마이크로웨이브 가열을 이용한 슬래그로부터 인의 용철로의 환원이동에 관한 열역학적 고찰

이준호; 김은주; 김태영; 강윤배; Joonho Lee; Eunju Kim; Taeyoung Kim; Youn-Bae Kang

Korean Journal of Materials Research, Vol.20, No.1, 42-46, January, 2010

DOI10.3740/MRSK.2010.20.1.042 Export Citation

마이크로웨이브 가열을 이용한 슬래그로부터 인의 용철로의 환원이동에 관한 열역학적 고찰

Thermodynamic Study for P Reduction from Slag to Molten Steel by using the Microwave Heating

이준호 ^†, 김은주, 김태영, 강윤배¹

고려대학교 공과대학 신소재공학과
¹포항공과대학교 철강대학원

Joonho Lee^†, Eunju Kim, Taeyoung Kim, and Youn-Bae Kang¹

Department of Materials Science and Engineering, Korea University, 5 Anam-dong, Seongbuk-gu, Seoul, 136-713 Korea
¹GIFT, POSTECH, San 31, Hyoja-dong, Nam-ku, Pohang, 790-784 Korea

E-mail:

Phosphorus exhibits considerable segregation in steelmaking slag. In order to recover phosphorus from slag to K3PO4 via molten iron, a carbothermic reaction using microwave heating was suggested recently. The carbothermic reduction of phosphorus from slag to molten iron using microwave heating was carried out at 2073K. However, at this temperature the thermodynamic properties of both slag and molten iron cannot be determined experimentally. Therefore, the computational approach of the so-called CALPHAD method is very useful to understand the transfer of phosphorus from slag to metal and to enhance this reaction. In the present investigation, a theoretical study of the reduction behavior of phosphorus in slag was carried out at much lower temperatures using the recently developed thermodynamic database in the FactSage program. The calculated results showed reasonable accordance with the experimental data; namely, the thermodynamic database could be applied successfully to higher temperature reactions. The current study found that higher temperature and high SiO2 concentration are favorable for the recovery of phosphorus from slag.

Keywords:carbothermic reduction;microwave;P recovery;slag;thermodynamic

[References]

Yokoyama K, Kubo H, Nakajima K, Jeong YS, Nagasaka T, in Proceeding of 3rd International Conference on Process Development in Iron and Steelmaking (Lulea, Sweden, June 2008), MEFOS, Lulea, Sweden, vol.1, p.551. (2008)
Yokoyama K, Kubo H, Mori K, Okada H, Takeuchi S, Nagasaka T, Tetsu-to-Hagane, 92, 683 (2006)
Morita K, Guo M, Oka N, Sano N, J. Mater. Cycles Waste Manag, 4, 93 (2002)
Fowler RH, Guggenheim EA, Statistical Thermodynamics, p.350, Cambridge, Cambridge, England (1939). (1939)
Pelton AD, Blander M, Metall. Mater. Trans. B, 17, 805 (1986)
Pelton AD, Degterov SA, Eriksson G, Robelin C, Dessurault Y, Metall. Mater. Trans. B, 31, 651 (2000)
Decterov S, Kang YB, Jung IH, J. Phase Equilibria Diffusion, 30, 443 (2009)
Im K, Morita K, Sano N, ISIJ Int., 36, 517 (1996)
Park SS, Lee YB, Ryu SC, Jang YS, Park HC, Korean J. Mater. Res., 6(6), 576 (1996)

[Referenced By]

[Related Articles]

[1] Yokoyama K, Kubo H, Nakajima K, Jeong YS, Nagasaka T, in Proceeding of 3rd International Conference on Process Development in Iron and Steelmaking (Lulea, Sweden, June 2008), MEFOS, Lulea, Sweden, vol.1, p.551. (2008)

[2] Yokoyama K, Kubo H, Mori K, Okada H, Takeuchi S, Nagasaka T, Tetsu-to-Hagane, 92, 683 (2006)

[3] Morita K, Guo M, Oka N, Sano N, J. Mater. Cycles Waste Manag, 4, 93 (2002)

[4] Fowler RH, Guggenheim EA, Statistical Thermodynamics, p.350, Cambridge, Cambridge, England (1939). (1939)

[5] Pelton AD, Blander M, Metall. Mater. Trans. B, 17, 805 (1986)

[6] Pelton AD, Degterov SA, Eriksson G, Robelin C, Dessurault Y, Metall. Mater. Trans. B, 31, 651 (2000)

[7] Decterov S, Kang YB, Jung IH, J. Phase Equilibria Diffusion, 30, 443 (2009)

[8] Im K, Morita K, Sano N, ISIJ Int., 36, 517 (1996)

[9] Park SS, Lee YB, Ryu SC, Jang YS, Park HC, Korean J. Mater. Res., 6(6), 576 (1996)