Investigation on effect of colloidal nano-silica on the strength and durability characteristics of red mud blended Portland cement paste through tortuosity

K.  Athira; T.  Shanmugapriya

doi:10.3989/mc.2022.01922

Autores/as

K. Athira School of Civil Engineering, VIT https://orcid.org/0000-0002-5772-3619
T. Shanmugapriya School of Civil Engineering, VIT https://orcid.org/0000-0003-1565-152X

DOI:

https://doi.org/10.3989/mc.2022.01922

Palabras clave:

Porosidad, Distribución de la estructura porosa, Tortuosidad, Resistencias mecánicas, Durabilidad

Resumen

En este estudio se presenta un nuevo sistema aglomerante para compuestos en base cemento que depende de las características de resistencia y durabilidad. Se evalúa la posibilidad de incluir pastas de cemento de lodo rojo calcinado con y sin nanosílice coloidal (CNS) en pastas de cemento Portland ordinario (OPC) en tres relaciones a/b (0,3, 0,4, 0,5). El porcentaje óptimo de reemplazo de cemento por lodo rojo (15 %) se seleccionó de los valores de resistencia a la compresión obtenidos entre los diferentes reemplazos de cemento considerados (5 %, 10 %, 15 % y 20 %). Se añadió nanosílice coloidal (CNS) al 0,5 %, 1 %, 1,5 % y 2 % a la pasta de cemento de lodo rojo seleccionada. Se realizaron pruebas de absorción de agua, sorción, resistencia al ataque de sulfatos y resistencia al ataque de ácidos para obtener una pasta de cemento de lodo rojo óptima con y sin CNS. Los resultados experimentales se explican basados en parámetros de tortuosidad con fórmulas empíricas y modelos matemáticos de distribución de redes de poros. La tortuosidad es directamente proporcional a la interconectividad de los poros. Las mezclas con 15% de lodo rojo calcinado y 1,5% de reemplazo de CNS presentaron mejor resistencia y durabilidad en todas las relaciones a/b. En la mezcla (R15NS1.5) con un valor mínimo de tortuosidad se obtiene el mayor rendimiento general de la pasta. Las mezclas con una relación a/b de 0,3 generan una pasta de cemento de alto rendimiento en comparación con relaciones a/b más altas.

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