Quasi-second-order kinetics equation. After four cycles of electroadsorption/desorption experiments on activated carbon fiber electrode, the adsorption and removal rate of Cr(Ⅵ) remained above 84%.
引文
[1]ALTUNDOGAN H S.Cr(VI)removal from aqueous solution by iron(III)hydroxided sugar beet pulp[J].Process Bio-chemisty,2005,40(4):1443-1452.
[2]BARRERA-DIAZ C E,LUGO-LUGO V,BILYEU B.A review of chemical,electrochemical and biological methods for aqueous Cr(VI)reduction[J].Journal of hazardous materials,2012,1(2):223-224.
[3]KIM Y J,CHOI J H.Enhanced desalination efficiency in capacitive deionization with an ion-selective membrane[J].Separation and Purification Technology,2010,71(1):70-75.
[4]ANDELMAN M.Ionic group derivitized nano porous carbon electrodes for capacitive deionization[J].Journal of Materials Science and Chemical Engineering,2014,2(3):16-22.
[5]张世春,刘海宁,王世栋,等.ZnCl2改性活性炭纤维电极对Rb+、Cs+的电吸附行为研究[J].无机盐工业,2017,49(8):26-30.
[6]尹晋,程方,苏润西,等.载铁改性活性炭纤维电极电吸附水中2,4,6-三氯酚[J].水处理技术,2018,44(7):49-53.
[7]崔爱玲,孙天男,赵朝成.电吸附法处理模拟含镍废水的研究[J].电镀与环保,2017,37(2):60-63.
[8]程健,王世平,蔡文姝,等.氯化锌处理活性炭电极及电容去离子研究[J].水处理技术,2015,41(11):34-38.
[9]李金鑫,孙文全,龙建,等.板式活性炭纤维电极电吸附除盐实验研究[J].水处理技术,2014,40(3):32-35.
[10]王甜甜,赵春玲,张倩茹,等.活性炭纤维电极电吸附去除乙酸[J].环境工程学报,2017,11(8):4789-4796.
[11]胡欣琪,杨硕,张旭,等.电增强载铝活性炭纤维吸附除氟的效果与影响因素[J].环境工程学报,2013.7(3):951-956.
[12]中国标准出版社第二编辑室.中国环境保护标准汇编:水质分析方法[M].北京:中国标准出版社,2001:11-14.
[13]黄巍.活性炭吸附法处理含铬电镀废水探讨[J].江苏环境科技,2001,14(3):18-19.
[14]污水综合排放标准:GB 8978-1996[S].
[15]孙奇娜,盛义平.载钛活性炭电吸附去除Cr(VI)的研究[J].环境工程学报,2007,1(2):59-63.
[2]BARRERA-DIAZ C E,LUGO-LUGO V,BILYEU B.A review of chemical,electrochemical and biological methods for aqueous Cr(VI)reduction[J].Journal of hazardous materials,2012,1(2):223-224.
[3]KIM Y J,CHOI J H.Enhanced desalination efficiency in capacitive deionization with an ion-selective membrane[J].Separation and Purification Technology,2010,71(1):70-75.
[4]ANDELMAN M.Ionic group derivitized nano porous carbon electrodes for capacitive deionization[J].Journal of Materials Science and Chemical Engineering,2014,2(3):16-22.
[5]张世春,刘海宁,王世栋,等.ZnCl2改性活性炭纤维电极对Rb+、Cs+的电吸附行为研究[J].无机盐工业,2017,49(8):26-30.
[6]尹晋,程方,苏润西,等.载铁改性活性炭纤维电极电吸附水中2,4,6-三氯酚[J].水处理技术,2018,44(7):49-53.
[7]崔爱玲,孙天男,赵朝成.电吸附法处理模拟含镍废水的研究[J].电镀与环保,2017,37(2):60-63.
[8]程健,王世平,蔡文姝,等.氯化锌处理活性炭电极及电容去离子研究[J].水处理技术,2015,41(11):34-38.
[9]李金鑫,孙文全,龙建,等.板式活性炭纤维电极电吸附除盐实验研究[J].水处理技术,2014,40(3):32-35.
[10]王甜甜,赵春玲,张倩茹,等.活性炭纤维电极电吸附去除乙酸[J].环境工程学报,2017,11(8):4789-4796.
[11]胡欣琪,杨硕,张旭,等.电增强载铝活性炭纤维吸附除氟的效果与影响因素[J].环境工程学报,2013.7(3):951-956.
[12]中国标准出版社第二编辑室.中国环境保护标准汇编:水质分析方法[M].北京:中国标准出版社,2001:11-14.
[13]黄巍.活性炭吸附法处理含铬电镀废水探讨[J].江苏环境科技,2001,14(3):18-19.
[14]污水综合排放标准:GB 8978-1996[S].
[15]孙奇娜,盛义平.载钛活性炭电吸附去除Cr(VI)的研究[J].环境工程学报,2007,1(2):59-63.
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