初始损伤对砂岩力学性能劣化的影响机制研究

doi:10.3724/1000-6915.jrme.2025.0328

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摘要深部开挖会在围岩中诱发不同程度的初始损伤，进而影响其承载能力与变形特性，但传统强度准则难以定量反映该类损伤效应。为揭示初始损伤对砂岩力学性能的劣化机制，并构建可用于工程预测的改进强度准则，首先通过单轴增量循环加卸载试验制备不同损伤等级试样，并结合三轴压缩试验获取峰值强度、变形模量及抗剪强度参数的演化规律；同时基于PFC2D模拟裂纹萌生–扩展–贯通过程，从细观尺度阐明损伤导致强度弱化的内在机制；进一步根据损伤对Hoek-Brown参数m，s的分阶段影响，建立损伤–参数的定量关系，并将其嵌入广义Hoek-Brown准则中，形成可描述初始损伤效应的改进强度预测方法。研究表明，初始损伤使砂岩峰值强度与刚度呈指数衰减，而泊松比随之升高，且损伤效应具有明显的围压依赖性；裂纹网络的重构与弱化是造成宏观力学性能劣化的根本原因，高围压可通过抑制张性裂纹扩展并促进摩擦滑移显著延缓破坏；改进的Hoek-Brown准则能够准确反映不同损伤水平下的强度折减特征。工程应用验证显示，该方法在围岩变形预测中的精度优于传统准则。该研究为开挖诱导损伤岩体的强度折减分析提供了新的定量化途径，对深部地下工程的稳定性评价与支护优化具有重要参考价值。

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	晏启祥1
	贺文城1
	刘瑞琦1
	孙明辉1
	2*
	杨潇3

关键词 ：岩石力学, 初始损伤, 砂岩, 损伤劣化机制, 离散元模拟, Hoek-Brown准则改进

Abstract：Deep underground excavation inevitably induces varying degrees of initial damage to the surrounding rock, significantly altering its load-bearing capacity and deformation behavior. However, conventional strength criteria are insufficient for quantitatively characterizing these damage effects. This study aims to elucidate the deterioration mechanisms of sandstone under initial damage and to develop an improved strength criterion suitable for engineering predictions. Sandstone specimens with varying levels of damage were prepared through uniaxial incremental cyclic loading-unloading tests, from which their peak strength, deformation modulus, and shear strength parameters were obtained via triaxial compression tests. Additionally, PFC2D was utilized to simulate crack initiation, propagation, and coalescence, providing microscopic insights into the damage-induced weakening of strength. Based on these findings, the staged influence of damage on the Hoek-Brown parameters m and s was quantified, leading to the establishment of a “damage-parameter” relationship incorporated into the generalized Hoek-Brown criterion, thereby enhancing the strength prediction method. The results indicate that initial damage causes exponential decay in peak strength and stiffness, accompanied by an increase in Poisson′s ratio, with the damage effect being strongly dependent on confining pressure. The reconstruction and weakening of the crack network were identified as fundamental causes of macroscopic deterioration, while high confining pressure effectively suppresses tensile cracking and promotes frictional slip, thereby delaying failure. The improved Hoek-Brown criterion accurately captures strength reduction at different damage levels. Engineering case verification further demonstrates that the proposed method yields higher prediction accuracy for surrounding rock deformation compared to conventional criteria. This study provides a quantitative approach for evaluating strength degradation in excavation-induced damaged rock and offers valuable guidance for stability assessment and support optimization in deep underground engineering.

Key words： rock mechanics initial damage sandstone damage deterioration mechanism discrete element simulation improved Hoek-Brown criterion

引用本文:

晏启祥1，贺文城1，刘瑞琦1，孙明辉1，2*，杨潇3. 初始损伤对砂岩力学性能劣化的影响机制研究[J]. 岩石力学与工程学报, 2026, 45(5): 1378-1391.
YAN Qixiang1, HE Wencheng1, LIU Ruiqi1, SUN Minghui1, 2*, YANG Xiao3. Mechanistic effects of initial damage on the degradation of sandstone mechanical properties. , 2026, 45(5): 1378-1391.

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https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0328 或 https://rockmech.whrsm.ac.cn/CN/Y2026/V45/I5/1378

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