4.7 Article

Self-compacting concrete containing coarse recycled precast-concrete aggregate and its durability in marine-environment-related tests

Journal

CONSTRUCTION AND BUILDING MATERIALS
Volume 377, Issue -, Pages -

Publisher

ELSEVIER SCI LTD
DOI: 10.1016/j.conbuildmat.2023.131084

Keywords

Recycled precast -concrete aggregate; Self -compacting concrete; Marine environment; Capillary water absorption; Carbonation; Moist; dry test

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This study evaluates the performance of Self-Compacting Concrete (SCC) with different contents of coarse Recycled Precast-Concrete Aggregate (RPCA) and two cement contents under marine conditions. The results show that SCC with adequate durability under marine conditions can be produced. The addition of RPCA reduces water absorption and SCC carbonation, but leads to greater weight variations due to reactions with chlorides, sulfates, and salt deposition. However, SCC compressive strength is not adversely affected, and the projected service life of all mixes is over 100 years, making SCC a feasible option for construction in marine environments.
Marine environments are extremely challenging for the long-term durability of concrete. Prior validation of concrete durability is therefore a prerequisite to guarantee its adequate performance under marine environmental conditions. In this study, the performance of Self-Compacting Concrete (SCC) with variable contents of coarse Recycled Precast-Concrete Aggregate (RPCA) and two different cement contents is assessed in terms of capillary water absorption, natural and accelerated carbonation, resistance to SO2 attack, and moist/dry performance in drinking water, marine water, and sulfate water. These tests are intended to simulate the conditions of a marine environment. In general, the results showed that an SCC containing coarse RPCA of adequate durability under marine conditions could be produced. On the one hand, porosity due to the presence of RPCA increased less as the cement content was increased, which in turn reduced water absorption and SCC carbonation. For example, the effective porosity of the SCC was reduced by 25 % between day 28 and day 180, following the addition of 100 % coarse RPCA. On the other hand, both the SO2-attack and the moist/dry tests revealed that the weight of the SCC with RPCA underwent greater variations, due to the reactions of the cementhydration products with chlorides and sulfates, as well as salt deposition. However, SCC compressive strength was never adversely affected, as the concrete strength increased up to 8 MPa after the drinking-water and the sulfate-water moist/dry tests when using RPCA. According to both Fick's and Parrot's models, the projected service life of all the mixes was over 100 years, regardless of the coarse RPCA content, making this sort of SCC a feasible option for construction in marine environments.

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