Synthesis of Cordierite from the High-Alumina Fly Ash and Talc Powder Mixtures

Jiang Feng Chen; Guo Peng Guo; Long Yi Shao

doi:10.4028/www.scientific.net/AMR.399-401.1204

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 399-401Synthesis of Cordierite from the High-Alumina Fly...

Synthesis of Cordierite from the High-Alumina Fly Ash and Talc Powder Mixtures

Abstract:

There is much more profit in synthesis of cordierite from high-alumina fly ash, comparing with common fly ash. In this paper, the high-alumina fly ash collected from the Jungar power plant was calcined, grinded, beneficiated with HCl, diluted and dried. Furthermore, the cordierite was conducted from the purified fly ash and talc powder mixtures by solid reaction sintering. The physical properties of the cordierite samples were measured using Archimedes’ method, and the phase of cordierite samples was analyzed by XRD and the microstructure of the cordierite samples was observed by SEM. The results show that the cordierite, based on the proportion of the treated high-alumina fly ash and talc powder designated as 1.515/1 at 1350°C or/an 1370°C for 2h or/and 3h, could meet the quality requirement of physical properties, and the major crystalline phases in the sintered samples were predominantly α-cordierite (indialite) with minor crystals of mullite, spinel and almost no glassy matter.

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Periodical:

Advanced Materials Research (Volumes 399-401)

Pages:

1204-1207

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https://doi.org/10.4028/www.scientific.net/AMR.399-401.1204

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Online since:

November 2011

Authors:

Jiang Feng Chen, Guo Peng Guo, Long Yi Shao

Keywords:

Cordierite, High-Alumina Fly Ash, Sintering, Talc Powder

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References

[1] M. Ahmaruzzaman: Progress in Energy and Combustion Science, Vol.36(2010), p.327

Google Scholar

[2] R.S. Iyer and J.A. Scott: Resources Conservation & Recycling, Vol.31(2001), p.217

Google Scholar

[3] X. Querol, N. Moreno and J.C. Umana: International Journal of Coal Geology, Vol.50(2002), p.413

Google Scholar

[4] N. Chandra, N. Agnihotri, S. Bhasin, A.F. Khan: Journal of the European Ceramic Society, Vol. 25(2005), p.81

Google Scholar

[5] P.K. Rohatgi, D. Weiss and N. Gupta: JOM, Vol. 58(11) (2006), p.71

Google Scholar

[6] J.F. CHEN, L.Y. SHAO and J. LU: Journal of the Geological Society of China, Vol. 82(1) (2008), p.99

Google Scholar

[7] A. Chowdhury, S. Maitra, S. Das, A. Sen, G.K. Samanta, P, Datta: InterCeram: International Ceramic Review, Vol. 56(1) (2007), p.18

Google Scholar

[8] A. Chowdhury, S. Maitra, S. Das, A. Sen, G.K. Samanta, P, Datta: InterCeram: International Ceramic Review, Vol. 56(2) (2007), p.98

Google Scholar

[9] N.N. Sampathkumar, A.M. Umarji, B.K: Materials Research Bulletin, Vol. 30(9) (1995), p.1107

Google Scholar

[10] S. Kumar, K.K. Singh, P. Pamachandrarao: Journal of Materials Science Letters, Vol. 19(2000), p.1263

Google Scholar

[11] R. Goren, C. Ozgur and H. Gocmez: Ceramics International, Vol. 32(2006), pp.53-56

Google Scholar

[12] E. Yalamac and S. Akkurt: Ceramics International. Vol. 32(2006),p.825

Google Scholar

[13] R. Goren, H. Gocmez and C. Ozgur: Ceramics International, Vol.32(2006), p.407

Google Scholar