Xianfeng Wang scite author profile

Abstract:The recovery behavior for strength and impermeability of cementitious composites embedded with organic microcapsules was investigated in this study. Mortar specimens were formed by mixing the organic microcapsules and a catalyst with cement and sand. The mechanical behaviors of flexural and compression strength were tested. The results showed that strength could increase by up to nine percent with the addition of a small amount of microcapsules and then decrease with an increasing amount of microcapsules. An orthogonal test for investigating the strength recovery rate was designed and implemented for bending and compression using the factors of water/cement ratio, amount of microcapsules, and preloading rate. It is shown that the amount of microcapsules plays a key role in the strength recovery rate. Chloride ion permeability tests were also carried out to investigate the recovery rate and healing effect. The initial damage was obtained by subjecting the specimens to compression. Both the recovery rate and the healing effect were nearly proportional to the amount of microcapsules. The obtained cementitious composites can be seen as self-healing owing to their recovery behavior for both strength and permeability.

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Effect of nano-SiO2 on strength, shrinkage and cracking sensitivity of lightweight aggregate concrete

Wang

Huang

et al. 2018

Construction and Building Materials

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Mechanical experiment evaluation of the microvascular self-healing capability of bitumen using hollow fibers containing oily rejuvenator

Guo

Xie

et al. 2019

Construction and Building Materials

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Evaluation of the mechanical performance recovery of self-healing cementitious materials – its methods and future development: A review

Wang

Yang

Fang

et al. 2019

Construction and Building Materials

106

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A novel capsule-based self-recovery system with a chloride ion trigger

Xiong

Tang

Zhu

et al. 2015

Sci Rep

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Steel is prone to corrosion induced by chloride ions, which is a serious threat to reinforced concrete structures, especially in marine environments. In this work, we report a novel capsule-based self-recovery system that utilizes chloride ions as a trigger. These capsules, which are functionalized via a smart response to chloride ions, are fabricated using a silver alginate hydrogel that disintegrates upon contact with chloride ions, and thereby releases the activated core materials. The experimental results show that the smart capsules respond to a very low concentration of chloride ions (0.1 wt%). Therefore, we believe that this novel capsule-based self-recovery system will exhibit a promising prospect for self-healing or corrosion inhibition applications.

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Xianfeng Wang

Experimental Study on Cementitious Composites Embedded with Organic Microcapsules

Effect of nano-SiO2 on strength, shrinkage and cracking sensitivity of lightweight aggregate concrete

Mechanical experiment evaluation of the microvascular self-healing capability of bitumen using hollow fibers containing oily rejuvenator

Evaluation of the mechanical performance recovery of self-healing cementitious materials – its methods and future development: A review

A novel capsule-based self-recovery system with a chloride ion trigger

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