[1] |
M. Geith, Ch. Majcenovic, A. Wiry. Hercynite & galaxite — “active spinel”, additives for excellent cement rotary kiln bricks. RHI Bulletin, 2003:25-28.
|
[2] |
Jacek Szczerba, Ilona Jastrzebska, Zbigniew Pedzich, Mirosław M. Bućko. Corrosion of basic refractories in contact with cement clinker and kiln hot meal. Journal of Material Science and Chemical Engineering, 2014 (2):16-25.
|
[3] |
Geraldo Eduardo Gonçalves, Graziella Pacheco, Modestino Alves de Moura Brito, Sérgio Luiz Cabral da Silva. Influence of magnesia in the infiltration of magnesia-spinel refractory bricks by different clinkers. Revista Escola de Minas, 2015, 68(4):409-415.
DOI
URL
|
[4] |
Zongqi Guo, Stefan Palco, Michel Rigaud. Reaction characteristics of magnesia-spinel refractories with cement clinker. International Journal of Applied Ceramic Technology, 2005, 2(4):327-335.
DOI
URL
|
[5] |
D. Kitaguchi, M. Ono, Y. Tsuchiya, E. Nakajima, Y. Kalita. New chrome free brick for the burning zone of cement rotary kilns. Proceedings of UNITECR 2011, Kyoto, Japan, 2011:2-B2-3.
|
[6] |
Bhagiratha Mishra, Nilachal Sahoo, Jai Narayan Tiwari, Suvash Chandra Swain. Development of improved quality magnesia alumina spinel brick for cement rotary kilns. Proceedings of UNITECR 2009, Salvador, Brazil.
|
[7] |
H. Harmuth, K. Tschegg E. Tschegg. A fracture mechanics approach for the development of refractory materials with reduced brittleness. Fatigue & Fracture of Engineering Materials and Structures, 1997, 20(11):1585-1603.
|
[8] |
M. Geith, S. Jörg, R. Krischanitz. Influence of flexibilisers on basic cement rotary kiln brick properties. Proceedings of UNITECR 2017, Santiago, Chile, 2017:74-77.
|
[9] |
M. Geith, S. Jörg, R. Krischanitz. Hybrid spinel technology—basic refractories for cement rotary kiln linings with optimized flexibility. Proceedings of UNITECR 2019, Yokohama, Japan, 2019:242-245.
|