High-temperature performance of mortars and concretes based on alkali-activated slag/metakaolin blends

S. A. Bernal; R. Mejía de Gutiérrez; F. Ruiz; H. Quiñones; J. L. Provis

doi:10.3989/mc.2012.01712

Autores/as

S. A. Bernal Universidad del Valle - University of Melbourne
R. Mejía de Gutiérrez Universidad del Valle
F. Ruiz Universidad del Valle
H. Quiñones Universidad del Valle
J. L. Provis University of Melbourne

DOI:

https://doi.org/10.3989/mc.2012.01712

Palabras clave:

cementos alcalinos, altas temperaturas, escoria siderúrgica, metacaolín, propiedades mecánicas

Resumen

Este artículo evalúa el desempeño de morteros y hormigones basados en mezclas de escoria siderúrgica (GBFS)/metacaolín (MK), activadas alcalinamente expuestos a temperaturas altas. Se identifica una elevada estabilidad en morteros con contenidos de MK de hasta un 60% cuando se exponen a temperaturas de 600 ºC, con una resistencia residual de 20 MPa posterior a la exposición a esta temperatura. Por otra parte, la exposición a temperaturas más elevadas conduce al agrietamiento de los hormigones como consecuencia de una elevada contracción de la matriz cementante y las restricciones por efecto de los áridos, especialmente en aquellos especímenes con cementantes que contienen altos contenidos de MK. Se identifican diferencias significativas en las propiedades de absorción de agua de morteros y hormigones, y esto se relaciona con las divergencias en el desempeño de estos materiales posterior a la exposición a temperaturas altas. Esto indica que el desempeño a temperaturas elevadas de morteros de activación alcalina no es completamente transferible a hormigones, ya que los sistemas difieren en permeabilidad. Las diferencias en los coeficientes de expansión térmica entre matriz cementante y los áridos gruesos contribuyen al macrofisuramiento del material y su consecuente reducción de propiedades mecánicas.

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Citas

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