Öz
In this study, microelectrolysis (ME) method was used for the treatment of the Reactive Black 5, which is a type of azo dye from the model wastewater. ME reactor was filled by iron chip-granular activated carbon (Fe/C) or carbon steel-granular activated carbon (CS/C) mixtures. In microelectrolysis experiments the effects of operational parameters such as initial RB5 concentration (50-150 mg/L), the pumping speed of the solution (30-60 rpm), initial pH value of the solution , solution conductivity (3-9 mS/cm) and temperature (25-45 oC) were examined. Under the conditions of an initial pH of 3, RB5 concentration of 50 mg/L, pumping speed of 30 rpm, and conductivity of 3 mS/cm, the dye removal efficiencies of 97.5% for Fe/C filling and 96.6% for CS/C filling were achieved
Anahtar Kelimeler
Microelectrolysis Reactive Black 5 Dye Iron cips Carbon steel Dye stuff removal
Kaynakça
- Chen Z., Sun X. , Liu Z., Huang X. and Jia R. (2013). A Novel Application of Micro Electrolysis-Fenton Process on High-strength Acidic Dye Wastewater, Nature Environment and Pollution Technology 12( 2) 255-260.
- Cheng, H., Xu, W., Liu, J., Wang, H., He, Y. and Chen, G. (2007). Pretreatment of Wastewater from Triazine Manufacturing by Coagulation, Electrolysis, and Internal Microelectrolysis, Journal Hazardous Materials 146, 385–392.
- Cheng, L., Bi X. and Liu, C. (2010). Pretreatment of Straw Pulp and Papermaking Middle Stage Wastewater by Iron-carbon Microelectrolysis, IEEE.
- Fan, L., Ni, J., Wu, Y. and Zhang,Y., (2009). Treatment of Bromoamine Acid Wastewater using Combined Process of Micro-Electrolysis and Biological Aerobic Filter, Journal Hazardous Materials, 162, 1204-1210.
- Guo, X., Cai, Y. Wei, Z. H.,Hou Yang, X. and Wang, Z. (2013). Treatment of Di Azo Dye C.I. Reactive Black 5 in Aqueous Solution by Combined Process of Interior Micro Electrolysis and Ozonation, Water Science & Technology, 67 1880-1885.
- http1://www.sigmaaldrich.com/catalog/product/sial/306452?lang=en®ion=TR
- Huang, D., Yue, Q., Fu, K., Zhang, B., Gao, B., Li, Q. and Wang, Y. (2014). Application for Acrylonitrile Wastewater Treatment by New Micro-electrolysis Ceramic Fillers, Desalination and Water Treatment, 1-9.
- Kuşvuran E., Irmak S., Yavuz H.I., Samil A. and Erbatur O. (2005). Comparison of the Treatment Methods Efficiency for Decolorization and Mineralization of Reactive Black 5 azo dye, J. Hazard. Mater., 119, 109–116.
- Lai, B., Zhou, Y., Yang, P., Yang, J. and Wang, J. (2013). Degradation of 3,3-iminobis-Propanenitrile in Aqueous Solution by Fe0 /GAC Micro-electrolysis System, Chemosphere, 90 1470-1477.
- Lan, S.,Ju, F. and Wu, X. (2012). Treatment of Wastewater Containing EDTA-Cu(II) using the Combined Process of Interior Microelectrolysis and Fenton Oxidation–coagulation, Separation and Purification Technology, 89, 117–124.
- Li, M., Zou, D., Zou, H. and Fan D. (2011) Degradation of Nitrobenzene in Simulated Wastewater by Iron-Carbon Micro-electrolysis Packing, Environmental Technology, 33 (15-16) 1761-6.
- Pazos, M., Sanroman, A.M. and Rivera M. (2011). Development of an Electrochemical Cell for the Removal of Reactive Black 5, Desalination, 274, 39-43.
- Qin, G. and Gong, D. (2014). Pretreatment of Petroleum Refinery Wastewater by Microwave-Enhanced Fe0/GAC Micro-electrolysis, Desalination and Water Treatment, 52, 2512–2518.
- Qin, L., Zhang, G., Meng, Q., Xu, L. and Lv, B. (2012). Enhanced MBR by Internal Micro-electrolysis for Degradation of Anthraquinone Dye Wastewater, Chemical Engineering Journal, 210, 575– 584.
- Ren, Y., Wu, Z., Ondruschka, B., Braeutigam, P., Franke, M., Nehring, H. and Hampel, U. (2011) Oxidation of Phenol by Microbubble-Assisted Microelectrolysis, Chemical Engineering Technology, 34, 5, 699–706.
- Şengil A. and Özacar M. (2009). The Decolorization of C.I. Reactive Black 5 in Aqueous Solution by Electrocoagulation using Sacrificial Iron Electrodes, Journal of Hazardous Materials, 161, 1369– 1376.
- Tsang, D. C. W., Hu, J., Liu, M. Y., Zhang, W., Lai, K. C. K. and Lo, I. M. C. (2007) Activated Carbon Produced from Waste Wood Pallets: Adsorption of Three Classes of Dyes, Water, Air, and Soil Pollution, 184 (1-4) 141-155.
- Wen-wu, L.,Xue-yan, T., Xiu-ping, W., Feng-qun, W. and Wen, L. (2012), Pretreatment of Coking Wastewater by Acid Out, Micro-electrolysis Process with in Situ Electrochemical Peroxidation Reaction, Chemical Engineering Journal, 200, 720–728.
- Wu, Q., Hua, T. and Zhou, Q. (2011). Treatment and Remediation of a Wastewater Lagoon using Microelectrolysis and Modified DAT/IAT Methods, Journal of Environmental Sciences, 23(3) 388–395.
- Yang, H., Xue, J.-jun , Wang, L., Wang, Z.-wei, Ling, S.-sheng, Kong, L.-guo and Chen, Y.-lan. (2012). Research on the Treatment of Phosphoric Wastewater by Ultrasound-assisted Microelectrolysis Method, Environmental Technology, 33 (2) 221–227.
- Yang, X. (2009), Interior Micro Electrolysis Oxidation of Polyester Wastewater and its Treatment Technology, Journal of Hazardous Materials, 169, 480–485.
- Yang, X., Xue, Y. and Wang, W. (2009) Mechanism, Kinetics and Application Studies on Enhanced Activated sludge by Interior Microelectrolysis, Bioresource Technology, 100, 649–653.
- Yavuz Y. and Shahbazi R. (2012) Anodic Oxidation of Reactive Black 5 Dye using Boron Doped Diamond Anodes in a Bipolar Trickle Tower Reactor, Separation and Purification Technology 85 130–136.
- Ying, D., Peng J., Xu X., Li K., Wang Y. and Ji, J. (2012). Treatment of Mature Landfill Leachate by Internal Micro-electrolysis Integrated with Coagulation: A Comparative Study on a Novel Sequencing Batch Reactor Based on Zero Valent Iron, Journal Hazardous Materials 229, 426- 433.
- Zhou, J., Gao, J., Liu, Y., Xiao, S., Zhang, R. and Zhang, Z. (2013). Contaminant Removal Performances on Domestic Sewage using Modified Anoxic/Anaerobic/Oxic Process and Micro-electrolysis, Environmental Technology, 34 (19) 2773–2779.
- Zhou, Z., Qiao, W., Lin, Y., Shen, X., Hu, D., Zhang, J., Jiang, L.M. and Wang, L. (2014). Phosphonate Removal from Discharged Circulating Cooling Water using Iron-Carbon Micro-Electrolysis, Water Science Technology 70(3), 524-532.
Öz
Bu çalışmada bir azo boya olan Reaktif Black 5 (RB5) içeren model atık suyun arıtımı için mikroelektroliz (ME) yöntemi kullanıldı. Demir talaşı-granül aktif karbon (Fe/C) ve karbon çeliği-granül aktif karbon (KÇ/C) karışımları ME reaktörü dolgusu olarak kullanıldı. Mikroelektroliz deneylerinde boya derişiminin (50-150 mg/L), çözelti pompalama hızının (30-60 rpm), çözelti pH değerinin (2-4), çözelti iletkenliğinin (3-9 mS/cm) ve sıcaklığın (25-45 0C) boya giderim yüzdesine olan etkileri incelendi. Her iki dolgu için de çalışılan parametrelerin en uygun değerleri pH=3, 50 mg/L boya derişimi, 30 dev/dk pompalama hızı ve 3 mS/cm iletkenlik olarak belirlendi. Bu koşullarda (Fe/C) dolgu ile %97,5; (KÇ/C) dolgu ile %96,6’ lık RB% giderimine ulaşıldı.
Anahtar Kelimeler
: Mikroelektroliz Reaktif Black 5 Boyar madde Demir talaşı Karbon çeliği Boyar madde giderimi
Kaynakça
- Chen Z., Sun X. , Liu Z., Huang X. and Jia R. (2013). A Novel Application of Micro Electrolysis-Fenton Process on High-strength Acidic Dye Wastewater, Nature Environment and Pollution Technology 12( 2) 255-260.
- Cheng, H., Xu, W., Liu, J., Wang, H., He, Y. and Chen, G. (2007). Pretreatment of Wastewater from Triazine Manufacturing by Coagulation, Electrolysis, and Internal Microelectrolysis, Journal Hazardous Materials 146, 385–392.
- Cheng, L., Bi X. and Liu, C. (2010). Pretreatment of Straw Pulp and Papermaking Middle Stage Wastewater by Iron-carbon Microelectrolysis, IEEE.
- Fan, L., Ni, J., Wu, Y. and Zhang,Y., (2009). Treatment of Bromoamine Acid Wastewater using Combined Process of Micro-Electrolysis and Biological Aerobic Filter, Journal Hazardous Materials, 162, 1204-1210.
- Guo, X., Cai, Y. Wei, Z. H.,Hou Yang, X. and Wang, Z. (2013). Treatment of Di Azo Dye C.I. Reactive Black 5 in Aqueous Solution by Combined Process of Interior Micro Electrolysis and Ozonation, Water Science & Technology, 67 1880-1885.
- http1://www.sigmaaldrich.com/catalog/product/sial/306452?lang=en®ion=TR
- Huang, D., Yue, Q., Fu, K., Zhang, B., Gao, B., Li, Q. and Wang, Y. (2014). Application for Acrylonitrile Wastewater Treatment by New Micro-electrolysis Ceramic Fillers, Desalination and Water Treatment, 1-9.
- Kuşvuran E., Irmak S., Yavuz H.I., Samil A. and Erbatur O. (2005). Comparison of the Treatment Methods Efficiency for Decolorization and Mineralization of Reactive Black 5 azo dye, J. Hazard. Mater., 119, 109–116.
- Lai, B., Zhou, Y., Yang, P., Yang, J. and Wang, J. (2013). Degradation of 3,3-iminobis-Propanenitrile in Aqueous Solution by Fe0 /GAC Micro-electrolysis System, Chemosphere, 90 1470-1477.
- Lan, S.,Ju, F. and Wu, X. (2012). Treatment of Wastewater Containing EDTA-Cu(II) using the Combined Process of Interior Microelectrolysis and Fenton Oxidation–coagulation, Separation and Purification Technology, 89, 117–124.
- Li, M., Zou, D., Zou, H. and Fan D. (2011) Degradation of Nitrobenzene in Simulated Wastewater by Iron-Carbon Micro-electrolysis Packing, Environmental Technology, 33 (15-16) 1761-6.
- Pazos, M., Sanroman, A.M. and Rivera M. (2011). Development of an Electrochemical Cell for the Removal of Reactive Black 5, Desalination, 274, 39-43.
- Qin, G. and Gong, D. (2014). Pretreatment of Petroleum Refinery Wastewater by Microwave-Enhanced Fe0/GAC Micro-electrolysis, Desalination and Water Treatment, 52, 2512–2518.
- Qin, L., Zhang, G., Meng, Q., Xu, L. and Lv, B. (2012). Enhanced MBR by Internal Micro-electrolysis for Degradation of Anthraquinone Dye Wastewater, Chemical Engineering Journal, 210, 575– 584.
- Ren, Y., Wu, Z., Ondruschka, B., Braeutigam, P., Franke, M., Nehring, H. and Hampel, U. (2011) Oxidation of Phenol by Microbubble-Assisted Microelectrolysis, Chemical Engineering Technology, 34, 5, 699–706.
- Şengil A. and Özacar M. (2009). The Decolorization of C.I. Reactive Black 5 in Aqueous Solution by Electrocoagulation using Sacrificial Iron Electrodes, Journal of Hazardous Materials, 161, 1369– 1376.
- Tsang, D. C. W., Hu, J., Liu, M. Y., Zhang, W., Lai, K. C. K. and Lo, I. M. C. (2007) Activated Carbon Produced from Waste Wood Pallets: Adsorption of Three Classes of Dyes, Water, Air, and Soil Pollution, 184 (1-4) 141-155.
- Wen-wu, L.,Xue-yan, T., Xiu-ping, W., Feng-qun, W. and Wen, L. (2012), Pretreatment of Coking Wastewater by Acid Out, Micro-electrolysis Process with in Situ Electrochemical Peroxidation Reaction, Chemical Engineering Journal, 200, 720–728.
- Wu, Q., Hua, T. and Zhou, Q. (2011). Treatment and Remediation of a Wastewater Lagoon using Microelectrolysis and Modified DAT/IAT Methods, Journal of Environmental Sciences, 23(3) 388–395.
- Yang, H., Xue, J.-jun , Wang, L., Wang, Z.-wei, Ling, S.-sheng, Kong, L.-guo and Chen, Y.-lan. (2012). Research on the Treatment of Phosphoric Wastewater by Ultrasound-assisted Microelectrolysis Method, Environmental Technology, 33 (2) 221–227.
- Yang, X. (2009), Interior Micro Electrolysis Oxidation of Polyester Wastewater and its Treatment Technology, Journal of Hazardous Materials, 169, 480–485.
- Yang, X., Xue, Y. and Wang, W. (2009) Mechanism, Kinetics and Application Studies on Enhanced Activated sludge by Interior Microelectrolysis, Bioresource Technology, 100, 649–653.
- Yavuz Y. and Shahbazi R. (2012) Anodic Oxidation of Reactive Black 5 Dye using Boron Doped Diamond Anodes in a Bipolar Trickle Tower Reactor, Separation and Purification Technology 85 130–136.
- Ying, D., Peng J., Xu X., Li K., Wang Y. and Ji, J. (2012). Treatment of Mature Landfill Leachate by Internal Micro-electrolysis Integrated with Coagulation: A Comparative Study on a Novel Sequencing Batch Reactor Based on Zero Valent Iron, Journal Hazardous Materials 229, 426- 433.
- Zhou, J., Gao, J., Liu, Y., Xiao, S., Zhang, R. and Zhang, Z. (2013). Contaminant Removal Performances on Domestic Sewage using Modified Anoxic/Anaerobic/Oxic Process and Micro-electrolysis, Environmental Technology, 34 (19) 2773–2779.
- Zhou, Z., Qiao, W., Lin, Y., Shen, X., Hu, D., Zhang, J., Jiang, L.M. and Wang, L. (2014). Phosphonate Removal from Discharged Circulating Cooling Water using Iron-Carbon Micro-Electrolysis, Water Science Technology 70(3), 524-532.
Ayrıntılar
| Birincil Dil | Türkçe |
|---|---|
| Bölüm | Araştırma Makalesi |
| Yazarlar | |
| Yayımlanma Tarihi | 12 Kasım 2015 |
| Yayımlandığı Sayı | Yıl 2015 Cilt: 16 Sayı: 2 |
