Addition of sodium alginate capsules containing Lysinibacillus sphaericus for self-healing of cracks in mortars

Caroline Moraes da  Cruz; Sylma Carvalho Maestrelli; Silvana Marina Piccoli  Pugine; Alan Rodrigo Sorce; Eliana Cristina da Silva  Rigo

doi:10.33448/rsd-v12i3.40331

Autores/as

Caroline Moraes da Cruz Universidade de São Paulo https://orcid.org/0000-0001-5712-4766
Sylma Carvalho Maestrelli Universidade Federal de Alfenas https://orcid.org/0000-0002-5037-4276
Silvana Marina Piccoli Pugine Universidade de São Paulo https://orcid.org/0000-0002-9563-1088
Alan Rodrigo Sorce Universidade de São Paulo https://orcid.org/0000-0003-2370-9218
Eliana Cristina da Silva Rigo Universidade de São Paulo https://orcid.org/0000-0003-3368-5707

DOI:

https://doi.org/10.33448/rsd-v12i3.40331

Palabras clave:

Argamasa; Fisuras; Bacterias; Biomineralización; Alginato de sodio; Esferificación.

Resumen

La técnica de biomineralización para la remediación de grietas en morteros de construcción se puede realizar incorporando bacterias calcificantes a la matriz del mortero. La contracción térmica y autógena asociada con la hidratación del cemento puede ser perjudicial para la supervivencia de las esporas bacterianas. La encapsulación de las esporas en una matriz como los hidrogeles superabsorbentes, específicamente el alginato de sodio, puede brindar protección contra estas condiciones nocivas, además de servir como reservorio de agua para la actividad metabólica de las células bacterianas. Este trabajo investigó la adición de cápsulas de alginato de sodio preparadas por esferificación en morteros de construcción, con el objetivo de preservar y optimizar las propiedades reológicas, físicas y mecánicas y liberar bacterias cuando se producen fisuras. Las formulaciones de mortero con cápsulas con Lysinibacillus sphaericus se calcularon para mantener la distribución granulométrica de la formulación estándar, obteniendo así productos con excelentes propiedades reológicas, físicas y mecánicas, y permitiendo la adición de hasta un 1% de cápsulas. Se aplicó análisis de varianza multivariante en cada edad, demostrando que las formulaciones mantuvieron las mismas propiedades que la fórmula original. Luego de la formación de grietas, se pudo observar la acción de las bacterias liberadas, a través de la formación de estructuras cristalinas en las grietas. Las cápsulas se prepararon mediante un proceso sencillo y económico; además, su adición no afectó las propiedades del hormigón y protegió eficazmente a las bacterias tanto durante la mezcla y el endurecimiento como en el desprendimiento después de la fisuración.

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Adición de cápsulas de alginato de sodio que contienen Lysinibacillus sphaericus para la autocuración de grietas en morteros

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