• Settling and Filtering Process for the Treatment of Fine Suspended Solids and Soluble Heavy Metals in H Mine Drainage
  • Oh, Minah;Kim, WonKi;Kim, DukMin;Lee, SangHoon;Lee, Jai-Young;
  • Department of Environmental Engineering, The University of Seoul;Department of Environmental Engineering, The University of Seoul;Mine Reclamation and Technology Center, Mine Reclamation Corporation;Department of Environmental Engineering, The Catholic University of Korea;Department of Environmental Engineering, The University of Seoul;
  • H 광산배수 내 미세부유물질 및 용해성 중금속의 제거를 위한 침전 및 여과 공법에 관한 연구
  • 오민아;김원기;김덕민;이상훈;이재영;
  • 서울시립대학교 환경공학부;서울시립대학교 환경공학부;한국광해관리공단 광해기술연구소;가톨릭대학교 환경공학전공;서울시립대학교 환경공학부;
Abstract
Fine suspended solids generated effluence from treatment process of mine drainage could destroy environment as the aesthetic landscapes, and depreciate water quality. Therefore, the purpose of this research is focused on process development applied the actual field for controlling fine suspended solids and heavy metals, and so lab-scale test was performed for inducement of basic data. The mine drainage used in this research was sampled in H mine located Jeongseon-gun, Gangwon-do. Concentration of suspended solid, arsenic, iron and manganese was exceeded the standard of contaminant limitation for the clean water, and particle size of suspended solid was less than 10 m as fine particle. Although hydraulic retention time of mine drainage for effective settling was required more than 6 hours, hydraulic retention time would be increased in winter season when the settling efficiency could be reduced because of viscosity decreasing. Moreover, installed inclination plate helped to increase settling efficiency of suspended solid about 48 %. Filtering media that was the most effective removal of suspended solids and heavy metal was decided granular activated carbon of 1~2 mm was the optimal size.

Keywords: Mine drainage;Filtering;Settling;Fine suspended solid;

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This Article

  • 2012; 17(6): 102-111

    Published on Dec 31, 2012

  • 10.7857/JSGE.2012.17.6.102
  • Received on Nov 20, 2012
  • Revised on Dec 4, 2012
  • Accepted on Dec 5, 2012