• Feasibility Tests for Treating Fine Suspended Solids from Mining Drainage, using Various Media by Column Methods - A Case from H Coal Mine
  • Lee, Sanghoon;Kwon, HyukHyun;Oh, Minah;Lee, Jai-Young;Kim, DukMin;
  • Department of Environmental engineering, The Catholic University of Korea;Department of Environmental engineering, The Catholic University of Korea;Department of Environmental engineering, The University of Seoul;Department of Environmental engineering, The University of Seoul;Mine Reclamation and Technology Center, Mine Reclamation Corporation;
  • 광산배수 부유물질 저감을 위한 다양한 여과 매질의 특성 및 적용성 평가 - H 석탄광산 배수
  • 이상훈;권혁현;오민아;이재영;김덕민;
  • 가톨릭대학교 환경공학전공;가톨릭대학교 환경공학전공;서울시립대학교 환경공학부;서울시립대학교 환경공학부;한국광해관리공단 기술연구소;
Abstract
Fine suspended solids from mine drainage draw attentions due to their potential adverse influences on the water quality, such as increasing turbidity and degrading aesthetic landscape. Currently, sand filter beds are adapted in some mine drainage treating systems. However, more efficient system is in demand, as the existing sand beds reveal some problems, such as frequent maintenance intervals. Various filtering mediums including fly ash, mine tailing aggregates and the sand were tested for improving the current system, using column experimental set-up. Mine drainage samples were collected from the current treating systems in the abandoned H coal mine. The experiment was run for 7 days. Suspended solids recorded as 100.9 mg/L and the value exceeds the current standard, 30 mg/L. Sand was proved to still be the optimum medium for the fine suspended solids, compared to fly ash and fly ash + sand. Mine tailing aggregates were placed at the exit of the columns, substituting gravels. The tailing aggregates is made by mine tailings and clay. Sand bed filters can also be improved by mixing granular activated carbon, which was found to be economical and efficient in the batch experiment, conducted at the same time.

Keywords: Mine drainage;Suspended solids;Sand bed;Filtration;

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This Article

  • 2012; 17(6): 112-118

    Published on Dec 31, 2012

  • 10.7857/JSGE.2012.17.6.112
  • Received on Nov 29, 2012
  • Revised on Dec 10, 2012
  • Accepted on Dec 11, 2012