Damage evolution characteristics of freeze–thaw rock combined with CT image and deep learning technology

IF 3.7 2区工程技术 Q3 ENGINEERING, ENVIRONMENTAL

Bulletin of Engineering Geology and the Environment Pub Date : 2024-12-23 DOI:10.1007/s10064-024-04010-3

Hui Liu, Xinyue Dai, Gengshe Yang, Yanjun Shen, Pengzhi Pan, Jiami Xi, Borong Li, Bo Liang, Yao Wei, Huiqi Huang

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引用次数: 0

Abstract

The surrounding rock of tunnel engineering in an alpine mountainous environment is prone to frequent freeze–thaw action due to fissure water and temperature differential, which leads to crack propagation and even failure in rock. Freezing sandstone CT damage-free scanning studies were conducted. Based on deep learning theory, the U-Net network technique is utilized to naturally merge high-resolution properties of frozen rock CT images in the shrinking path with low-resolution characteristics in the expansion path. Intelligent detection of freezing rock fissures and geometric information parameters at the pixel level has been accomplished. The primary fracture structure and its parameters of the sandstone with natural damage during the freeze–thaw process are obtained, and the pixel-level intelligent identification of the meso-structure and geometric information parameters of the freeze–thaw rock fracture is realized. This justifies the classification of naturally cracked rock under load and freeze–thaw as a discrete time-dimensional evolution system. The dynamic process and mechanical characteristics of meso-damage propagation of naturally fractured rock under freeze–thaw and compression load are investigated using Casrock numerical computation software, which is based on the cellular automata theory. The results reveal that when the number of freeze–thaw cycles rises, the random rate of fracture network structure distribution increases, the uniformity of fracture distribution increases, and the dominating direction decreases. The sandstone's secondary fractures progressively increase as the fracture dominant angle rises, and the rock sample's failure mode eventually shifts from tensile failure to compression-shear mixed failure. When the comprehensive dominant angle of fracture is 60°, the fracture of freeze–thaw rock is more prone to expansion and its mechanical strength deteriorates more. The fractured rock creates narrow strip directional damage along the end of the original fracture when subjected to compressive load, exhibiting typical localization features. The main crack and the secondary crack dominate the crack progression. The number of secondary fractures inside sandstone steadily grows as the fracture's comprehensive dominant angle increases. The direction of the crack penetration development is determined by the comprehensive dominating angle of the fracture.

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结合CT图像和深度学习技术的冻融岩石损伤演化特征

高寒山地环境下的隧道工程围岩由于裂隙水和温差的作用，容易发生频繁的冻融作用，导致岩石裂纹扩展甚至破坏。进行了冻结砂岩CT无损伤扫描研究。基于深度学习理论，利用U-Net网络技术将冻土CT图像在收缩路径上的高分辨率特征与扩张路径上的低分辨率特征进行自然融合。实现了冻结岩体裂隙和几何信息参数在像素级的智能检测。获得了冻融过程中自然损伤砂岩的主裂缝结构及其参数，实现了冻融岩石裂缝细观结构和几何信息参数的像素级智能识别。这证明了自然破裂岩石在荷载和冻融作用下的分类是一个离散的时维演化系统。采用基于元胞自动机理论的Casrock数值计算软件，研究了冻融和压缩荷载作用下天然裂隙岩石细观损伤扩展的动态过程和力学特征。结果表明：随着冻融循环次数的增加，裂缝网络结构分布的随机率增加，裂缝分布的均匀性增加，主导方向降低；随着裂缝主导角的增大，砂岩的次生裂缝逐渐增多，岩样的破坏模式最终由拉伸破坏转变为压剪混合破坏。当裂缝综合主导角为60°时，冻融岩石的裂缝更容易膨胀，其机械强度更差。受压缩载荷作用时，裂隙沿原裂隙末端形成窄条状定向损伤，表现出典型的局部化特征。主裂纹和次裂纹主导裂纹的扩展。砂岩内部次生裂缝数量随着裂缝综合优势角的增大而稳步增加。裂缝贯通发展方向由裂缝综合支配角决定。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Bulletin of Engineering Geology and the Environment 工程技术-地球科学综合

CiteScore

7.10

自引率

11.90%

发文量

445

审稿时长

4.1 months

期刊介绍： Engineering geology is defined in the statutes of the IAEG as the science devoted to the investigation, study and solution of engineering and environmental problems which may arise as the result of the interaction between geology and the works or activities of man, as well as of the prediction of and development of measures for the prevention or remediation of geological hazards. Engineering geology embraces: • the applications/implications of the geomorphology, structural geology, and hydrogeological conditions of geological formations; • the characterisation of the mineralogical, physico-geomechanical, chemical and hydraulic properties of all earth materials involved in construction, resource recovery and environmental change; • the assessment of the mechanical and hydrological behaviour of soil and rock masses; • the prediction of changes to the above properties with time; • the determination of the parameters to be considered in the stability analysis of engineering works and earth masses.