锚固参数对岩石节理剪切力学及声发射特性影响试验研究

doi:10.3724/1000-6915.jrme.2025.0922

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摘要锚固支护被广泛应用于地下结构稳定性控制，由于锚固参数的差异导致锚固支护性能不同，尤其是锚固段与围岩内节理的相对位置，造成锚杆抗剪性能产生明显差异。为探究锚固参数对锚固节理剪切力学特性的影响，开展了一系列不同锚固长度与锚固厚度下锚固节理剪切试验。结果表明：同一锚固厚度随着锚固长度的增加，平均剪切峰值与锚杆破断强度分别增大3.15%，2.56%，平均锚杆变形范围、锚杆破断位移分别下降18.41%，16.48%。同一锚固长度下随着锚固厚度的增大，平均剪切峰值强度与锚杆破断强度提高1.93%，1.64%。锚杆破断后变形呈“S”型，随着锚固长度越大，锚杆变形越对称，锚杆破断时的法向位移量越低、轴力越小，锚杆提供抗剪力越大。峰前阶段振铃计数、能量分别占其总量的61.7%，58.5%，b值在剪切峰值处降至最低；峰后变形阶段b值不断升高，在破断峰值处升至最大值。通过GMM（Gaussian Mixture Model）统计裂纹类型得出锚固节理主要发生剪切破坏，平均声发射剪切破坏约占86.05%，拉伸破坏仅占13.95%。

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	栾恒杰1
	2
	贾志伟1
	2
	张孙豪1
	2*
	蒋宇静1
	2
	3
	刘香兰4
	张广超1
	2
	唐子奇1
	2
	吴硕1
	张峰源2

关键词 ：岩石力学, 岩石节理, 锚固参数, 剪切试验, 力学特性, 声发射

Abstract：Anchorage support is extensively utilized in the stability control of underground structures. The performance of such support varies with anchorage parameters, particularly influenced by the relative position between the anchorage section and the joints in the surrounding rock, which significantly affects the shear resistance of the bolts. To investigate the impact of anchorage parameters on the shear mechanical behavior of bolted joints, a series of shear tests were conducted with varying anchorage lengths and thicknesses. The results indicate that, for a given anchorage thickness, increasing the anchorage length enhances the average shear peak strength and the rod breaking strength by 3.15% and 2.56%, respectively, while simultaneously reducing the average deformation range and the breaking displacement of the bolts by 18.41% and 16.48%, respectively. For a constant anchorage length, an increase in anchorage thickness improves the average shear peak strength and breaking strength by 1.93% and 1.64%, respectively. Post-failure, the deformed bolts exhibit an “S”-shaped profile. As the anchorage length increases, the deformation becomes more symmetric, the normal displacement at peak failure decreases, the axial force reduces, and the shear force provided by the bolts increases. In the pre-peak stage, the ring-down count and energy account for 61.7% and 58.5% of the total, respectively, while the b-value reaches its lowest point at the shear peak. During the post-peak deformation stage, the b-value continuously rises, peaking at the breaking point. Through Gaussian Mixture Model (GMM) statistics of crack types, it is concluded that the shear failure of the bolted joint predominantly occurs in shear, with an average of 86.05% attributed to acoustic emission shear failure and only 13.95% to tensile failure.

Key words： rock mechanics rock joints anchorage parameters shear test mechanical property acoustic emission

引用本文:

栾恒杰1，2，贾志伟1，2，张孙豪1，2*，蒋宇静1，2，3，刘香兰4，张广超1，2，唐子奇1，2，吴硕1，张峰源2. 锚固参数对岩石节理剪切力学及声发射特性影响试验研究[J]. 岩石力学与工程学报, 2026, 45(6): 1639-1656.
LUAN Hengjie1, 2, JIA Zhiwei1, 2, ZHANG Sunhao1, 2*, JIANG Yujing1, 2, 3, LIU Xianglan4, ZHANG Guangchao1, 2, TANG Ziqi1, 2, WU Shuo1, ZHANG Fengyuan2 . Influence of anchorage parameters on the shear mechanics and acoustic emission characteristics of rock joints. , 2026, 45(6): 1639-1656.

链接本文:

https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0922 或 https://rockmech.whrsm.ac.cn/CN/Y2026/V45/I6/1639

[1] 蒋宇静，张孙豪，栾恒杰，等. 循环载荷对岩石节理宏细观剪切特性影响的模拟研究[J]. 煤炭学报，2023，48(1)：199–211.(JIANG Yujing，ZHANG Sunhao，LUAN Hengjie，et al. Numerical investigation on the effect of cyclic loading on macro-meso shear characteristics of rock joints[J]. Journal of China Coal Society，2023，48(1)：199–211.(in Chinese))
[2] WANG G，LIU T F，WANG C S，et al. Experimental and numerical study on the shear behaviour of standard JRC double-joint rock masses[J]. International Journal of Rock Mechanics and Mining Sciences，2024，183：105930.
[3] 胡宇璇，叶祖洋，李硕. 实时温度下红砂岩粗糙节理剪切力学特性研究[J]. 煤炭学报，2025，50(增1)：63–73.(HU Yuxuan，YE Zuyang，LI Shuo. Shear mechanical properties of rough-walled joints of red sandstone under real-time temperature[J]. Journal of China Coal Society，2025，50(Supp.1)：63–73.(in Chinese))
[4] SHANG D Q，ZHANG S H，JIANG Y J，et al. Elucidating the rate-dependent shear failure mechanism in cement fractures based on multi-parameter acoustic emission analysis[J]. Journal of Building Engineering，2025，111：113161.
[5] SHANG D Q，JIANG Y J，ZHANG S H，et al. Rate-dependent shear behavior of rough joints based on acoustic emission[J]. Journal of Rock Mechanics and Geotechnical Engineering，2025，17(10)：6 195–6 212.
[6] ZHENG H F，WU X Z，JIANG Y J，et al. Shear behavior of rock joints reinforced with fully-grouted and energy-absorbing bolts subjected to shear cycles[J]. Journal of Rock Mechanics and Geotechnical Engineering，2024，17(7)：4 314–4 328.
[7] 蒋宇静，张孙豪，栾恒杰，等. 恒定法向刚度边界条件下锚固节理岩体剪切特性试验研究[J]. 岩石力学与工程学报，2021，40(4)：663–675.(JIANG Yujing，ZHANG Sunhao，LUAN Hengjie，et al. Experimental study on shear characteristics of bolted rock joints under constant normal stiffness boundary conditions[J]. Chinese Journal of Rock Mechanics and Engineering，2021，40(4)：663–675.(in Chinese))
[8] CHEN N，ZHANG X B，JIANG Q H，et al. Shear behavior of rough rock joints reinforced by bolts[J]. International Journal of Geomechanics，2018，18(1)，https://doi.org/10.1061/(ASCE)GM.1943-5622.000104.
[9] JIANG Y J，LI X P，LIU J K，et al. Study on shear behavior and failure characteristics of bolted anisotropic rock joints[J]. Materials，2023，16(6)：2 210.
[10] 吕萌，王亮清，谢妮，等. 加锚异性结构面剪切特性及声发射响应特征研究[J]. 岩土力学，2025，46(7)：2 106–2 120.(LU Meng，WANG Liangqing，XIE Ni，et al. Shear characteristics and acoustic emission response characteristics of anchored heterogeneous structural plane[J]. Rock and Soil Mechanics，2025，46(7)：2 106–2 120.(in Chinese))
[11] 韩观胜，陈志靖，李博，等. 恒定法向刚度条件下吸能锚杆锚固节理岩体剪切特性试验研究[J]. 岩石力学与工程学报，2024，43(4)：999–1 012.(HAN Guansheng，CHEN Zhijing，LI Bo，et al. Experimental study on shear characteristics of energy-absorbing bolt anchored jointed rock mass under constant normal stiffness condition[J]. Chinese Journal of Rock Mechanics and Engineering，2024，43(4)：999–1 012.(in Chinese))
[12] WU X Z，JIANG Y J，LI B. Influence of joint roughness on the shear behaviour of fully encapsulated rock bolt[J]. Rock Mechanics and Rock Engineering，2017，51：953–959.
[13] WANG G，ZHANG Y Z，JIANG Y J，et al. Shear behaviour and acoustic emission characteristics of bolted rock joints with different rough nesses[J]. Rock Mechanics and Rock Engineering，2018，51：1 885–1 906.
[14] 宋洋，王贺平，金佳旭，等. 深部充填节理岩体锚固抗力力学模型研究[J]. 岩土工程学报，2025，47(8)：1 672–1 680.(SONG Yang，WANG Heping，JIN Jiaxu，et al. Mechanical model for anchorage resistance of deep filling jointed rock mass[J]. Chinese Journal of Geotechnical Engineering，2025，47(8)：1 672–1 680.(in Chinese))
[15] 刘广建，裘伟奇，杜程，等. 考虑锚杆强度的加锚岩体结构面锚固效应试验研究[J]. 岩土工程学报，2025，47(3)：580–588.(LIU Guangjian，QIU Weiqi，DU Cheng，et al. Experimental study on bolting effects of bolted joint rock masses considering strength of bolts[J]. Chinese Journal of Geotechnical Engineering，2025，47(3)：580–588.(in Chinese))
[16] 张书博，王长盛，王刚，等. BFRP筋锚固节理岩体剪切行为试验研究[J]. 岩石力学与工程学报，2022，41(4)：712–724.(ZHANG Shubo，WANG Changsheng，WANG Gang，et al. Experimental study on the shear behaviors of bolted rock joints reinforced with BFRP bars[J]. Chinese Journal of Rock Mechanics and Engineering，2022，41(4)：712–724.(in Chinese))
[17] 杨凯丞，吴曙光，廖海成，等. 双锚杆受力机制分析及模型试验研究[J]. 岩土力学，2023，44(增1)：495–503.(YANG Kaicheng，WU Shuguang，LIAO Haicheng，et al. Mechanism analysis and model test research on double anchor rods[J]. Rock and Soil Mechanics，2023，44(Supp.1)：495–503.(in Chinese))
[18] SRIVASTAVA L P，SINGH M. Effect of fully grouted passive bolts on joint shear strength parameters in a blocky mass[J]. Rock Mechanics and Rock Engineering，2014，48：1 197–1 206.
[19] CHEN Y L，TENG J Y，SADIQ R A B，et al. Experimental study of bolt-anchoring mechanism for bedded rock mass[J]. International Journal of Geomechanics，2020，20(4)，https://doi.org/10.1061/ (ASCE)GM. 1943-5622.0001561.
[20] CUI G J，ZHANG C Q，CHEN J L，et al. Effect of bolt inclination angle on shear behavior of bolted joints under CNL and CNS conditions[J]. Journal of Central South University，2020，27：937–950.
[21] 刘爱卿，鞠文君，许海涛，等. 锚杆预紧力对节理岩体抗剪性能影响的试验研究[J]. 煤炭学报，2013，38(3)：391–396.(LIU Aiqing，JU Wenjun，XU Haitao，et al. Experimental study on the effect of bolt prestress on the shear behavior of jointed rockmass[J]. Journal of China Coal Society，2013，38(3)：391–396.(in Chinese))
[22] ZHENG H F，WU X Z，JIANG Y J，et al. Insights into velocity-dependent shear characteristics of bolted rock joints：a comparative study of fully-grouted and energy-absorbing bolts[J]. International Journal of Rock Mechanics and Mining Sciences，2024，183：105 910.
[23] 崔国建，张传庆，刘立鹏，等. 锚杆杆体–砂浆界面力学特性的剪切速率效应研究[J]. 岩土力学，2018，39(增1)：275–281.(CUI Guojian，ZHANG Chuanqing，LIU Lipeng，et al. Study of effect of shear velocity on mechanical characteristics of bolt-grout interface[J]. Rock and Soil Mechanics，2018，39(Supp.1)：275–281.(in Chinese))
[24] 张农，王朋，阚甲广，等. 高频低能冲击扰动下锚固结构渐进失效试验研究[J]. 煤炭学报，2024，49(1)：309–319.(ZHANG Nong，WANG Peng，KAN Jiaguang，et al. Experimental study on progressive failure of anchoring structure under high-frequency and low-energy impact disturbance[J]. Journal of China Coal Society，2024，49(1)：309–319.(in Chinese))
[25] WU X Z，JIANG Y J，GONG B，et al. Behaviour of rock Joint reinforced by energy-absorbing rock bolt under cyclic shear loading condition[J]. International Journal of Rock Mechanics and Mining Sciences，2018，110：88–96.
[26] ZHENG H F，WU X Z，JIANG Y J，et al. Shear behavior of rock joints reinforced with fully-grouted and energy-absorbing bolts subjected to shear cycles[J]. Journal of Rock Mechanics and Geotechnical Engineering，2025，17(7)：4 314–4 328.
[27] LI S C，WANG H T，WANG Q，et al. Failure mechanism of bolting support and high-strength bolt-grouting technology for deep and soft surrounding rock with high stress[J]. Journal of Central South University，2016，23：440–448.
[28] YANG N，LI W，XUAN C M，et al. Improvement of breakable anchor bolt element in FLAC3D and its application in deep coal roadway[J]. Journal of Mining and Safety Engineering，2017，34(2)：251–258.
[29] YANG R S，LI Y L，GUO D M，et al. Failure mechanism and control technology of water-immersed roadway in high-stress and soft rock in a deep mine[J]. International Journal of Mining Science and Technology，2017，27(2)：245–252.
[30] YAN S，SONG Y B，BAI J B，et al. A study on the failure of resin end-anchored rockbolts subjected to tensile load[J]. Rock Mechanics and Rock Engineering，2019，52(6)：1 917–1 930.
[31] 蒋宇静，张孙豪，栾恒杰，等. 锚固方式对岩石节理宏细观剪切特性的影响及其机制研究[J]. 岩石力学与工程学报，2024，43(6)：1 301–1 315.(JIANG Yujing，ZHANG Sunhao，LUAN Hengjie，et al. Study of the effect of anchorage modes on the macro and micro shear characteristics of rock joints and its mechanism[J]. Chinese Journal of Rock Mechanics and Engineering，2024，43(6)：1 301–1 315.(in Chinese))
[32] 腾俊洋，张宇宁，唐建新，等. 锚固方式对节理岩体剪切性能影响试验研究[J]. 岩土力学，2017，38(8)：2 279–2 285.(TENG Junyang，ZHANG Yuning，TANG Jianxin，et al. Experimental study on shear behavior of jointed rock mass with anchorage mode[J]. Rock and Soil Mechanics[J]. Rock and Soil Mechanics，2017，38(8)：2 279–2 285.(in Chinese))
[33] FENG C，LIU S W，FU M X，et al. Failure mechanism and strengthening countermeasures of end-anchored cable free section under combined tension and shear[J]. Engineering Failure Analysis，2024，157：107949.
[34] ZHANG S H，JIANG Y J，LUAN H J，et al. Study on shear mechanical characteristics of rock joints under different anchorage lengths[J]. Rock Mechanics and Rock Engineering，2024，57：9 959–9 981.
[35] 王培涛，任奋华，蔡美峰. 基于离散元方法的粗糙性节理岩体直剪力学及尺寸效应特性[J]. 煤炭学报，2018，43(4)：976–983.(WANG Peitao，REN Fenhua，CAI Meifeng. Mechanical analysis and size effect of rough discrete fractures network model under direct shear tests based on particle flow code[J]. Journal of China Coal Society，2018，43(4)：976–983.(in Chinese))
[36] 王洪涛，王琦，王富奇，等. 不同锚固长度下巷道锚杆力学效应分析及应用[J]. 煤炭学报，2015，40(3)：509–515.(WANG Hongtao，WANG Qi，WANG Fuqi，et al. Mechanical effect analysis of bolts in roadway under different anchoring lengths and its application[J]. Journal of China Coal Society，2015，40(3)：509–515.(in Chinese))
[37] MINDLIN R D. Force at a point in the interior of a semi infinite solid[J]. Physics，1936，7(5)：195–202.
[38] 姚强岭，王伟男，孟国胜，等. 树脂锚杆不同锚固长度锚固段受力特征试验研究[J]. 采矿与安全工程学报，2019，36(4)：643–649.(YAO Qiangling，WANG Weinan，MENG Guosheng，et al. Experimental study on mechanical characteristics of resin bolt anchoring section with different anchorage lengths[J]. Journal of Mining and Safety Engineering，2019，36(4)：643–649.(in Chinese))
[39] 王佳奇，姚直书，刘小虎，等. 温压耦合不同锚固长度锚固体受力特征及拉拔荷载传递规律研究[J]. 中南大学学报：自然科学版，2024，55(12)：4 628–4 640.(WANG Jiaqi，YAO Zhishu，LIU Xiaohu，et al. Study on stress characteristics and pull-out load transfer law of anchorage body with different anchorage length under temperature pressure coupling[J]. Journal of Central South University：Science and Technology，2024，55(12)：4 628–4 640.(in Chinese))
[40] ZHOU K，ZHAO Z Q，ZHANG P D，et al. Mechanical response characteristics and failure evolution law of anchorage body under different confining pressure gradient and anchorage length[J]. Geomechanics and Geophysics for Geo-Energy and Geo-Resources，2025，11(1)：109–109.
[41] 余涛，方勇，姚志刚，等. 隧道预应力锚杆锚固结构承载效应及围岩力学分析[J]. 岩土工程学报，2022，44(6)：1 069–1 077.(YU Tao，FANG Yong，YAO Zhigang，et al. Bearing effect of prestressed bolt-anchored structures and mechanical analysis of surrounding rock[J]. Chinese Journal of Geotechnical Engineering，2022，44(6)：1 069–1 077.(in Chinese))
[42] 康红普，崔千里，胡滨，等. 树脂锚杆锚固性能及影响因素分析[J]. 煤炭学报，2014，39(1)：1–10.( KANG Hongpu，CUI Qianli，HU Bin，et al. Analysis on anchorage performances and affecting factors of resin bolts[J]. Journal of China Coal Society，2014，39(1)：1–10.(in Chinese))
[43] XU J Q，YANG X H，JIA X M，et al. Comparative study of transverse shear characteristics of shear-yielding bolts and traditional bolts based on numerical simulations and direct shear tests[J]. Buildings，2024，14(12)：4 066.
[44] 武东阳，蔚立元，苏海健，等. 单轴压缩下加锚裂隙类岩石试块裂纹扩展试验及PFC3D模拟[J]. 岩土力学，2021，42(6)：1 681–1 692. (WU Dongyang，YU Liyuan，SU Haijian，et al. Experimental study and PFC3D simulation on crack propagation of fractured rock-like specimens with bolts under uniaxial compression[J]. Rock and Soil Mechanics，2021，42(6)：1 681–1 692.(in Chinese))
[45] JIANG Y，XIAO J，TANABASHI Y，et al. Development of an automated servo-controlled direct shear apparatus applying a constant normal stiffness condition[J]. International Journal of Rock Mechanics and Mining Sciences，2003，41：275–286.
[46] 刘日成，尹乾，杨瀚清，等. 恒定法向刚度边界条件下三维粗糙节理面循环剪切力学特性[J]. 岩石力学与工程学报，2021，40(6)：1 092–1 109.(LIU Richeng，YIN Qian，YANG Hanqing，et al. Cyclic shear mechanical properties of 3D rough joint surfaces under constant normal stiffness(CNS) boundary conditions[J]. Chinese Journal of Rock Mechanics and Engineering，2021，40(6)：1 092–1 109.(in Chinese))
[47] JIA J F，ZHAO N N，BAI Y L，et al. Bond-slip model for rebar mounted to high-strength grouting material[J]. Journal of Building Engineering，2023，74：106794.
[48] KE L，AI Z C，FENG Z，et al. Interfacial bond behavior between ribbed CFRP bars and UHPFRC：effects of anchorage length and cover thickness[J]. Engineering Structures，2023，286：116140.
[49] 中华人民共和国国家标准编写组. GB/T 35056—2018煤巷锚杆支护技术规范[S]. 北京：中国煤炭工业协会，2018.(The National Standards Compilation Group of People?s Republic of China. GB/T 35056—2018 Technical specifications for rock bolting in coal mine roadways[S]. Beijing：China National Coal Association，2018.(in Chinese))
[50] 文晓泽，冯国瑞，郭军，等. 低频扰动下高应力砂岩非线性动态力学响应特征[J]. 煤炭学报，2024，49(9)：3 810–3 828.(WEN Xiaoze，FENG Guorui，GUO Jun，et al. Nonlinear mechanical dynamic response characteristics of high stress sandstone subject to low frequency disturbance[J]. Journal of China Coal Society，2024，49(9)：3 810–3 828.(in Chinese))
[51] MA L P，LIU C Y，ZHAO G M. Rock fracture mode and acoustic emission characteristics under true triaxial single-sided unloading path[J]. Frontiers in Materials，2025，12，https://doi.org/10.3389/ fmats.2025.1557889.
[52] LI Y，ZUO J P. Measuring crack evolution in artificial rocks under different quasi-static loading rates：insights from mechanical-optical-acoustic monitoring[J]. Rock Mechanics and Rock Engineering，2025，58(12)：13 005–13 026.
[53] ZHANG Q，ZHANG X P. A numerical study on cracking processes in limestone by the b-value analysis of acoustic emissions[J]. Computers and Geotechniacs，2017，92：1–10.
[54] MA H F，SONG Y Q，YANG J K，et al. Experimental investigation on physical–mechanical behaviors and macro–micro-structural responses of lignite subjected to freeze-thaw cycles[J]. Natural Resources Research，2022，32(2)：543–566.
[55] SAGASTA F，ZITTO M E，PIOTRKOWSKI R，et al. Acoustic emission energy b-value for local damage evaluation in reinforced concrete structures subjected to seismic loadings[J]. Mechanical Systems and Signal Processing，2018，102：262–277.
[56] 刘泉声，雷广峰，彭星新，等. 节理岩体中锚杆剪切力学模型研究及试验验证[J]. 岩土工程学报，2018，40(5)：794–801.(LIU Quansheng，LEI Guangfeng，PENG Xingxin，et al. Shearing mechanical model and experimental verification of bolts in jointed rock mass[J]. Chinese Journal of Geotechnical Engineering，2018，40(5)：794–801.(in Chinese))
[57] 宋洋，范波，王贺平. 考虑法向应力与岩石强度的加锚节理岩体剪切力学模型研究[J]. 岩石力学与工程学报，2023，42(6)：1 325–1 335.(SONG Yang，FAN Bo，WANG Heping，et al. Research on shear mechanics model of anchored-jointed rock mass considering normal stress and rock strength[J]. Chinese Journal of Rock Mechanics and Engineering，2023，42(6)：1 325–1 335.(in Chinese))
[58] 冯超，刘少伟，付孟雄，等. 预应力锚索自由段剪切破坏机制研究[J]. 岩石力学与工程学报，2024，43(6)：1 468–1 479.(FENG Chao，LIU Shaowei，FU Mengxiong，et al. Research on shear failure mechanism of free section of prestressed anchor cables[J]. Chinese Journal of Rock Mechanics and Engineering，2024，43(6)：1 468–1 479. (in Chinese))
[59] LI X W，NEMCIK J，MIRZAGHORBANALI A，et al. Analytical model of shear behaviour of a fully grouted cable bolt subjected to shearing[J]. International Journal of Rock Mechanics and Mining Sciences，2015，80：31–39.
[60] LI Y Z，TANNANT D D，PANG J Y，et al. Experimental and analytical investigation of the shear resistance of a rock joint held by a fully-grouted bolt and subject to large deformations[J]. Transportation Geotechniacs，2021，31：100671.
[61] LIU C H，LI Y Z. Predicting the shear resistance contribution of passive fully grouted bolts to jointed rock[J]. International Journal of Geomechanics，2020，20，https://doi.org/10.1061/(ASCE)GM.1943-5622.0001581.
[62] PELLET F，EGGER P. Analytical model for the mechanical behaviour of bolted rock joints subjected to shearing[J]. Rock Mechanics and Rock Engineering，1996，29：73–97.
[63] JALALIFAR H，AZIZ N. Analytical behaviour of bolt–joint intersection under lateral loading conditions[J]. Rock Mechanics and Rock Engineering，2010，43(1)：89–94.