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热塑性微胶囊对石灰石煅烧粘土水泥混凝土抗硫酸盐性能及自修复性能的影响研究

Study on the Influence of Thermoplastic Microcapsules on the Sulfate Resistance and Self-Healing Performance of Limestone Calcined Clay Cement Concrete.

作者信息

Du Wei, Jiang Lu, Liu Quantao, Chen Wei, Ding Qingjun

机构信息

Hubei Provincial Engineering Research Center of Industrial Detonator Intelligent Assembly, Wuhan Textile University, Wuhan 430073, China.

School of Materials Science and Engineering, Wuhan Textile University, Wuhan 430200, China.

出版信息

Molecules. 2024 Oct 10;29(20):4797. doi: 10.3390/molecules29204797.

DOI:10.3390/molecules29204797
PMID:39459166
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11510000/
Abstract

Limestone calcined clay cement (LC3), enhanced through reactions with volcanic ash and the interaction between limestone and clay, significantly improves the performance of cementitious materials. It has the potential to cut CO emissions by up to 30% and energy consumption in cement manufacture by 15% to 20%, providing a promising prospect for the large-scale production of low-carbon cement with a lower environmental effect. To effectively manufacture LC3 concrete, this study utilized limestone (15%), calcined clay (30%), and gypsum (5%) as supplementary cementitious materials (SCMs), replacing 50% of ordinary Portland cement (OPC). However, in regions abundant in sulfate, sulfate attack can cause interior cracking of concrete, reducing the longevity of the building. To address this issue, microcapsules containing microcrystalline wax, ceresine wax, and nano-CaCO encapsulated in epoxy resin were prepared and successfully incorporated into LC3 concrete. Sulfate resistance tests were conducted through sulfate dry-wet cycles, comparing samples with and without microcapsules. The findings revealed that the initial mechanical and permeability properties of LC3 concrete did not significantly differ from OPC concrete. LC3 concrete with added microcapsules (SP4) exhibited enhanced resistance to sulfate attack, reducing mass loss and compressive strength degradation. SEM images displayed a mesh-like structure of repair products in SP4. After 14 days of self-repair, SP4 exhibited a 44.2% harmful pore ratio, 98.1% compressive strength retention, 88.7% chloride ion diffusion coefficient retention, 91.12 mV maximum amplitude, and 9.14 mV maximum frequency amplitude. The experimental results indicate that the presence of microcapsules enhances the sulfate attack self-healing performance of LC3 concrete.

摘要

石灰石煅烧黏土水泥(LC3)通过与火山灰的反应以及石灰石与黏土之间的相互作用得到增强,显著改善了胶凝材料的性能。它有潜力将水泥生产中的二氧化碳排放量削减多达30%,并将能源消耗降低15%至20%,为大规模生产环境影响较小的低碳水泥提供了广阔前景。为有效制备LC3混凝土,本研究使用石灰石(15%)、煅烧黏土(30%)和石膏(5%)作为辅助胶凝材料(SCMs),替代了50%的普通硅酸盐水泥(OPC)。然而,在硫酸盐丰富的地区,硫酸盐侵蚀会导致混凝土内部开裂,缩短建筑物的使用寿命。为解决这一问题,制备了包裹在环氧树脂中的含有微晶蜡、地蜡和纳米碳酸钙的微胶囊,并成功将其掺入LC3混凝土中。通过硫酸盐干湿循环进行抗硫酸盐试验,对比有和没有微胶囊的样品。研究结果表明,LC3混凝土的初始力学性能和渗透性与OPC混凝土没有显著差异。添加微胶囊的LC3混凝土(SP4)表现出增强的抗硫酸盐侵蚀能力,减少了质量损失和抗压强度退化。扫描电子显微镜图像显示SP4中有修复产物的网状结构。自修复14天后,SP4的有害孔隙率为44.2%,抗压强度保留率为98.1%,氯离子扩散系数保留率为88.7%,最大振幅为91.12毫伏,最大频率振幅为9.14毫伏。实验结果表明,微胶囊的存在增强了LC3混凝土的抗硫酸盐侵蚀自修复性能。

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