基于原位CT扫描的三峡花岗岩细观结构特征与破裂机制研究

doi:10.3724/1000-6915.jrme.2025.0293

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摘要针对三峡地区中粗粒与中细粒两类典型花岗岩开展原位CT测试，并借助数字体积相关（DVC）技术实现岩石试样内部变形场的非侵入测量，研究花岗岩细观结构特征对花岗岩宏观力学性质和破坏模式的影响规律。结果表明：中粗粒与中细粒花岗岩的细观结构差异主要表现为云母定向排列的不同，云母矿物普遍呈现扁平的椭球状结构，且中粗粒花岗岩中的云母颗粒相较于中细粒形状更为扁平，其云母矿物具有更加显著的空间定向排列特征；中细粒花岗岩破裂网络呈各向同性分布，其破裂模式受应力控制，而中粗粒花岗岩破裂面方向与云母定向排列高度一致，表现为典型的结构控制破坏；等效应变较大的区域与岩石峰后破裂形态基本一致，说明等效应变能够有效预测峰后岩石的实际破裂形态，将中粗粒花岗岩等效应变＞0.4%的区域视为潜在破坏区域，则其分布形态与云母排列方向基本一致，揭示了花岗岩细观结构对其破裂过程的主导作用。

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	朱泽奇1
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	3
	田铠玮1
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	李子硕4
	盛谦1
	2
	陈健1
	2
	3

关键词 ：岩石力学, 花岗岩, X射线CT扫描, 花岗岩细观结构, 单轴强度, 破裂模式

Abstract：In situ CT testing was conducted on two typical types of granite from the Three Gorges region, specifically medium coarse-grained and medium fine-grained granite. Non-invasive measurement of the internal deformation field of rock samples was achieved using digital volume correlation (DVC) technology. This study examined the influence of the microstructural characteristics of granite on its macroscopic mechanical properties and failure modes. The results indicate that the difference in microstructure between medium coarse-grained and medium fine-grained granites is primarily manifested in the directional arrangement of mica. Mica minerals generally exhibit a flat ellipsoidal structure, and the mica particles in medium coarse-grained granites are flatter in shape compared to those in medium fine-grained granites, suggesting a more pronounced spatial directional arrangement of mica in the former. The fracture network of medium and fine-grained granite displays an isotropic distribution, with the fracture mode being stress-controlled. The orientation of the fracture surface in medium coarse-grained granite closely aligns with the orientation and arrangement of mica, demonstrating typical structural control failure. Areas exhibiting larger equivalent strain changes correlate well with the post-peak fracture morphology of the rocks, indicating that equivalent strain can effectively predict the actual fracture morphology of post-peak rocks. In medium coarse-grained granite, regions with equivalent strain changes exceeding 0.4% are identified as potential failure areas, with their distribution patterns aligning closely with the direction of mica arrangement, revealing the dominant role of the mesostructure of granite in its fracture process.

Key words： rock mechanics')" href="#">

rock mechanics granite X-ray CT scanning granite mesostructure uniaxial strength fracture mode

引用本文:

朱泽奇1，2，3，田铠玮1，2，李子硕4，盛谦1，2，陈健1，2，3. 基于原位CT扫描的三峡花岗岩细观结构特征与破裂机制研究[J]. 岩石力学与工程学报, 2025, 44(11): 2887-2900.
ZHU Zeqi1, 2, 3, TIAN Kaiwei1, 2, LI Zishuo4, SHENG Qian1, 2, CHEN Jian1, 2, 3. Meso-structural characteristics and fracture mechanism of Three Gorges granite based on in-situ CT scanning. , 2025, 44(11): 2887-2900.

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https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0293 或 https://rockmech.whrsm.ac.cn/CN/Y2025/V44/I11/2887

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