Journal of Korean Society of Water and Wastewater (상하수도학회지)

The Korean Society of Water and Wastewater (대한상하수도학회)
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Disinfection effect and formation characteristics of disinfection by-product at the Electrolyzed Water

전기분해수 살균효과 및 소독부산물 생성 특성 평가

  • 조영만 (부산광역시상수도사업본부 수질연구소)
  • Received : 2013.08.27
  • Accepted : 2013.10.04
  • Published : 2013.10.15
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Abstract

Chlorine has strong oxidizing power, also it is many advantages over other disinfectants such as the residual characteristic and economic feasibility. However, chlorine also has disadvantages such as creating disinfection by-products of chlorine as THMs. In particular, the most deadly disadvantage of chlorine is that it is extremely poisonous toxins about all alive lives. Disinfection with electrolysis water can be a very useful way Because you do not have to worry about chlorine's dangerous. In this study, we evaluated the potential as a disinfectant, across the evaluating disinfection effect and generating characteristic of by-products. The electrolyzed water could be obtained removal efficiencies of over 99.9 % the coliform by operating condition such as residence time, current density (voltage), the electrode gap. The residual chlorine be generated 10,000 mg/L in current density $1.0A/dm^2$ and residence time of 10 minutes. The residual chlorine concentration was possible to maintain a stable. The by-products generated by high concentration residual chlorine in the reactor such as trihalomethanes, haloaceticacid, chloralhydrate, haloacetonitrile were detected in less than a water quality standards. At the concentration of less than residual chlorine of 1 ppm, the chlorine disinfection by-products be generated most below the detection limit.

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References

  1. Jun-O h Park, Wan-Sok Kim, Young-Ki Choi, Young-Min Lee, Hyong Kyu Kim, Eun- Jong Cha, Seok-Yong Kim(2008), Disinfection of Bacteria in Saline-Tap Water by Electrolysis, Journal of Biomedical Research, 9(2), pp21-28
  2. Song J ae-Min, Han Moo-Young, Chung Tai-Hak(2001), The Effect of Coagulation Time on the Turbidity Removal Efficiency in Electrocoagulation, Journal of the Korean Society of Water and Wastewater, 15(1), pp50-57
  3. Dongh yuk Shin, Eunseok Jo, Hyengsung Kim, Jaehyun Kwon(2011), A Study on the generation of oxidants and its application by electrolysis, Journal of the Korean Society of Water and Wastewater, 22(4), pp156
  4. Jong-man Lee, Nam-jun Jo(2012), A Study on the generation of hypochlorous acid in the underground water with using electrolysis, Korea University of Technology & Education, Chonan pp330-708
  5. Jinsik Sohn, Sunjae Lee, Chorong Shin(2009), Model development for chlorine generation using electrolysis, Journal of Korean Society of Water and Wastewater, 23(3) pp331-337
  6. Kyung -hyuk Lee, Jae-Lim Lim, Doo-Jin Lee, Seong Su Kim, Hyo-Won Ahn(2005), Evaluation of Disinfection Characteristics for Mixed Oxidants produced by electrochemical method, Journal of the Korean Society of Water and Wastewater, 19(5), pp625-631
  7. Moham mad Y.A. Mollah, Paul Morkovsky, Jewel A.G. Gomes, Mehmet Kesmez, Jose Parga, David L. Cocke(2004), Fundamentals, present and future perspectives of electrocoagulation, Journal of Hazardous Materials B114, pp199-210
  8. Peter K. Holt, Geoffrey W. Barton, Cynthia A. Mitchell(2004), The future for electrocoagulation as a localised water treatment technology, Chemosphere, 59, pp355-367