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NTIS 바로가기Resources recycling = 자원리싸이클링, v.30 no.6, 2021년, pp.53 - 60
왕제필 (국립부경대학교 금속공학과, 마린융합디자인공학과(첨단소재공학)) , 김행구 (한국해양대학교 에너지자원공학과) , 고민석 (국립부경대학교 마린융합디자인공학과(첨단소재공학)) , 이동헌 (국립부경대학교 마린융합디자인공학과(첨단소재공학))
In EAF steelmaking industries, MgO content in slag increases due to the addition of dolomite flux to protect refractory lines of furnaces and improve the desulfurization capability of slag. In addition, coal powder is injected in the molten steel bath to increase the energy efficiency of the process...
Liesbeth Horckmans, Peter Nielsen, Philippe Dierckx, et al., 2019 : Recycling of refractory bricks used in basic steel-making : A review, Resources, Conservation & Recycling, 140, pp.297-304.
Kun Mok Shon, Jang Su Kim, Si Wan Kim, et al., 2002 : Recycling of waste refractory materials for steel, Ceramist, 5(5), pp.35-42.
POSCO Chem-Tech, 2011. KR. KR20110124661A.
Mohammed Tayeb, Andre N. Assis, Seetharaman Sridhar, et al., 2015 : MgO Solubility in Steelmaking Slags, Metallurgical and Materials Transactions B 46(3), pp.1112-1114.
Ping Wang, Qing-min Meng, Hong-ming Long, et al., 2006 : Influence of Basicity and MgO on Fluidity and Desulfurization Ability of High Aluminum Slag, High Temp. Mater. Proc., 35(7), pp.669-675.
K. S. Kwong., J. P. Bennett., 2000 : Balancing MgO for Foamy Slag and Refractory Protection, D.L. Schroeder & Associates, Twenty Second Annual Symposium, Process Systems for Electric Furnace Steelmaking, Orlando, Florida, 9-10 November 2000.
Deisi Vieiraa, Rodolfo Arnaldo Montecinos de Almeidaa, Wagner Viana Bielefeldta, et al., 2016 : Slag Evaluation to Reduce Energy Consumption and EAF Electrical Instability, Materials Research, 19(5), pp.1127-1131.
A. P. Luz, T. A. Avila, P. Bonadia, et al., 2011 : Slag Foaming: Fundamentals, Experimental Evaluation and Application in the Steelmaking Industry, Refractories Worldforum, 3(2), pp.91-98.
Kyei-Sing Kwong and James P. Bennett, 2002 : Recycling practices of spent MgO-C refractories, Journal of Minerals & Materials Characterization & Engineering, 1(2), pp.69-78.
A.N. Conejo, R.G. Lule, F. Lopez, et al., 2006 : Recycling MgO-C refractory in Electric Arc Furnaces, Resources Conservation and Recycling, 49(1), pp.14-31.
Rodolfo Montecinos Almeida, Deisi Vieira, W. V. Bielefeldt, et al., 2017 : MgO Saturation Analisys of CaO-SiO 2 -FeO-MgO-Al 2 O 3 Slag System, Materials Research, 21(1).
Marcus Kirschen, 2020 : Visualization of Slag Data for Efficient Monitoring and Improvement of Steelmaking Slag Operation in Electric Arc Furnaces, with a Focus on MgO Saturation, Metals - Open Access Metallurgy Journal, 11(1), pp.17.
Marcus Kirschen, In-Ho Jung and Gernot Hackl, 2020 : Phase Equilibrium Diagram for Electric Arc Furnace Slag Optimization in High Alloyed Chromium Stainless Steel-making, Metals, 10(6), pp.826.
Alena Pribulova, Peter Futas, Jozef Petrik, et al., 2018 : Comparison of cupola furnace and blast furnace slags with respect to possibilities of their utilization, Arch. Metall. Mater., 63(4), pp.1865-1873.
James Bennett, Kyei-Sing Kwong, 2010 : Thermodynamic Studies of MgO Saturated EAF Slag, Ironmaking & Steel-making, 37(7), pp.529-535.
Fruehan, R J., Li, Y., Brabie, L., 2003 : Dissolution of magnesite and dolomite in simulated EAF slags, ISSTECH-Conference Proceedings, pp.799-812, Iron & Steel Society International Technology Conference and Exposition, Indianapolis, IN., USA, 2003.
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