Efeito do teor de água e tamanho de partícula na decomposição térmica de pastas de cimento moídas

Menezes, Raquel Maria Rocha Oliveira; Costa, Leonardo Martins; Tavares, Ludmila Rodrigues Costa; Bezerra, Augusto César da Silva; Aguilar, Maria Teresa Paulino

doi:10.1590/s1517-707620200001.0888

Cited by 1 publication

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“…First, as previously indicated, pozzolans can physically and chemically interact with hydrated cement, provide pore refinement and increase the density of the cementitious matrix microstructure (Fig. 7) 12,80,113,114 . This effect hinders the diffusion of carbon dioxide (CO 2 ) into the remaining pore solution 26 and explains the improvement in electrical resistance and water absorption in the RC composite.…”

Section: Volumetric Electrical Resistancementioning

confidence: 74%

Influence of quartz powder and silica fume on the performance of Portland cement

Tavares

Costa

et al. 2020

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Supplementary cementitious materials interact chemically and physically with cement, influencing the formation of hydrate compounds. Many authors have analyzed the filler and pozzolanic effect. However, few studies have explored the influence of these effects on hydration, properties in the fresh and hardened states, and durability parameters of cementitious composites separately. This study investigates the influence of the replacement of 20% of Portland cement for silica fume (SF) or a 20-µm medium diameter quartz powder (QP) on the properties of cementitious composites from the first hours of hydration to a few months of curing. The results indicate that SF is pozzolanic and that QP has no pozzolanic activity. The use of SF and QP reduces the released energy at early times to the control paste, indicating that these materials reduce the heat of hydration. The microstructure with fewer pores of SF compounds indicates that the pozzolanic reaction reduced pore size and binding capability, resulting in equivalent mechanical properties, reduced permeability and increased electrical resistance of the composites. SF and QP increase the carbonation depth of the composites. SF and QP composites are efficient in the inhibition of the alkali-aggregate reaction. The results indicate that, unlike the filler effect, the occurrence of pozzolanic reaction strongly influences electrical resistance, reducing the risk of corrosion of the reinforcement inserted in the concrete.

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