화력발전소 바닥재로 제조된 결정화 유리의 미세구조

강승구; Seunggu Kang

Korean Journal of Materials Research, Vol.19, No.2, 95-101, February, 2009

DOI10.3740/MRSK.2009.19.2.095 Export Citation

화력발전소 바닥재로 제조된 결정화 유리의 미세구조

Microstructure of Glass-ceramics Made from Bottom Ash Produced at a Thermal Power Plant

강승구 ^†

경기대학교 재료공학과, 경기도 수원시 영통구 이의동 산 94-6

Seunggu Kang^†

Department of Materials Engineering, Kyonggi University, Suwon 443-760, Korea

E-mail:

Glass ceramics were made from coal bottom ash by adding CaO and Li2O as glass modifiers and TiO2 as a nucleating agent in a process of melting and quenching followed by a thermal treatment. The surface of the glass ceramics has 1.6 times more Li2O compared to the inner matrix. When TiO2 was not added or when only 2 wt% was added, the surface parts of the glass ceramics were crystalline with a thickness close to 130 μm. In addition, the matrixes showed only the glass phase and not the crystalline phase. However, doping of TiO2 from 4 wt% to 10 wt% began to create small crystalline phases in the matrix with an increase in the quantity of the crystalline. The matrix microstructure of glass ceramics containing TiO2 in excess of 8 wt% was a mixture of dark-gray crystalline and white crystalline parts. These two parts had no considerable difference in terms of composition. It was thought that the crystallization mechanism affects the crystal growth, direction and shape and rather than the existence of two types of crystals.

Keywords:glass-ceramics;bottom ash;microstructure;surface crystallization;TiO2;bulk crystallization

[References]

Benavidez E, Grasselli C, Quaranta N, Ceram. International, 29(1), 61 (2003)
Kumar S, Stewart J, Mishra S, Inter. J. Environ. Studies, 61(5), 551 (2004)
Kniess CT, De Lima JC, Prates PB, Kuhnen NC, Riella HG, J. Non-Cryst. Solids, 353, 4819 (2007)
Leroy C, Ferro MC, Monteiro RCC, Fernandes MHV, J. Euro. Ceram. Soc., 21(2), 195 (2001)
Erol M, Kucukbayrak S, Ersoy-Mericboyu A, Fuel, 86(5-6), 706 (2007)
Strnad Z, Glass-ceramic Materials: Glass Science and Technology, p. 85-97, Elsevier Science Publishing Co., New York, USA (1986). (1986)
Kim WH, Kang SG, J. Cerm. Proc. Res., to be published, (2009). (2009)
Holand W, Beall G, Glass Ceramic Technology, p. 53-55, The American Ceramic Society, USA (2002). (2002)
Berard MF, Wider DR, Fundamentals of Phase Equilibria in Ceramic Systems, p. 25, R.A.N., USA (1990). (1990)

[Referenced By]

[Related Articles]

[1] Benavidez E, Grasselli C, Quaranta N, Ceram. International, 29(1), 61 (2003)

[2] Kumar S, Stewart J, Mishra S, Inter. J. Environ. Studies, 61(5), 551 (2004)

[3] Kniess CT, De Lima JC, Prates PB, Kuhnen NC, Riella HG, J. Non-Cryst. Solids, 353, 4819 (2007)

[4] Leroy C, Ferro MC, Monteiro RCC, Fernandes MHV, J. Euro. Ceram. Soc., 21(2), 195 (2001)

[5] Erol M, Kucukbayrak S, Ersoy-Mericboyu A, Fuel, 86(5-6), 706 (2007)

[6] Strnad Z, Glass-ceramic Materials: Glass Science and Technology, p. 85-97, Elsevier Science Publishing Co., New York, USA (1986). (1986)

[7] Kim WH, Kang SG, J. Cerm. Proc. Res., to be published, (2009). (2009)

[8] Holand W, Beall G, Glass Ceramic Technology, p. 53-55, The American Ceramic Society, USA (2002). (2002)

[9] Berard MF, Wider DR, Fundamentals of Phase Equilibria in Ceramic Systems, p. 25, R.A.N., USA (1990). (1990)