• Enhanced Separation Technique of Heavy Metal (Pb, Zn) in Contaminated Agricultural Soils near Abandoned Metal Mine
  • Park, Chan Oh;Kim, Jin Soo;Seo, Seung Won;Lee, Young Jae;Lee, Jai Young;Park, Mi Jeong;Kong, Sung Ho;
  • Institute of Technology Research, Korea Resources Corporation;Research Institute, Aina Environmental Group Korea Co. Ltd.;Research Institute, Aina Environmental Group Korea Co. Ltd.;Department of Earth & Environmental Sciences, Korea University;Department of Environmental Engineering, The University of Seoul;Institute of Mine Reclamation Technology, Mine Reclamation Corporation;Department of Chemical Engineering, Hanyang University;
  • 폐금속 광산지역 농경지 납, 아연 오염 토양의 중금속 고도선별
  • 박찬오;김진수;서승원;이영재;이재영;박미정;공성호;
  • 한국광물자원공사 기술연구원;아이나환경코리아 부설연구소;아이나환경코리아 부설연구소;고려대학교 지구환경과학과;서울시립대학교 환경공학과;한국광해관리공단 광해기술연구소;한양대학교 화학공학과;
Abstract
The study is to propose the optimal separation technique of heavy metals (Pb and Zn) contaminated in soil for improving the removal efficiency by various applicable techniques. The heavy metal contaminated soil samples near abandoned mine X-1 and X-2 were used for the study. Firstly, the wet classification process was shown more than 80% of removal efficiency for lead and zinc. Meanwhile, the magnetic separation process was shown low removal efficiency for lead and zincs because those heavy metals were non-magnetic materials. For the next step, the flotation separation process was shown approximately 24.4% of removal efficiency for zinc, while the gravity concentration process was shown approximately 57% of removal efficiency for lead, and 19.9% of removal efficiency for zinc, respectively. Therefore, zinc contaminated in soil would be effectively treated by the combination technique of the wet classification and the flotation technique. Meanwhile, lead contaminated in soil would be effectively treated by the combination technique of the wet classification process and the flotation process. Furthermore, the extraction of organic matter was shown more effective with aeration, 3% of hydrogen peroxide and 3% of lime such as calcium hydroxide.

Keywords: Heavy metal (Lead;Zinc) contamination in soil;Abandoned metal mine;Separation technique of heavy metal;Soil restoration;

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This Article

  • 2013; 18(7): 41-53

    Published on Dec 30, 2013

  • 10.7857/JSGE.2013.18.7.041
  • Received on Sep 30, 2013
  • Revised on Nov 14, 2013
  • Accepted on Nov 14, 2013