考虑裂纹扩展机制的花岗岩单轴压缩实验室尺寸效应研究

doi:10.3724/1000-6915.jrme.2025.0465

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (10967 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要岩体在单轴压缩下普遍表现出显著的尺寸效应，但其细观主控机制及裂纹参数敏感性仍缺乏系统认知。本文针对花岗岩不同实验室尺寸试样开展了单轴压缩与声发射（acoustic emission，AE）监测实验，并结合X射线衍射矿物组分约束和AE数据引导，基于PFC平台建立含原生裂隙网络的数值模型。结果表明：岩样的单轴抗压强度、破坏模式及裂纹扩展均表现出明显尺寸依赖性，峰值强度随尺寸增大而降低，破坏模式由劈裂向剪切转变。在均质矿物基质模型（无原生裂隙）下，强度基本不随尺寸变化，表明原生裂隙是尺寸效应的主控因素。此外，裂隙长度对强度劣化的影响远高于裂隙数量，且小尺寸试样对裂隙参数变化更为敏感。所建模型在应力–应变、AE时序、AF-RA裂纹分型及破坏形态等方面与试验结果一致，验证多尺度数值模型的可靠性。研究结果可为复杂地质条件下工程岩体的强度尺寸效应修正与安全设计提供理论支撑。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	余乔娟1
	2
	杜时贵1
	张泽平1
	刘广建1
	罗战友1*
	吕原君1

关键词 ：岩石力学, 尺寸效应, 多尺度数值模拟, 声发射, 原生裂隙网络, AF-RA, 花岗岩

Abstract：Rock masses often exhibit significant size effects under uniaxial compression, yet the underlying mesoscopic controlling mechanisms and sensitivity to crack parameters remain poorly understood. In this study, we conducted uniaxial compression and acoustic emission (AE) monitoring experiments on granite specimens of various laboratory scales. By incorporating constraints from X-ray diffraction (XRD) mineral composition and AE-guided micro-crack data, we established a numerical model with a pre-existing micro-crack network using the PFC platform. The results indicate that the uniaxial compressive strength, failure mode, and crack propagation of the specimens demonstrate pronounced size dependence: peak strength decreases with increasing specimen size, and the failure mode transitions from splitting to shearing. In a homogeneous mineral matrix model (without pre-existing micro-cracks), the strength is nearly independent of specimen size, suggesting that pre-existing micro-cracks are the primary factor controlling the size effect. Furthermore, crack length has a significantly greater impact on strength degradation than crack number, with smaller specimens being more sensitive to variations in crack parameters. The established model effectively reproduces the experimental results regarding stress-strain behavior, AE event sequences, AF-RA crack classification, and failure patterns, thereby validating the reliability of the multi-scale numerical approach. These findings provide theoretical support for addressing the strength size effect and enhancing the safety design of engineering rock masses under complex geological conditions.

Key words： rock mechanics size effect multiscale numerical simulation acoustic emission pre-existing micro-crack network AF-RA granite

引用本文:

余乔娟1，2，杜时贵1，张泽平1，刘广建1，罗战友1*，吕原君1. 考虑裂纹扩展机制的花岗岩单轴压缩实验室尺寸效应研究[J]. 岩石力学与工程学报, 2026, 45(2): 412-431.
YU Qiaojuan1, 2, DU Shigui1, ZHANG Zeping1, LIU Guangjian1, LUO Zhanyou1*, LYU Yuanjun1. Size effect of granite in uniaxial compression considering crack propagation mechanism. , 2026, 45(2): 412-431.

链接本文:

https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0465 或 https://rockmech.whrsm.ac.cn/CN/Y2026/V45/I2/412

[1] GONZÁLEZ-FERNÁNDEZ M A，ESTÉVEZ-VENTOSA X，ALEJANO L R，et al. Size-dependent behaviour of hard rock under triaxial loading[J]. Rock Mechanics and Rock Engineering，2023，56(8)：6 009–6 025.
[2] FAKHIMI A，TAROKH A. Process zone and size effect in fracture testing of rock[J]. International Journal of Rock Mechanics and Mining Sciences，2013，60：95–102.
[3] 梁正召，张永彬，唐世斌，等. 岩体尺寸效应及其特征参数计算[J]. 岩石力学与工程学报，2013，32(6)：1 157–1 166.(LIANG Zhengzhao，ZHANG Yongbin，TANG Shibin，et al. Size effect of rock messes and associated representative element properties[J]. Chinese Journal of Rock Mechanics and Engineering，2013，32(6)：1 157–1 166.(in Chinese))
[4] DARBOR M，FARAMARZI，SHARIFZADEH. Size-dependent compressive strength properties of hard rocks and rock-like cementitious brittle materials[J]. Geosystem Engineering，2019，22(4)：179–192.
[5] ROSHAN H，MASOUMI H，REGENAUER-LIEB K. Frictional behaviour of sandstone：a sample-size dependent triaxial investigation[J]. Journal of Structural Geology，2017，94：154–165.
[6] 靖洪文，苏海健，杨大林，等. 损伤岩样强度衰减规律及其尺寸效应研究[J]. 岩石力学与工程学报，2012，31(3)：543–549.(JING Hongwen，SU Haijian，YANG Dalin，et al. Study of strength degradation law of damaged rock sample and its size effect[J]. Chinese Journal of Rock Mechanics and Engineering，2012，31(3)：543–549.(in Chinese))
[7] ZHAI H，MASOUMI H，ZOORABADI M，et al. Size-dependent behaviour of weak intact rocks[J]. Rock Mechanics and Rock Engineering，2020，53(8)：3 563–3 587.
[8] 刘刚，肖福坤，秦涛. 小尺寸效应下岩石力学特性及声发射规律[J]. 岩石力学与工程学报，2018，37(增2)：3 905–3 917.(LIU Gang，XIAO Fukun，QIN Tao. Rock mechanics characteristics and acoustic emission rule under small-size effect[J]. Chinese Journal of Rock Mechanics and Engineering，2018，37(Supp.2)：3 905–3 917.(in Chinese))
[9] 梁昌玉，李晓，张辉，等. 中低应变率范围内花岗岩单轴压缩特性的尺寸效应研究[J]. 岩石力学与工程学报，2013，32(3)：528–536.(LIANG Changyu，LI Xiao，ZHANG Hui，et al. Research on size effect of uniaxial compression properties of granite under medium and low strain rates[J]. Chinese Journal of Rock Mechanics and Engineering，2013，32(3)：528–536.(in Chinese))
[10] 潘鹏志，周辉，冯夏庭. 加载条件对不同尺寸岩石单轴压缩破裂过程的影响研究[J]. 岩石力学与工程学报，2008，27(增2)：3 636–3 642.(PANG Pengzhi，ZHOU Hui，FENG Xiating. Research on effect of loading conditions on failure processes of rocks with different sizes under uniaxial compression[J]. Chinese Journal of Rock Mechanics and Engineering，2008，27(Supp.2)：3 636–3 642.(in Chinese))
[11] 杨圣奇，徐卫亚，苏承东. 考虑尺寸效应的岩石损伤统计本构模型研究[J]. 岩石力学与工程学报，2005，24(24)：4 484–4 490.(YANG Shengqi，XU Weiya，SU Chengdong. Study on statistical damage constitutive model of rock considering scale effect[J]. Chinese Journal of Rock Mechanics and Engineering，2005，24(24)：4 484–4 490.(in Chinese))
[12] MASOUMI H，SAYDAM S，HAGAN P C. Incorporating scale effect into a multiaxial failure criterion for intact rock[J]. International Journal of Rock Mechanics and Mining Sciences，2016，83：49–56.
[13] MASOUMI H，ROSHAN H，HAGAN P C. Size-dependent hoek- brown failure criterion[J]. International Journal of Geomechanics，2017，17(2)：04016048.
[14] LI K，YIN Z Y，HAN D，et al. Size effect and anisotropy in a transversely isotropic rock under compressive conditions[J]. Rock Mechanics and Rock Engineering，2021，54(9)：4 639–4 662.
[15] TANG C，THAM L G，LEE P K K，et al. Numerical studies of the influence of microstructure on rock failure in uniaxial compression—Part I：effect of heterogeneity[J]. International Journal of Rock Mechanics and Mining Sciences，2000，37(4)：555–569.
[16] SUN Y，KWOK C Y，DUAN K. Size effects on crystalline rock masses: insights from grain-based dem modeling[J]. Computers and Geotechnics，2024，171：106376.
[17] WEISS J，GIRARD L，GIMBERT F，et al. (Finite) statistical size effects on compressive strength[J]. Proceedings of the National Academy of Sciences，2014，111(17)：6 231–6 236.
[18] WU H，JU Y，HAN X，et al. Size effects in the uniaxial compressive properties of 3D printed models of rocks：an experimental investigation[J]. International Journal of Coal Science and Technology，2022，9(1)：83.
[19] 张明，卢裕杰，杨强. 准脆性材料的破坏概率与强度尺寸效应[J]. 岩石力学与工程学报，2010，29(9)：1 782–1 789.(ZHANG Ming，LU Yujie，YANG Qiang. Failure probability and strength size effect of quasi-brittle materials[J]. Chinese Journal of Rock Mechanics and Engineering，2010，29(9)：1 782–1 789.(in Chinese))
[20] 张后全，徐建峰，贺永年，等. 灰岩单轴压缩实验室尺度效应研究[J]. 岩石力学与工程学报，2012，31(增2)：3 491–3 496.(ZHANG Houquan，XU Jianfeng，HE Yongnian，et al. Study of laboratory scale effect of limestone under uniaxial compression[J]. Chinese Journal of Rock Mechanics and Engineering，2012，31(Supp.2)：3 491–3 496.(in Chinese))
[21] TANG C. Numerical simulation of progressive rock failure and associated seismicity[J]. International Journal of Rock Mechanics and Mining Sciences，1997，34(2)：249–261.
[22] WONG L N Y，EINSTEIN H H. Crack coalescence in molded gypsum and carrara marble: part 1. macroscopic observations and interpretation[J]. Rock Mechanics and Rock Engineering，2009，42(3)：475–511.
[23] ZHAO L Y，ZHU Q Z，SHAO J F. A micro-mechanics based plastic damage model for quasi-brittle materials under a large range of compressive stress[J]. International Journal of Plasticity，2018，100：156–176.
[24] 张晓平，王思敬，韩庚友，等. 岩石单轴压缩条件下裂纹扩展试验研究——以片状岩石为例[J]. 岩石力学与工程学报，2011，30(9)：123–132.(ZHANG Xiaoping，WANG Sijing，HAN Gengyou，et al. Crack propagation study of rock based on uniaxial compressive test—A case study of schistose rock[J]. Chinese Journal of Rock Mechanics and Engineering，2011，30(9)：123–132.(in Chinese))
[25] 王传乐，杜广印，李二兵，等. 北山深部花岗岩常规三轴压缩条件下的强度参数演化及能量耗散[J]. 岩石力学与工程学报，2021，40(11)：2 238–2 248.(WANG Chuanle，DU Guangyin，LI Erbing，et al. Evolution of strength parameters and energy dissipation of Beishan deep granite under conventional triaxial compression[J]. Chinese Journal of Rock Mechanics and Engineering，2021，40(11)：2 238–2 248.(in Chinese))
[26] 包含，裴润生，兰恒星，等. 基于循环加卸载的矿物定向排列致各向异性岩石损伤演化规律——以黑云母石英片岩为例[J]. 岩石力学与工程学报，2021，40(10)：2 015–2 026.(BAO Han，PEI Runsheng，LAN Hengxing，et al. Damage evolution of Biotite quartz schist caused by mineral directional arrangement under cyclic loading and unloading[J]. Chinese Journal of Rock Mechanics and Engineering，2021，40(10)：2 015–2 026.(in Chinese))
[27] ZHENG Y L，MA Z J，GONG Q M，et al. Heating-dominated fracturing of granite by open-ended microwave: insights from acoustic emission measurement[J]. Rock Mechanics and Rock Engineering，2022，55(8)：4 577–4 589.
[28] DU K，LI X F，TAO M，et al. Experimental study on acoustic emission (ae) characteristics and crack classification during rock fracture in several basic lab tests[J]. International Journal of Rock Mechanics and Mining Sciences，2020，133：104411.
[29] HE C D，MISHRA B，SHI Q W，et al. Correlations between mineral composition and mechanical properties of granite using digital image processing and discrete element method[J]. International Journal of Mining Science and Technology，2023，33(8)：949–962.
[30] MA Z，ZHANG C，PATHEGAMA GAMAGE R，et al. Uncovering the creep deformation mechanism of rock-forming minerals using nanoindentation[J]. International Journal of Mining Science and Technology，2022，32(2)：283–294.
[31] 张燕，周轩，叶剑红. 大开度裂隙网络内非线性两相渗流的数值研究[J]. 岩石力学与工程学报，2018，37(4)：931–939.(ZHANG Yan，ZHOU Xuan，YE Jianhong. Numerical analysis of nonlinear two-phase flow within large opening fracture networks in rockmass[J]. Chinese Journal of Rock Mechanics and Engineering，2018，37(4)：931–939.(in Chinese))
[32] 张奇华，邬爱清. 三维任意裂隙网络渗流模型及其解法[J]. 岩石力学与工程学报，2010，29(4)：720–730.(ZHANG Qihua，WU Aiqing. Three-dimensional arbitrary fracture network seepage model and its solution[J]. Chinese Journal of Rock Mechanics and Engineering，2010，29(4)：720–730.(in Chinese))
[33] DING X，ZHANG L，ZHU H，et al. Effect of model scale and particle size distribution on PFC3D simulation results[J]. Rock Mechanics and Rock Engineering，2014，47(6)：2 139–2 156.
[34] YU Q，DU S，ZHU Q Z，et al. A novel micro-mechanical anisotropic elastic-plastic damage model for understanding time-dependent behaviors on rock-like materials[J]. International Journal of Rock Mechanics and Mining Sciences，2024，179：105780.
[35] BROWN E T，HOEK E. Underground excavations in rock[M]. London：CRC Press，1980：92–96.
[36] KONG L L，WU J，WANG H，et al. Size effect of mechanical characteristics of sandstone and granite under uniaxial compression[J]. Frontiers in Energy Research，2023，11：1223400.