The work proposes a cold-setting approach for designing and producing aluminosilicate refractories that save energy and emit low levels of CO2. This process is based on shrinkage-free theory and the management of the expansion coefficient of refractory oxides from natural raw materials. Refractory composites can be designed to withstand high temperatures and thermal gradients. Refractory matrices based on Al-rich kalsilite, mullite, tialite and mullite-cordierite are designed with alternative cold-setting processes to achieve the desired porosity for dense and porous refractories. The formation and consolidation mechanisms of cold-setting refractory matrices are presented, demonstrating the role of colloidal silica and alumina in partially replacing an alkali-based colloidal solution. The optimum microstructure was accounted for the improvement of refractoriness, shrinkage and thermal resistance.

Design of aluminosilicate refractory matrices in the context of climate change: sustainability approach / Kamseu, E., Veronesi, P., Djiogue, L.T.K., Djouda, J.M., Lancellotti, I., Colombini, E., Leonelli, C.. - In: CERAMICS INTERNATIONAL. - ISSN 0272-8842. - 52:16(2026), pp. 30327-30341. [10.1016/j.ceramint.2026.05.102]

Design of aluminosilicate refractory matrices in the context of climate change: sustainability approach

Kamseu E.
Writing – Original Draft Preparation
;
Veronesi P.
Project Administration
;
Lancellotti I.
Investigation
;
Colombini E.
Membro del Collaboration Group
;
Leonelli C.
Supervision
2026

Abstract

The work proposes a cold-setting approach for designing and producing aluminosilicate refractories that save energy and emit low levels of CO2. This process is based on shrinkage-free theory and the management of the expansion coefficient of refractory oxides from natural raw materials. Refractory composites can be designed to withstand high temperatures and thermal gradients. Refractory matrices based on Al-rich kalsilite, mullite, tialite and mullite-cordierite are designed with alternative cold-setting processes to achieve the desired porosity for dense and porous refractories. The formation and consolidation mechanisms of cold-setting refractory matrices are presented, demonstrating the role of colloidal silica and alumina in partially replacing an alkali-based colloidal solution. The optimum microstructure was accounted for the improvement of refractoriness, shrinkage and thermal resistance.
2026
52
16
30327
30341
Design of aluminosilicate refractory matrices in the context of climate change: sustainability approach / Kamseu, E., Veronesi, P., Djiogue, L.T.K., Djouda, J.M., Lancellotti, I., Colombini, E., Leonelli, C.. - In: CERAMICS INTERNATIONAL. - ISSN 0272-8842. - 52:16(2026), pp. 30327-30341. [10.1016/j.ceramint.2026.05.102]
Kamseu, E.; Veronesi, P.; Djiogue, L. T. K.; Djouda, J. M.; Lancellotti, I.; Colombini, E.; Leonelli, C.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11380/1411989
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