Advanced treatment of biologically pretreated coking wastewater by electrochemical oxidation using Ti/RuO2-IrO2 electrodes

Journal of Chemical Technology and Biotechnology

Volumn 88, Issue 8, 2013, Pages 1568-1575

  He, Xuwen ^a   Chai, Zhen ^a   Li, Fuping ^b   Zhang, Chunhui ^a   Li, Dong ^a   Li, Jing ^a   Hu, Jianlong ^a  

^a CHINA UNIVERSITY OF MINING AND TECHNOLOGY   (China)

^b Guangxi Nonferrous Metals Group Co Ltd   (China)

Author keywords

COD and NH4+ N; Coking wastewater; Electrochemical oxidation; Energy consumption; Ti RuO2 IrO2 electrodes

Indexed keywords

ADVANCED TREATMENT; COKING WASTEWATER; DISCHARGE STANDARDS; ELECTROCHEMICAL TREATMENTS; GAS CHROMATOGRAPHY-MASS SPECTROMETRIES (GC-MS); OPTIMAL CONDITIONS; OPTIMUM CONDITIONS; PSEUDO-FIRST ORDER KINETICS;

CHEMICAL OXYGEN DEMAND; CURRENT DENSITY; EFFLUENTS; ELECTRIC DISCHARGES; ELECTRODES; ENERGY UTILIZATION; GAS CHROMATOGRAPHY; WASTEWATER TREATMENT;

ELECTROCHEMICAL OXIDATION;

INDOLE; NITROGEN; PHENANTHRENE; PYRIMIDINE; QUINOLINE; RUTHENIUM DIOXIDE; TITANIUM DIOXIDE; UNCLASSIFIED DRUG;

ARTICLE; CHEMICAL OXYGEN DEMAND; EFFLUENT; ELECTRODE; ENERGY CONSUMPTION; MASS FRAGMENTOGRAPHY; OXIDATION; PH; WASTE WATER; WASTE WATER MANAGEMENT;

EID: 84879885469     PISSN: 02682575     EISSN: 10974660     Source Type: Journal    
DOI: 10.1002/jctb.4006     Document Type: Article

References (62)

1. Zhu XP, Ni JR and Lai P, Advanced treatment of biologically pretreated coking wastewater by electrochemical oxidation using boron-doped diamond electrodes. Water Res 43:4347-4355 (2009).
2. Wei CH, He MH, Ren Y, Li GB and Chen JG, Pollution characteristics of coking wastewater and control strategies: biological treatment process and technology. Acta Sci Circumst 27:1083-1093 (2007).
3. 3-N removal. Water Res 32(2):519-527 (1998).
4. Lim BR, Hu HY and Fujie K, Biological degradation and chemical oxidation characteristics of coke-oven wastewater. Water Air Soil Poll 146(1-4):23-33 (2003).
5. Wang JL, Quan XC, Wu LB, Qian Y and Hegemann W, Bioaugmentation as a tool to enhance the removal of refractory compound in coke plant wastewater. Process Biochem 38(5):777-781 (2002).
6. Lai P, Zhao HZ, Wang C, and Ni JR, Advanced treatment of coking wastewater by co-agulation and zero-valent iron processes. J Hazard Mater 147(1-2):232-239 (2007).
7. Lai P, Zhao HZ, Zeng M and Ni JR, Study on treatment of coking wastewater by bio-film reactors combined with zero-valent iron process. J Hazard Mater 162(2-3):1423-1429 (2009).
8. Zhang MH, Zhao QL, Bai Xand Ye ZF, Adsorption of organic pollutants from coking wastewater by activated coke. Colloids Surf A Physicochem Eng Aspects 362(1-3):140-146 (2010).
9. Zhang M, Tay JH, Qian Y and Gu XS, Comparison between anaerobic-anoxic-oxic and anoxic-oxic systems for coke plant wastewater treatment. J Environ Eng - ASCE 123(9):876-883 (1997).
10. Luthy RG and Tailor JT, Biological treatment of coal gasification process wastewater. Water Res 14:1269-1282 (1980).
11. Cameron S and Paul L, Thiocyanate degradation during activated sludge treatment of coke-ovens wastewater. Biochem Eng J 34:122-130 (2007).
12. Maranon E, Vazquez I, Rodrguez J, Castrillon L, Fernandez Y and Lopez H, Treatment of coke wastewater in a sequential batch reactor (SBR) at pilot plant scale. Bioresource Technol 99:4192-4198 (2008).
13. Sutton PM, Hurvid J and Hoeksema M, Biological fluidized-bed treatment of wastewater from byproduct coking operations: full-scale case history. Water Environ Res 71:5-9 (1999).
14. Lee MW and Park YJ, Biological nitrogen removal from coke plant wastewater with external carbon addition. Water Environ Res 70:1090-1095 (1998).
15. Qian Y, Wen YB and Zhang HM, Efficacy of pre-treatment methods in the activated sludge removal of refractory compounds in coke-plant wastewater. Water Res 28:701-707 (1994).
16. Wang JL, Quan XC, Wu LB, Qian Y and Werner H, Bio augmentation as a tool to enhance the removal of refractory compound in coke plant wastewater. Process Biochem 38:777-781 (2003).
17. Li HQ, Han HJ, Du MA and Wang W, Removal of phenols, thiocyanate and ammonium from coal gasification wastewater using moving bed biofilm reactor. Bioresource Technol 102:4667-4673 (2011).
18. Wang W, Ma WC, Han HJ, Li HQ and Yuan M, Thermophilic anaerobic digestion of Lurgi coal gasification wastewater in a UASB reactor. Bioresource Technol 102:2441-2447 (2011).
19. Wang JL, Quan XC, Wu LB, Qian Y and Hegemann W, Bio augmentation as a tool to enhance the removal of refractory compound in coke plant wastewater. Process Biochem 38:777-781 (2002).
20. Lee MW and Park YJ, Biological nitrogen removal from coke plant wastewater with external carbon addition. Water Environ Res 70:1090-1095 (1998).
21. Zhao WT, Huang X and Lee DJ, Enhanced treatment of coke plant wastewater using an anaerobic-anoxic-oxic membrane bioreactor system. Sep Purif Technol 66:279-286 (2009).
22. Jia JP, Yang J, Liao J, Wang WH and Wang ZJ, Treatment of dyeing wastewater with ACF electrodes. Water Res 33:881-884 (1999).
23. Shen ZM, Yang J, Hu XF, Lei YM, Ji XL, Jia JP and Wang WH, Dual electrodes oxidation of dye wastewater with gasdiffusion cathode. Environ Sci Technol 39:1819-1826 (2005).
24. Avsar Y, Kurt U and Talha G, Comparison of classical chemical and electrochemical processes for treating rose processing wastewater. J Hazard Mater 148:340-345 (2007).
25. Bahadir KK and Abdurrahman T, Continuous electrochemical treatment of phenolic wastewater in a tubular reactor. Water Res 37(7):1505-1514 (2003).
26. 2-Pt. J Hazard Mater 162:455-462 (2009).
27. Abdelwahab O, Amin NK and El-Ashtoukhy E-SZ, Electrochemical removal of phenol from oil refinery wastewater. J Hazard Mater 163(2-3):711-716 (2009).
28. Noureddine BT and André S, Electrochemical removal of phenol in alkaline solution. Contribution of the anodic polymerization on different electrode materials. Electrochim Acta 54:4809-4816 (2009).
29. Ma HZ, Zhang XH and Ma QL, Electrochemical catalytic treatment of phenol wastewater. J Hazard Mater 165:475-480 (2009).
30. Cui YP, Yang C Z and Qian GM, Remediation of phenol-contaminated sediment by non-uniform electrochemical oxidation reactor. Fresen Environ Bull 15(11):1413-1418 (2006).
31. Rajkumar D, Song BJ and Kim JG, Electrochemical degradation of Reactive Blue 19 in chloride medium for the treatment of textile dyeing wastewater with identification of intermediate compounds. Dyes Pigments 72:1-7 (2007).
32. Bahadir KK, Response surface optimization of electrochemical treatment of textile dye wastewater. J Hazard Mater 145:277-286 (2007).
33. Cao LM, Yang J and Jia JP, Electro-thermal treatment of high concentration ammonia in water by gaseous oxidation inliquid phase (GOLP). Chemosphere 80:463-468 (2010).
34. Lei XH, Li M, Zhang ZY, Feng CP, Bai W and Sugiura N, Electrochemical regeneration of zeolites and the removal of ammonia. J Hazard Mater 169:746-750 (2009).
35. Pikaar I, Rozendal RA, Yuan Z, Keller J and Rabaey K, Electrochemical sulfide removal from synthetic and real domestic wastewater at high current densities. Water Res 45:2281-2289 (2011).
36. Feng C, Sugiura N, Shimada S and Maekawa T, Development of a high performance electrochemical wastewater treatment system. J Hazard Mater 103:65-78 (2003).
37. Feng YJ and Li XY, Electro-catalytic oxidation of phenol on several metal-oxide electrodes in aqueous solution. Water Res 37:2399-2407 (2003).
38. Wang YQ, Gu B and Xu WL, Electro-catalytic degradation of phenol on several metal-oxide anodes. J Hazard Mater 162:1159-1164 (2009).
39. Zhou MH, Dai QZ, Lei LC, Ma C and Wang DH, Long life modified lead dioxide anode for organic wastewater treatment: electrochemical characteristics and degradation mechanism. Environ Sci Technol 39:363-370 (2005).
40. Awad YM and Abuzaid NS, Electrochemical oxidation of phenol using graphite anodes. Sep Sci Technol 34(4):699-708 (1999).
41. Torres RA, Torres W, Peringer P and Pulgarin C, Electrochemical degradation of p-substituted phenols of industrial interest on Pt electrodes. Attempt of a structure-reactivity relationship assessment. Chemosphere 50:97-104 (2003).
42. Comninellis C, Electrocatalysis in the electrochemical conversion/combustion of organic pollutants for wastewater treatment. Electrochim Acta 39:1857-1862 (1994).
43. Simod O and Comninellis C, Anodic oxidation of organics on Ti/IrO2 anodes using Na.on(R) as electrolyte. Electrochim Acta 42:2013-2018 (1997).
44. 2 anodes on stainless steel. Electrochim Acta 52:7022-7027 (2007).
45. 5 based anodes for wastewater treatment. J Appl Electrochem 33:1211-1215 (2003).
46. Li XY, Cui YH, Feng YJ, Xie ZM and Gu JD, Reaction pathways and mechanisms of the electrochemical degradation of phenol on different electrodes. Water Res 39(10):1972-1981 (2005).
47. Iniesta J, González-Garciá J, Expósito E, Montiel V and Aldaz A, Influence of chloride ionon electrochemical degradation of phenol in alkaline medium using bismuth doped and pure PbO2 anodes. Water Res 35:3291-3300 (2001).
48. Hao YC, Ge WQ and Liu YJ, Application of electrode material for treatment of organic wastewater by electrochemical catalytic oxidation. Chem Eng 01:35-37 (2012).
49. 2 anodes: a study of microstructure and working life for the chlorine evolution reaction. Ceram Int 33(6):1087-1091 (2007).
50. Kim S, Choi SK and Yoon BY, Effects of electrolyte on the electrocatalytic activities of RuO2/Ti and Sb-SnO2/Ti anodes for water treatment. Appl Catal B - Environ 97:135-141 (2010).
51. Kapalka A, Fóti G and Comninellis C, Basic principles of the electrochemical mineralization of organic pollutants for wastewater treatment. in Electrochemistry for the Environment, ed by Comninellis C and Chen G. Springer Science+Business Media, LLC, 1-23 (2010).
52. Arena F, Giovenco R, Torre T, Venuto A and Parmaliana A, Activity and resistance to leaching of Cu-based catalysts in the wet oxidation of phenol. Appl Catal B 45:51-62 (2003).
53. Lim BR, Hu HY and Fu KJ, Biological degradation and chemical oxidation characteristics of coke-oven wastewater. Water Air Soil Pollut 146:23-33 (2003).
54. Guo DS, Shi QT, He BB and Yuan XY, Different solvents for the regeneration of the exhausted activated carbon used in the treatment of coking wastewater. J Hazard Mater 186:1788-1793 (2011).
55. Chu LB, Wang JL, Dong J, Liu HY and Sun XL, Treatment of coking wastewater by an advanced Fenton oxidation process using iron powder and hydrogen peroxide. Chemosphere 86:409-414 (2012).
56. Vázquez I, Rodríguez J, Maranón E, Castrillón L and Fernández Y, Simultaneous removal of phenol, ammonium and thiocyanate from coke wastewater by aerobic biodegradation. J Hazard Mater B 137:1773-1780 (2006).
57. Li, YM, Gu GW, Zhao JF and Yu HQ, Anoxic degradation of nitrogenous heterocyclic compounds by acclimated activated sludge. Process Biochem 37:81-86 (2001).
58. Wei XX, Zhang ZY, Fan QL, Yuan XY and Guo DS, The effect of treatment stages on the coking wastewater hazardous compounds and their toxicity. J Hazard. Mater 239-240:135-141 (2012).
59. Iniesta J, Michaud PA, Panizza M, Cerisola G, Aldaz A and Comninellis C, Electrochemical oxidation of phenol at boron-doped diamond electrode. Electrochim Acta 46:3573-3578 (2001).
60. Rodrigo MA, Michaud PA, Duo I, Panizza M, Cerisola G and Comninellis C, Oxidation of 4-chlorophenol at boron-doped diamond electrode for wastewater treatment. J Electrochem Soc 148:D60-D64 (2001).
61. Lai P, Zhao HZ, Wang C and Ni JR, Advanced treatment of coking wastewater by coagulation and zero-valent iron processes. J Hazard Mater 147:232-239 (2007).
62. Zhang WH, Wei CH, Feng CH, Yan B, Li N, Peng PG and Fu JM, Coking wastewater treatment plant as a source of polycyclic aromatic hydrocarbons (PAHs) to the atmosphere and health-risk assessment for workers. Sci Tatal Environ 432:396-403 (2012).