Abstract
The previous researches on the degradation process of concrete under sulfate attack mainly focus on non-damaged concrete. It may lead to an excessive evaluation of the durability of the structure, which is detrimental to the safety of the structure. In this paper, three different damage degrees of concrete specimens with non-damaged (D0) and initial damage of 10% (D1) and 20% (D2) were prefabricated and subjected to sulfate attack and wetting–drying cycles. With the increase of sulfate attack cycles (0, 30, 60, 90, 120, 150 cycles), the changes in mass loss, relative dynamic modulus of elasticity, and the stress–strain curve were studied. The results show that the mass of the D0 specimen had been increasing continuously before 150 sulfate attack cycles. The mass of D1 and D2 had been increasing before 60 cycles, and decreasing after 60 cycles. At 150 cycles, the mass loss of D0, D1, D2 were − 1.054%, 0.29% and 3.20%, respectively. The relative dynamic modulus of elasticity (RDME) of D0 specimen increases continuously before 90 sulfate attack cycles. After 90 cycles, the RDME gradually decreases. However, for D1 and D2 specimens, the RDME began to decrease after 30 cycles. The damage degree has an obvious influence on the compressive strength and elastic modulus. For the D0 specimen, the compressive strength and elastic modulus increased continuously before 90 cycles and decreased after 90 cycles. The compressive strength and elastic modulus of D1 and D2 specimens began to decrease after 30 cycles. The stress–strain curves of concrete with different initial damage degrees were established, and the fitting results were good. Finally, based on the analysis of experimental data, the degradation mechanism of concrete with initial damage under the sulfate wetting–drying cycle was discussed.
Highlights
Concrete is the most important building material in the world, widely used in coastal engineering and inland saline areas (Sun et al 2013; Idiart et al 2011)
The results showed that the fatigue loading and drying–wetting cycles can accelerate the transportation of sulfate ion inside the concrete and the deterioration degree of concrete subjected to sulfate
3.1 Surface Characteristics of Sulfate‐Attacked Concrete Figure 3 presents the appearance of concrete with different initial damage degrees in different sulfate attack periods
Summary
Concrete is the most important building material in the world, widely used in coastal engineering and inland saline areas (Sun et al 2013; Idiart et al 2011). Existing studies have shown that sulfate ions have corrosive effects and lead to degradation of concrete durability (Gao et al 2013; Thaulow and Sahu 2004); (Helson et al 2018) studied the durability potential of different soil–cement mixtures, and defined the critical thresholds relative to clay and cement content. They found that mechanical damage was the result of microcracking and ettringite expansion. Rozier et al (2009) found that leaching and external sulfate attack of concrete would lead to
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