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Geochemical Reaction Processes and Controls on the Coal Mine Drainage using Pilot-scale Inclined Clarifiers
Lee, SangHoon;Oh, Minah;Lee, Jai-Young;Kwon, Eunhye;Kim, Doyoung;Kim, DukMin;
Pilot 규모의 경사판 침전지 시험을 통한 국내 석탄광산배수내 부유물질의 지구화학적 반응특성 및 조정영향
이상훈;오민아;이재영;권은혜;김도영;김덕민;
가톨릭대학교 환경공학전공;서울시립대학교 환경공학부;서울시립대학교 환경공학부;가톨릭대학교 환경공학전공;가톨릭대학교 환경공학전공;한국광해관리공단 광해기술연구소;

References

1. APHA, AWA, WEF, 2005, Standard Methods, 21st Edition.
2. Cavanagh, J.E., Pope, J., Harding, J.S., Trumm, D., Craw, D., Rait, R., Greig, H., Niyogi, D., Buxtion, R., Champeau, O., and Clemens, A., 2010, A framework for predicting and managing water quality impacts of mining on streams: a user's guide, Landcare Research New Zealand, 139-234.
3. Davidson, J., Helwig, N., and Summerfelt, S.T., 2008, Fluidized sand biofilters used to remove ammonia, biochemical oxygen demand, total coliform bacteria, and suspended solids from an intensive aquaculture effluent, Aquacult. Eng., 39, 6-15.
4. Eckenfelder, W.W., 1989, Industrial Water Pollution Control, 2nd Edition, Mcgaw-Hill Inc., New York, NY, 131-163.
5. Elbana, M., Ramirez de Cartagena, F., and Puig-Bargues, J., 2012, Effectiveness of sand media filters for removing turbidity and recovering dissolved oxygen from a reclaimed effluent used for micro-irrigation, Agr. Water Manage., 111, 27-33.
6. Gozan, M. and Wulan, P.P.D.K., 2011, Design of Precipitation System for the Removal of Total Suspended Solid, Turbidity and Mineral Content from Coal Processing Plant Wastewater, J. Chem. Sci., 1(5), 40-47.
7. Healy, M.G., Rodgers, M., and Mulqueen, J., 2007, Performance of a stratified sand filter in removal of chemical oxygen demand, total suspended solids and ammonia nitrogen from high-strength wastewaters, Environ. Manage., 83, 409-415.
8. Janiyak, H., 1992, Mine drainage treatment in Polish lignite mining, Mine water Environ., 11(1), 35-44.
9. Koohestanian, A., Hosseini, M., and Abbasian, Z., 2008, The Separation Method for Removing of Colloidal Particles from Raw Water, Am.-Eurasian J. Agric. Environ. Sci.,, 4(2), 266-273.
10. Lee, D.K., Yim, G.J., Cheong, Y.W., Sim, Y.S., Park, H.S., and Ji, W.H., 2008, Variation of Ferrous Ion Contents in Mine Drainage by Oxidation Reaction in Water Tanks, J. Kor. Soc. Geosyst. Eng., 45(5), 546-557.
11. Lee, S., Kwon, H.H., Oh, M.A., Lee, J.Y., and Kim, D.M., 2012, Feasibility Tests for Treating Fine Suspended Solids from Minig Drainage, using Various Media by Column Methods-A Case from H Coal Mine, J. Soil Groundwater Env,, 17(6), 112-118.
12. Oh, M., Kim, Wonki, Kim, D.M., Lee, S., and Lee, J-Y., 2012, Settling and Filtering Process for the Treatment of Fine Suspended Solids and Soluble Heavy Metals in H Mine Drainage, J. Soil Groundwater Env., 17(6), 102-111.
13. Oh, M.A., Kim, W.K., Oh, S.J, Kim, D.M., Lee, S.H., and Lee, J.Y., 2013, Removal of Fine Suspended Solids and Soluble Heavy Metals in H Mine Drainage using Settling and Filtering:Field Application, J. Soil Groundwater Env., (in print).
14. Mulligan, C.N., Neginmalak, D., Masaharu, F., and Tomohiro, I., 2009, Filtration of contaminated suspended solids for the treatment of surface water, Chemosphere, 74, 779-786.
15. Packman, J.J., Comings, K.J., and Booth, D.B., 1999, Using turbidity to determine total suspended solids in urbanizing streams in the Puget Lowlands: in confronting Uncertainty: Managing Change in Water Resources and the Environment, Can. Water Resour. Association annual meeting 27-29 October 1999, Vancouver, BC, pp. 158-165.
16. Stumn, W. and Morgan, J.J., 1996, Aquatic Chemistry, John Wiley and SONS, Inc.
17. Sullivan, A. B. and Drever, J. I., 2001, Geochemistry of suspended particles in a mine-affected mountain stream, Appl.Geochem., 16, 1663-1676.

This Article

2013; 18(7): 73-80

Published on Dec 30, 2013
10.7857/JSGE.2013.18.7.073
Received on Nov 22, 2013
Revised on Dec 5, 2013
Accepted on Dec 6, 2013

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