The application of advanced oxidation technologies to the treatment of effluents from the pulp and paper industry: a review

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• 作者：Daphne Hermosilla ; Noemí Merayo…
• 关键词：Advanced oxidation processes ; Biodegradability ; Electrooxidation ; Fenton ; Ozone ; Paper industry ; Photocatalysis ; Wastewater treatment chains
• 刊名：Environmental Science and Pollution Research
• 出版年：2015
• 出版时间：January 2015
• 年：2015
• 卷：22
• 期：1
• 页码：168-191
• 全文大小：805 KB
• 参考文献：1. Ahmad AL, Wong SS, Teng TT, Zuhairi A (2007) Optimization of coagulation-flocculation process for pulp and paper mill effluent by response surface methodological analysis. J Hazard Mater 145:162-68
  2. Ahmed B, Mohamed H, Limem E, Nasr B (2009) Degradation and mineralization of organic pollutants contained in actual pulp and paper mill wastewaters by a UV/H₂O₂ process. Ind Eng Chem Res 48:3370-379
  3. Alvares ABC, Diaper C, Parsons SA (2001) Partial oxidation by ozone to remove recalcitrance from wastewaters—a review. Environ Technol 22:409-27
  4. Amat AM, Arques A, Miranda MA (1999) p-Coumaric acid photodegradation with solar light, using 2,4,6-triphenylpyrylium salt as photosensitizer—a comparison with other oxidation methods. Appl Catal B 23:205-14
  5. Amat AM, Arques A, Beneyto H, García A, Miranda MA, Segui S (2003) Ozonisation coupled with biological degradation for treatment of phenolic pollutants: a mechanistically based study. Chemosphere 53:79-6
  6. Amat AM, Arques A, López F, Segui S, Miranda MA (2004) Abatement of industrial sulfonic pollutants by ozone and UV radiation. Environ Eng Sci 21:485-92
  7. Amat AM, Arques A, López F, Miranda MA (2005a) Solar photo-catalysis to remove paper mill wastewater pollutants. Sol Energy 79:393-01
  8. Amat AM, Arques A, Miranda MA, López F (2005b) Use of ozone and/or UV in the treatment of effluents from board paper industry. Chemosphere 60:1111-117
  9. Antony SP, Natesan B (2012) Optimization of integrated electro-bio process for bleaching effluent treatment. Ind Eng Chem Res 51:8211-221
  10. Antunes CSA, Bietti M, Salamone M, Scione N (2004) Early stages in the TiO₂-photocatalyzed degradation of simple phenolic and non-phenolic lignin model compounds. J Photochem Photobiol A 163:453-62
  11. Baig S, Liechti PA (2001) Ozone treatment for biorefractory COD removal. Water Sci Technol 43:197-04
  12. Bailey PS (ed) (1982) Ozonation in organic chemistry: nonolefinic compounds. Academic, New York
  13. Balabani? D, Hermosilla D, Blanco A, Merayo N, Klemenci? AK (2010) The possibility of removal of endocrine disrupters from paper mill waste waters using anaerobic and aerobic biological treatment, membrane bioreactor, ultra-filtration, reverse osmosis and advanced oxidation processes. In: Popov V, Brebbia CA (eds) Environmental toxicology III, vol 132. WIT Transactions on Ecology and the Environment. pp 33-4
  14. Balabani? D, Hermosilla D, Merayo N, Klemenci? AK, Blanco A (2012) Comparison of different wastewater treatments for removal of selected endocrine-disruptors from paper mill wastewaters. J Environ Sci Health A 47:1350-363
  15. Balcioglu IA, Cecen F (1999) Treatability of kraft pulp bleaching wastewater by biochemical and photocatalytic oxidation. Water Sci Technol 40:281-88
  16. Balcioglu IA, Moral CK (2008) Homogeneous and heterogeneous catalytic ozonation of pulp bleaching effluent. J Adv Oxid Technol 11:543-50
  17. Balcioglu IA, Alaton IA, Otker M, Bahar R, Bakar N, Ikiz M (2003) Application of advanced oxidation processes to different industrial wastewaters. J Environ Sci Health A 38:1587-596
  18. Balcioglu IA, Tarlan E, Kivilcimdan C, Sacan MT (2007) Merits of ozonation and catalytic ozonation pre-treatment in the algal treatment of pulp and paper mill effluents. J Environ Manag 85:918-26
  19. Barnd?k H, Hermosilla D, Cortijo L, Negro C, Blanco A (2012) Assessing the effect of inorganic anions on TiO₂-photocatalysis and ozone oxidation treatment efficiencies. J Adv Oxid Technol 15:125-32
  20. Bauer R, Fallmann H (1997) The photo-Fenton oxidation—a cheap and efficient wastewater treatment method. Res Chem Intermed 23:341-54
  21. Bauman HD, Lutz LR (1974) Ozonation of a kraft mill effluent. Tappi J 57:116-19
  22. Beltrán FJ, Encinar JM, Alonso MA (1998) Nitroaromatic hydrocarbon ozonation in water. 1. Single ozonation. Ind Eng Chem Res 37:25-1
  23. Beltrán FJ, García-Araya JF, Alvarez PM (2000) Sodium dodecylbenzenesulfonate removal from water and wastewater. 1. Kinetics of decomposition by ozonation. Ind Eng Chem Res 39:2214-220
  24. Benkelberg HJ, Warneck P (1995) Photodecomposition of iron (III) hydroxo and sulfato complexes in aqueous solution-wavelength dependence of OH^. and SO₄ <sup>?/sup> quantum yields. J Phys Chem 99:5214-221
  25. Bierbaum S, ?eller HJ (2009) Cost savings in the ozone treatment of paper mill effluents achieved by a closed-loop ozone control system. Ozone Sci Eng 31:454-60
  26. Bierbaum S, Escabasse J-Y, Well A, Kompare B, Drev D, Krivograd Klemencic A (2012) Reducing fresh water consumption in paper industry by recycling AOP-treated effluents. Fresenius Environ Bull 8:2178-184
  27. Bierbaum S, ?eller</sup>
• 刊物类别：Earth and Environmental Science
• 刊物主题：Environment
  Environment
  Atmospheric Protection, Air Quality Control and Air Pollution
  Waste Water Technology, Water Pollution Control, Water Management and Aquatic Pollution
  Industrial Pollution Prevention
  
• 出版者：Springer Berlin / Heidelberg
• ISSN：1614-7499

文摘

The paper industry is adopting zero liquid effluent technologies to reduce freshwater use and meet environmental regulations, which implies closure of water circuits and the progressive accumulation of pollutants that must be removed before water reuse and final wastewater discharge. The traditional water treatment technologies that are used in paper mills (such as dissolved air flotation or biological treatment) are not able to remove recalcitrant contaminants. Therefore, advanced water treatment technologies, such as advanced oxidation processes (AOPs), are being included in industrial wastewater treatment chains aiming to either improve water biodegradability or its final quality. A comprehensive review of the current state of the art regarding the use of AOPs for the treatment of the organic load of effluents from the paper industry is herein addressed considering mature and emerging treatments for a sustainable water use in this sector. Wastewater composition, which is highly dependent on the raw materials being used in the mills, the selected AOP itself, and its combination with other technologies, will determine the viability of the treatment. In general, all AOPs have been reported to achieve good organic removal efficiencies (COD removal >40?%, and about an extra 20?% if AOPs are combined with biological stages). Particularly, ozonation has been the most extensively reported and successfully implemented AOP at an industrial scale for effluent treatment or reuse within pulp and paper mills, although Fenton processes (photo-Fenton particularly) have actually addressed better oxidative results (COD removal?≈-5-5?%) at a lab scale, but still need further development at a large scale.