Influence mechanism of initial mechanical damage on concrete permeability and tunnel lining leakage

IF 4.7 2区 工程技术 Q1 MECHANICS Engineering Fracture Mechanics Pub Date : 2024-09-30 DOI:10.1016/j.engfracmech.2024.110531
Chenyang Zhao , Mingfeng Lei , Chaojun Jia , Chaoguang Wu , Zihan Yang , Yuanbo Shi
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Abstract

The stress state is not effectively considered in existing studies when researching the permeability evolution of concrete with initial mechanical damages, causing ambiguity in the influence mechanism of initial mechanical damage on tunnel lining leakage. This deficiency can lead to significant uncertainty in predicting the probability and evaluating the consequences of tunnel leakage diseases, further affecting the formulation of relevant prevention strategies. Therefore, mechanical damage is induced to concrete specimens by subjecting them to certain stress levels, and triaxial compression seepage tests are subsequently conducted to study the influence of initial mechanical damage on permeability evolution and macrocracks. Furthermore, the relationship between microcrack characteristics and concrete permeability is studied, ultimately revealing the influence mechanism of initial mechanical damage on tunnel lining leakage. Research results indicate that the concrete permeability decreases first, becomes stable, and then continuously increases during testing, and is positively related to changes in horizontal deformation ratio. When the damage-inducing stress reaches 80% of the uniaxial compressive strength (UCS), the impact of initial mechanical damage on concrete permeability increases significantly. The increase in initial mechanical damage can lead to a significant rise in permeability, even when the crack volume is in a compacted state. Additionally, cracks on the surface of the specimen become clearly visible when the test terminates, once the damage-inducing stress reaches 85% UCS. Two factors contribute to the gradual increase in concrete permeability with the rise in initial damage-inducing stress. Firstly, microcracks inside the concrete gradually widen and propagate. Secondly, the microcracks resulting from the initial damage progressively enlarge due to water pressure during the triaxial compression seepage test. Influenced by the blockage of seepage channels, concrete permeability can occasionally decrease during testing. The accidental load induces the gradual propagation of microcracks inside the mechanically damaged concrete. Then, the rebound deformation of concrete after the removal of the accidental load causes the closed microcracks to reopen significantly, leading to an increase in permeability and subsequent tunnel lining water leakage.
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初始机械损伤对混凝土渗透性和隧道衬砌渗漏的影响机理
现有研究在研究初始力学损伤混凝土渗透性演变时,并未有效考虑应力状态,导致初始力学损伤对隧道衬砌渗漏影响机理的模糊性。这一缺陷会给隧道渗漏病害的概率预测和后果评估带来很大的不确定性,进一步影响相关防治策略的制定。因此,通过对混凝土试件施加一定的应力水平,诱导其产生机械损伤,然后进行三轴压缩渗流试验,研究初始机械损伤对渗透性演变和大裂缝的影响。此外,还研究了微裂缝特征与混凝土渗透性之间的关系,最终揭示了初始机械损伤对隧道衬砌渗漏的影响机理。研究结果表明,在试验过程中,混凝土渗透率先降低、稳定后持续上升,并与水平变形比的变化呈正相关。当损伤诱导应力达到单轴抗压强度(UCS)的 80% 时,初始机械损伤对混凝土渗透性的影响显著增加。即使裂缝体积处于密实状态,初始机械损伤的增加也会导致渗透率显著上升。此外,当破坏应力达到 85% UCS 时,试验结束时试样表面的裂缝会变得清晰可见。有两个因素导致混凝土渗透性随着初始破坏诱导应力的增加而逐渐增加。首先,混凝土内部的微裂缝会逐渐扩大和扩展。其次,在三轴压缩渗水试验中,由于水压的作用,初始破坏产生的微裂缝逐渐扩大。受渗水通道堵塞的影响,混凝土的渗透性在试验过程中偶尔会降低。意外荷载会导致机械损伤混凝土内部的微裂缝逐渐扩展。然后,事故荷载移除后混凝土的回弹变形会使闭合的微裂缝重新明显打开,从而导致渗透性增加,进而造成隧道衬砌渗漏水。
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来源期刊
CiteScore
8.70
自引率
13.00%
发文量
606
审稿时长
74 days
期刊介绍: EFM covers a broad range of topics in fracture mechanics to be of interest and use to both researchers and practitioners. Contributions are welcome which address the fracture behavior of conventional engineering material systems as well as newly emerging material systems. Contributions on developments in the areas of mechanics and materials science strongly related to fracture mechanics are also welcome. Papers on fatigue are welcome if they treat the fatigue process using the methods of fracture mechanics.
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