恒定法向刚度边界条件下花岗岩真三轴剪切力学响应与断裂面演化特征研究

doi:10.3724/1000-6915.jrme.2025.0629

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摘要在深部真三轴应力环境下，岩体与支护结构相互作用复杂，传统恒定法向应力试验忽略了支护刚度效应，难以表征应力演化路径和岩体与支护耦合作用下的真实剪切响应。通过真三轴应力剪切试验，对比了恒定法向应力（CNL）与恒定法向刚度（CNS）两种边界条件下不同侧向应力（0～50 MPa）和法向刚度（0～70 GPa/m）对花岗岩真三轴剪切变形、剪切强度、剪切破坏模式和断裂面形貌特征、剪切断裂和摩擦滑动耗散能量的影响。试验结果表明：侧向应力主要约束侧向变形，而CNS边界有效抑制花岗岩法向膨胀变形。在CNL边界条件下，侧向应力与峰值剪切强度的提高率为负相关，当侧向应力由0 MPa提高至10 MPa，峰值强度提高率为41.9%；侧向应力由10 MPa提高至50 MPa，相对初始值的强度提高率降至11.36%。CNS边界条件能持续抑制法向膨胀并提升峰值与残余剪切强度（最大增幅为52.17%）。而CNL边界条件下，侧向应力易诱发羽状次生裂纹与阶梯状破裂面。CNS边界通过动态法向应力与侧向约束的耦合，改变了断裂能与摩擦滑动的耗能规律且断裂面形貌相对平缓，反映了边界条件对破坏模式的显著控制。这表明考虑CNS边界更能反映深部岩体的真实力学响应，为支护设计与稳定性控制提供了重要参考。

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	胡亮1
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	赵骏1
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	郭月1
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关键词 ：岩石力学, 深部工程, 真三轴剪切, 侧向应力, 法向刚度, 剪切力学响应

Abstract：In deep true triaxial stress environments, the interaction between rock masses and support structures is intricate. Traditional constant normal load (CNL) tests, which neglect the effect of support stiffness, face challenges in characterizing the stress evolution paths and the genuine shear response governed by rock-support coupling. This study systematically compares the influence of constant normal stress (CNS) and CNL boundaries on the mechanical response of granite through true triaxial shear tests. The research focuses on analyzing the effects of varying lateral stresses (0–50 MPa) and normal stiffnesses (0–70 GPa/m) on true triaxial shear deformation, shear strength, shear failure modes, fracture surface morphology, and energy dissipation characteristics during shear fracture and friction sliding. The experimental results indicate that lateral stress primarily constrains lateral deformation, while its enhancement of normal deformation is an indirect effect. The CNS boundary effectively suppresses the normal dilatancy of granite. Under CNL conditions, increasing lateral stress exhibits a negative correlation with the rate of peak shear strength enhancement; specifically, the strength enhancement rate was 41.9% when lateral stress increased from 0 MPa to 10 MPa, but decreased to 11.36% when lateral stress further increased from 10 MPa to 50 MPa. The CNS boundary condition continuously suppresses normal dilation and enhances both peak and residual shear strength, with a maximum increase of 52.17%. Furthermore, under CNL conditions, lateral stress tends to induce feather-like secondary wing cracks and step-like fracture surfaces. Conversely, the coupling of dynamic normal stress and lateral confinement under the CNS boundary alters the energy dissipation mechanisms during fracture and friction sliding, resulting in a relatively smoother fracture surface morphology. This demonstrates the significant influence of boundary conditions on the failure mode. The study concludes that considering the CNS boundary provides a more realistic representation of the mechanical response of deep rock masses, offering crucial theoretical insights for support design and stability control.

Key words： rock mechanics deep engineering true triaxial shear lateral stress normal stiffness shear mechanical response

引用本文:

胡亮1，2，赵骏1，2*，郭月1，2. 恒定法向刚度边界条件下花岗岩真三轴剪切力学响应与断裂面演化特征研究[J]. 岩石力学与工程学报, 2026, 45(6): 1773-1786.
HU Liang1, 2, ZHAO Jun1, 2*, GUO Yue1, 2. True triaxial shear mechanical response and fracture surface evolution of granite under constant normal stiffness boundary. , 2026, 45(6): 1773-1786.

链接本文:

https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0629 或 https://rockmech.whrsm.ac.cn/CN/Y2026/V45/I6/1773

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