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超高性能混凝土(UHPC)因其优异的力学性能和耐久性已得到广泛应用。然而带有裂缝的UHPC结构在冻融循环作用下的长期服役性能仍存在安全隐患。当前研究多聚焦于无损UHPC,针对已产生损伤的UHPC在冻融作用下的性能退化机制仍缺乏系统研究。本工作系统探讨了冻融循环条件下裂后UHPC的拉伸性能演化机制。通过预拉伸试验使试件产生初始裂缝,经历不同次数的冻融循环或不同龄期的水浴养护后,对试件开展二次拉伸试验直至其破坏。结果表明:水浴养护显著促进了UHPC的力学性能恢复,形成的水化产物如水化硅酸钙凝胶和氢氧化钙,有效填补了裂缝,提升了基体的密实性,达到了自愈合效果。在冻融循环的初期,UHPC的裂缝愈合效果较为显著,但在经过300次循环后,裂缝扩展和基体劣化加剧,导致力学性能显著下降。此外,通过单纤维拔出试验揭示了界面粘结性能的变化规律,微观测试进一步分析了二次水化和碳化反应在UHPC冻融过程中的作用机理。
Abstract:Introduction Ultra-High Performance Concrete(UHPC) is widely recognized for its exceptional mechanical properties and durability, making it a cornerstone material in modern infrastructure projects. However, the long-term service performance of UHPC structures with initial cracks under freeze–thaw(F–T) cycling remains a safety concern, particularly in harsh environments such as cold regions and coastal zones. While extensive research has focused on the properties of uncracked UHPC, the study on degradation of cracked UHPC under coupled F–T cycling and self-healing conditions is limited. Existing studies highlight UHPC's intrinsic self-healing potential through secondary hydration and carbonation reactions, yet the interplay between these healing mechanisms and cyclic F–T-induced deterioration remains unclear. To address this, the present study investigates the tensile performance evolution of pre-cracked UHPC under F–T cycling and water-curing conditions. By integrating macroscopic mechanical tests with microscopic analyses, this work aims to unravel the dual effects of self-healing and F–T-induced damage on UHPC's structural integrity. Methods UHPC specimens were prepared using white cement, silica fume, quartz powder/sand, steel fibers(2% by volume), and a polycarboxylate superplasticizer. The mix design followed a water-to-binder ratio of 0.22. After casting and demolding, specimens underwent 48 h hot-water curing at 90 ℃. Dog-bone-shaped specimens(30 mm×13 mm×80 mm) were pre-notched and subjected to pre-tensioning to introduce controlled initial cracks(100 μm width) via displacement-controlled loading. Pre-cracked specimens were divided into two groups, including 1) F–T cycling groups: Exposed to 100, 200, or 300 F–T cycles(-17 ℃ to 8 ℃ per cycle); 2) water-curing groups: immersed in 20 ℃ water for 14, 30 d, or 60 d. Secondary tensile tests were conducted to evaluate residual strength and crack recovery. Single-fiber pull-out tests assessed interfacial bond performance, while scanning electron microscopy(SEM) and thermogravimetric analysis(TGA) characterized microstructural evolution and hydration products. Results and discussion Water-cured specimens exhibited remarkable mechanical recovery. After 60 d, tensile strength exceeded the undamaged control group by 32%, attributed to C-S-H gel and Ca(OH)2 filling microcracks. SEM revealed dense microstructures with nearly closed cracks, confirming the role of secondary hydration in enhancing matrix integrity. Single-fiber pull-out tests showed interfacial bond strength fully recovered within 30 d, though prolonged immersion led to steel fiber corrosion, reducing post-peak ductility. F–T cycling initially promoted low-temperature self-healing. After 200 cycles, tensile strength increased by 14% due to partial crack closure via hydration. However, beyond 300 cycles, cumulative damage dominated: surface spalling, fiber corrosion, and interfacial debonding caused a 7.1% decline in tensile strength. TGA confirmed reduced Ca(OH)2 and CaCO3 content under F–T conditions, indicating suppressed hydration and carbonation compared to water curing. Progressive densification of the matrix with crystalline hydration products sealing cracks. Initial healing at 100–200 F–T cycles was counteracted by interfacial microcrack propagation and fiber-matrix debonding at 300 cycles. EDS analysis highlighted localized CaCO3 precipitation at crack surfaces, insufficient to offset F–T-induced damage. The study revealed a critical threshold(200 F–T cycles) where self-healing and deterioration mechanisms compete. While water ingress facilitates secondary hydration, prolonged F–T exposure disrupts the healing process through ice crystallization pressure and moisture redistribution, exacerbating matrix degradation. Conclusions Water curing significantly enhances UHPC's self-healing capacity, with complete tensile strength recovery, which was driven by continuous secondary hydration and carbonation, forming dense, crack-resistant matrices. Freeze–thaw cycling exhibited a dual role: healing occurred at early stages(≤200 cycles), but 300 cycles led to irreversible strength loss. Microstructural analysis underscored the importance of hydration products(C-S-H, CaCO3) in healing cracks, while F–T cycling disrupts interfacial bonding and accelerates matrix spalling. For UHPC structures in cold climates, proactive crack sealing and controlled curing are essential to maximize self-healing benefits before F–T damage accumulates. Future work should explore hybrid curing regimes and corrosion-resistant fibers to extend service life.
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基本信息:
DOI:10.14062/j.issn.0454-5648.20240714
中图分类号:TU528
引用信息:
[1]林勋,赵梦佳,陈璨,等.裂后超高性能混凝土在冻融循环下拉伸性能演化[J].硅酸盐学报,2025,53(05):1236-1246.DOI:10.14062/j.issn.0454-5648.20240714.
基金信息:
国家自然科学基金(52278245); 中央高校基本科研业务费(2242023R40006)
2025-03-24
2025-03-24
2025-03-24