한국염색가공학회지 (Textile Coloration and Finishing)

  • 제17권2호
  • /
  • Pages.31-39
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  • 2005
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  • 1229-0033(pISSN)
  • /
  • 2234-036X(eISSN)
한국염색가공학회 (The Korean Society of Dyers and Finishers)
권호 표지

수용액 중의 염료 제거를 위한 폐수처리공정의 특성(1) -화학적 응집 및 생물학적 처리-

Characteristics of The Wastewater Treatment Processes for The Removal of Dyes in Aqueous Solution(1) - Chemical Precipitation or Biological Treatment -

  • 한명호 (경일대학교 신소재환경공학과) ;
  • 허만우 (경일대학교 섬유패션학부)
  • Han Myung Ho (Department of advanced materials and environmental engineering, Kyungil University) ;
  • Huh Man Woo (School of textile and fashion technology, Kyungil University)
  • 발행 : 2005.04.01
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초록

This study was conducted to remove the dyes in dye wastewater by the chemical precipitation or biological treatment which are one of the main pollutants in dye wastewater. In order to remove the disperse dyes effectively in aqueous solution by chemical precipitation process, coagulation and flocculation tests were carried out using several coagulants on various reaction conditions. It was found that the Ferrous sulfate was the most effective coagulant for the removal of disperse dye(DB79), and we could get the best result for the removal of disperse dye(DB56) in the aspects of TOC removal efficiency and sludge yield. When the Ferrous sulfate dosage was 800mg/l, the sludge settling velocity was very fast$(SV_{30}=4\%)$, and the color was effectively removed in the disperse dye(DB79) solution. Although the color removal was ineffective when the Alum was used as a coagulant, the sludge yield decreased in comparison with the Ferrous sulfate or the Ferric sulfate being used in the disperse dye(DB56) solution. In order to decolorize disperse dye(DR17) by using biological treatment process, a strain which has potential ability to degrade disperse dyes was isolated from natural system. The optimal culture conditions of temperature and pH were found to be $40^{\circ}C\;and\;8.5\~9$, respectively. When yeast extract was mixed with polypeptone at the mixing ratio of 1:1 as a nitrogen source, decolorization efficiency was highest$(93\%)$ among the nitrogen sources. The strain screened was excellent to adjust to pH, and it seems to have ability to control pH needed to growth. The optimal culture conditions in concentration of $MgSO_{4.}\cdot7H_2O\;and\;KH_2PO_4$ were $0.1\%(w/v)\;and\;0.2\%(w/v)$, respectively. Strains degrading and decolorizing reactive dyes, RB198 and RR141 which were isolated from water system, are named RBK1 and RRK. And the cell growth characteristics of RBK1 and RRK were investigated. The optimal culture conditions of temperature and pH were found to be 30t' and 7.0, respectively. Optimum nitrogen source was peptone, and it was found that decolorization efficiencies by strains RBK1 and RRK, were $85\%\;and\;62\%$, respectively, with introduction of 4,000mg/l of peptone. In the case of RBK1, color removal efficiencies were very high below 400mg/l. Decolorization efficiency was over $90\%$ at 20hours of culture time. The Color degradation ability of RRK was lower than that of RBK1.

키워드

참고문헌

  1. S. Beszedits, 'Ozonation to Decolor Textile Effluents', American Dyestuff Reporter, pp. 301-305(1980)
  2. Y. Y. Yang, The Present Conditions and Countermeasures of Dyeing Wastewater, J. of Env. Hi-Tech. 4, 2-11(1996)
  3. M. H. Ban, et al., Treatment of Dye-Processing Wastewater by Chemical Precipitation, J. Korean Soc. Dyers & Finishers, 9(6), 26-32(1997)
  4. M. W. Cho, et al., Isolation and Culture Characteristics of Strains for Color Removal of Disperse Dyes, J. Korean Soc. Dyers & Finishers, 12(1), 25-31(2000)
  5. M. H. Han, et al., Ozonation of Reactive Dyes and Control of THM Formation Potentials, J. Korean Soc. Dyers & Finishers, 16(2), 34-40(2004)
  6. M. H. Han, et al., Adsorption of The Reactive Dyes on Aqueous Solutions and The Changes of THMFPs Using Activated Carbon Fiber, J. Korean Soc. Water & Wastewater, 17(1), 145-155(2003)
  7. M. H. Han, et al., Chemical Precipitation Treatment for the Disperse Dyes Removal, J. Korean Soc. Dyers & Finishers, 14(2), 40-50(2002)
  8. J. T. Spadaro, et al., Degradation of Azo Dyes by The Lignin-degrading Fungus Phanerochaete Chrysosporium, J. Applied & Env. Microbiol., 58(8) 2397-2401 (1992)
  9. B. H. Ryu and Y. D. Weon, Decolorization of Azo Dyes by Aspergillus Sojae B-10, J. Microbiol. & Biotech., 2(3), 215-219(1992)
  10. J. M. Kim, et al., Isolation and Culture Characteristics of Strains for Color Removal of Reactive Dyes, J. Korean Sac. Water & Wastewater, 12(4), 78-85(1998)
  11. 安武 重雄, 排水處理におけるオヅンの利用, 用水と廢水, 34(4), 31(1992)
  12. Y. Y. Yang and H. J. Kang, Color Removal of Dyes Using Electro-beam Accelerator, J. Env. Hi-Tec., 10(2), (1997)
  13. Editorial Dept. of Donghwa Pub., 'Examination of Water and Wastewater', Donghwa Pub., pp.129-173(1996)
  14. J. R. Shin, 'Chemicals for Water Treatment', Donghwa Pub., pp.22-33(1992)
  15. J. W. Kwak, Characteristics of Inorganic Coagulants and The Application for Water Treatment, J. Env. Hi-Tec., 5, 90(1998)
  16. S. S. Kim et al., A Study on the Decomposition Properties of Disperse Dye Ozone Oxidation Treatment and the Optimum Treatment Condition(I), J. Korean Soc. Dyers & Finishers, 8(1), 43-55(1996)
  17. D. G. Ra and D. G. Her, Colour Removal of Landfill Leachate by Coagulation, J. Korean Soc. of Env. Eng., 20(5), 701-710(1998)
  18. 遊佐 美津雄, '集理論の限界', 浮選, p. 123(1973)