Roberto Luiz Dias scite author profile

Roberto Luiz Dias

5Publications

1Citation Statement Received

97Citation Statements Given

How they've been cited

How they cite others

143

Affiliations

Federal University of Paraná

Publications

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Influência do silicato de sódio neutro na degradação de pastas de cimento Portland submetidas ao ataque por ácido sulfúrico

Dobrovolski

Munhoz

Nenevê

et al. 2019

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Visto que as instalações de tratamento de águas servidas estão sujeitas à corrosão induzida por micro-organismos devido ao ataque por ácido sulfúrico (H2SO4), esse estudo buscou testar o silicato de sódio neutro (Na2SiO3) como solução mitigadora do ataque ácido em pastas de cimento Portland. Foram moldados corpos de prova com diferentes teores de adição de Na2SiO3 (0%, 1%, 5% e 10%) e substituição de 35% do cimento Portland CP-V ARI por cinza volante classe C. Por fim, as amostras imersas em solução contendo H2SO4 foram comparadas com as amostras imersas em água saturada com cal. Nos resultados observou-se que a absorção de água e o índice de vazios dependeram do desenvolvimento da microestrutura e da velocidade da reação do cimento com o H2SO4, expresso pela recombinação química entre os íons sulfato e a portlandita. A degradação microestrutural foi comprovada com as análises de FT-IR.

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Preliminary study of the effect of carbonation curing on geopolymers

Beltrame

Medeiros-Junior

Dias

et al. 2024

Rev. IBRACON Estrut. Mater.

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Carbonation curing differs from weathering carbonation since it is performed intentionally at the early ages of cement hydration. This cure involves applying different levels of CO2 (5% to 99%) to concrete for a short period of time, usually followed by conventional hydration. The objective of this article was to evaluate the carbonation curing in metakaolin-based geopolymer concretes, activated with NaOH and Na2SiO3, and compare them with Portland cement (PC) concrete. The following tests were applied: determination of pH, carbonation depth, water absorption by immersion, void index, and compressive strength. The results showed that after the carbonation curing, the geopolymer concrete had compressive strength and carbonation depth equivalent to the concrete with PC, but with a lower absorbed CO2 content. Although this type of cement absorbs less CO2 but is more sensitive to carbonation. The effect on the void ratio was not remarkable. Furthermore, the alkalinity of concretes can be partially recovered after subsequent curing by water immersion.

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Ataque externo por ácido sulfúrico em pastas de cimento dosadas com silicato de sódio alcalino

Nenevê

Dias²,

Dobrovolski

et al. 2019

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Dentre os ataques mais severos às matrizes cimentícias, destaca-se o decorrente do ácido sulfúrico (H2SO4), que pode desenvolver-se em sistemas de coleta de esgoto. Para tanto, os agentes cristalizantes são capazes de trazer resultados positivos quanto à durabilidade através da redução da permeabilidade. Portanto, o presente artigo investigou a influência da adição de silicato de sódio alcalino em pastas de cimento exposta ao ataque por ácido sulfúrico. Fez-se uso de cimento CP V-ARI, cinza volante e superplastificante como demais materiais da mistura. Empregaram-se ensaios para avaliação de índice de vazios, absorção de água e FT-IR. Os resultados mostraram que o teor de adição de silicato de sódio alcalino e o ambiente de exposição influenciaram as características das amostras. As pastas com adição de silicato de sódio alcalino apresentaram menor degradação sob o ponto de vista dos ensaios de índice de vazios e absorção de água. O FT-IR evidenciou a formação dos produtos oriundos da degradação pelo ataque ácido. Palavras-chave: Ataque ácido; Silicato de sódio alcalino; Pasta de cimento.

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Effect of duration and pressure of carbonation curing on the chloride profile in concrete

Dias

Beltrame

Gonzalez

et al. 2023

Rev. IBRACON Estrut. Mater.

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Carbonation curing alters the characteristics of the concrete's microstructure and can interfere with the penetration of aggressive ions. The objective of this article was to evaluate the influence of CO2 pressure and carbonation cure time on chloride profiles. Concrete specimens were cured by carbonation with CO2 pressures ranging from 5 to 25 Psi, for a time within the carbonation chamber of 8, 24, and 36 hours. These concretes were subjected to 30 wetting and drying cycles in NaCl solution to stimulate the chloride ingress. The carbonation depth and the microstructure of the concrete were monitored over time. Chloride profiles were obtained and modeled by 4 mathematical equations. The results showed that the combination of less time and CO2 pressure during carbonation curing potentiated the reduction of chloride penetration in concrete. Also, the carbonation curing conditions of 5 and 10 Psi for 8 hours reduced the chloride diffusion coefficient.

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The influence of fly ash and neutral sodium silicate on concretes submitted to sulfuric acid attack

Munhoz

Dobrovolski

Nenevê

et al. 2022

Engineering Failure Analysis

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