不同因素影响下煤岩组合锚固体锚杆锚固性能研究

doi:10. 11799/ ce202505018

摘要/Abstract

摘要：

为了提高煤岩巷道复杂地质条件下锚固支护效果，针对煤岩巷道支护中锚杆锚固性能的关键影响因素展开了相关研究。首先，获取了典型矿井不同煤层及顶底板岩层的物理力学参数，并结合空心包体应力解除法测得巷道地应力分布；接着, 基于实测数据建立数值模型，反演掘采过程中锚杆工作环境的应力状态，确定围压范围为0~15 MPa；然后，通过室内试验系统地分析了不同煤岩强度比（1∶2、1∶3、1∶4、1∶5）、围压条件（0、5、10 和15MPa）以及穿层锚固方式（煤-岩、岩-煤）对煤岩组合锚固体锚杆承载性能的影响规律。研究结果表明：随着煤岩强度比的增加，锚杆的极限拉拔载荷显著提升，从1∶2条件下的45.4kN增长到1∶5条件下的68.79kN；围压增大能有效增强锚固体稳定性，极限载荷从0 MPa时的34.52kN提升至15MPa时的77.55kN；煤-岩穿层方式相比于岩-煤方式具有更优的锚固性能，极限拉拔载荷较岩-煤试样提高28.3%，并且在残余承载阶段没有明显的二次破坏。

关键词:

煤岩组合锚固体 , 拉拔试验 , 锚固性能 , 声发射

Abstract: The geological conditions of coal-rock roadways are complex, and the anchoring performance of bolts across layers is constrained by multiple factors, leading to suboptimal support effectiveness. This study focuses on the key influencing factors of bolt anchoring performance in coal-rock roadway support. Firstly, the physical and mechanical parameters of different coal seams and roof-floor strata in typical mines were obtained, combined with the hollow inclusion stress relief method to measure in-situ stress distribution within the roadway. Based on field data, a numerical model was established to invert the stress state of the bolt working environment during excavation and mining, determining a confining pressure range of 0–15 MPa. Through laboratory tests, the influence patterns of different coal-rock strength ratios (1:2, 1:3, 1:4, 1:5), confining pressures (0, 5, 10, 15 MPa), and cross-layer anchoring methods (coal-to-rock, rock-to-coal) on the load-bearing performance of coal-rock composite anchorages were systematically analysed. The results indicate that: Increasing the coal-rock strength ratio significantly enhances the ultimate pull-out load of bolts (from 45.4 kN at 1:2 to 68.79 kN at 1:5); Higher confining pressure effectively improves anchorage stability (ultimate load increases from 34.52 kN at 0 MPa to 77.55 kN at 15 MPa); The coal-to-rock anchoring method demonstrates superior performance compared to rock-to-coal, exhibiting delayed interface debonding and higher residual strength. These findings provide theoretical and experimental support for bolt support design in coal-rock roadways under complex geological conditions.

中图分类号:

TD353

赵芳昊, 高林, 赵爽, 等.

不同因素影响下煤岩组合锚固体锚杆锚固性能研究 [J]. 煤炭工程, 2025, 57(5): 132-139.

参考文献

[1]高林.缓倾斜煤层沿空半煤岩巷非对称变形破坏机理及控制技术[D].北京:中国矿业大学(北京), 2020. [2]Pandong Zhang, Lin Gao, Xiaohe Wang, et al.Tensile Bearing Performance and Mechanical Transfer Mechanism of Coal-Rock Composite Anchor Bodies Under Different Height Ratios of Rock to Coal[J]. Rock Mechanics and Rock Engineering, 2024(2024). [3]康红普.我国煤矿巷道锚杆支护技术发展年及展望[J].中国矿业大学学报, 2016, 45(06):1071-1081 [4]KANG Hongpu.Sixty years development and prosepects of rock bolting technology for underground coal mine roadways in China[J].Journal of China University of Mining& Technology, 2016, 45(06):1071-1081 [5]康红普, 林健, 吴拥政, 等.锚杆构件力学性能及匹配性[J].煤炭学报, 2015, 40(1):11- [6]KANG Hongpu, LIN Jian, WU Yongzheng, et al.Mechanical performances and compatibility of rock bolt components[J].Journal of China Coal Society, 2015, 40(1):11- [7]申艳梅, 韦四江.回采巷道锚杆支护效果模糊综合评判[J].采矿与安全工程学报, 2011, 28(04):576-580 [8]SHEN Yanmei, WEI Sijiang.Fuzzy Comprehensive Evaluation of Bolt Support Effects in Deep-Minging Gateway[J].Journal of Minging& Safety Engineering, 2011, 28(04):576-580 [9]战新宇.煤岩组合锚固体承载性能的界面结构效应[D].贵州大学, 2024. [10]张盼栋.煤岩组合锚固支护体承载作用机制研究[D].贵州大学, 2023. [11]余伟健，冯涛，王卫军，等.南方复杂条件下的薄煤层开采巷道围岩支护问题及对策[J].煤炭学报, 2015, 40(10):2370-2379 [12]Yu Weijian, Feng Tao, Wang Weijun, et al.Support problems and solutions of roadway surrounding rock for thin coal seams under complex conditions in Southern China[J].Journal of China Coal Society, 2015, 40(10):2370- [13]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(06):1301-1315 [14]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(06):1301-1315 [15]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(06):1325-1335 [16]SONG Yang, FAN Bo, WANG Heping.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(06):1325-1335 [17]余伟健, 吴根水, 刘泽, 等.煤-岩-锚组合锚固体单轴压缩试验及锚杆力学机制[J].岩石力学与工程学报, 2020, 39(01):57-68 [18]YU Weijian, WU Genshui, LIU Ze, et al.Uniaxial compression test of coal-rock-bolt anchorage body and mechanical mechanisms of bolts[J].Chinese Journal of Rock Mechanics and Engineering, 2020, 39(01):57-68 [19]Yu WJ, Wu GS, Pan B, et al.Laboratory and field investigations of different bolting configurations for coal mine roadways in weak coal strata[J]. Bulletin of Engineering Geology and the Environ-ment, 2021, 80(12). [20]Wu GS, Yu WJ, Zuo JP, et al.Experimental and theoretical in-vestigation on mechanisms performance of the rock-coal-bolt (RCB) composite system[J].International Journal of Mining Science and Technology, 2020, 30(06):759-768 [21]薛飞, 林锺钦, 尉伟峰, 等.不同围岩刚度条件下锚杆的锚固性能与失效机制研究[J].采矿与岩层控制工程学报, 2024, 6(06):89-100 [22]XUE Fei, LIN Zhongqin, WEI Weifeng, et al.Study on anchoring performance and failure mechanism of rock bolts under different stiffness conditions of surrounding rock[J].Journal of Mining and Strata Control Engineering, 2024, 6(6):063022- [23]王彤彤, 刘文龙, 曹立雪, 等.浅埋隧道预应力锚固体承载效应模型实验研究[J].矿业科学学报, 2024, 9(03):370-380 [24]WANG Tongtong, LIU Wenlong, CAO Lixue, et al.Model test study on bearing effect prestressing anchors in shallow buried tunnels,[J].Journal of Mining Science and Technology, 2024, 9(03):370-380 [25]孙克国, 许炜萍, 黄谦, 等.预应力锚杆拉拔力学特性及临界锚固长度研究[J].岩石力学与工程学报, 2024, 43(03):653-669 [26]SUN Keguo, XU Weiping, HUANG Qian, et al.Study on pull-out mechanical characteristics and critical anchorage length of prestressed anchor bolts[J].Chinese Journal of Rock Mechanics and Engineering, 2024, 43(03):653-669 [27]黄明华, 周智, 欧进萍.全长黏结式锚杆锚固段荷载传递机制非线性分析[J].岩石力学与工程学报, 2014, 33(S2):3992- [28]HUANG Minghua, ZHOU Zhi, OU Jinping.Nonlinear analysis on load transfer mechanism of wholly grouted anchor rod along anchoring section[J].Chinese Journal of Rock Mechanics and Engineering, 2014, 33(S2):3992- [29]黄明华, 周智, 欧进萍.拉力型锚杆锚固段拉拔受力的非线性全历程分析[J].岩石力学与工程学报, 2014, 33(11):2190- [30]HUANG Minghua, ZHOU Zhi, OU Jinping.Nonlinear full-range analysis of load transfer in fixed segment of tensile anchors[J].Chinese Journal of Rock Mechanics and Engineering, 2014, 33(11):2190- [31]FENG X, ZHANG N, WEN Z.Mechanical responses and acoustic emission properties of bolting system under short encapsulation cyclic thrust tests[J]. International Journal of Fatigue, 2019, 121: 39?54. [32]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- [33]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 & Safety Engineering, 2019, 36(4):643- [34]TEYMEN A, KILI? A.Effect of grout strength on the stress distribution(tensile) of fully-grouted rockbolts[J]. Tunnelling and Underground Space Technology, 2018, 77: 280?287. [35]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- [36]WANG Hongtao, WANG Qi, WANG Fuqi, et al.Me chanical effect analysis of bolts in roadway under differ ent anchoring lengths and its application[J].Journal of China Coal Society, 2015, 40(3):509- [37]董双勇.围压作用下锚杆锚固性能及其影响因素研究[D]. 煤炭科学研究总院, 2021. [38]战新宇, 高林, 赵芳昊, 等.大相似比模型试验用超高强相似材料配比试验研究[J].煤田地质与勘探, 2023, 51(11):109-118 [39]ZHAN Xinyu, GAO Lin, ZHAO Fanghao, et al.Experimental study on proportioning of ultra-high strength similar materials for large similarity ratio model tests[J].Coal Geology & Exploration, 2023, 51(11):109-