地下空间与工程学报 >

2026 , Vol. 22 >Issue 2: 583 - 591

DOI: https://doi.org/10.20174/j.JUSE.2026.02.20

理论与试验研究

基于纳米压痕试验的煤岩力学性能层理效应研究

  • 张超鹏 ,
  • 陈立超 ,
  • 马代兵 ,
  • 李世兵 ,
  • 刘敬丹
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  • 1.内蒙古工业大学 资源与环境工程学院,呼和浩特 010051;
    2.煤与煤层气共采全国重点实验室,山西 晋城 048012;
    3.甘肃煤田地质局一四九队,兰州 730020;
    4.甘肃科贝德煤与煤层气开发技术有限公司,兰州 730080
张超鹏(2000—),男,吉林白山人,硕士,主要从事储层岩石力学研究。E-mail:1049298745@qq.com
陈立超(1985—),男,内蒙古赤峰人,博士,副教授,主要从事非常规油气地质力学研究。E-mail:chenlichaogas@163.com

收稿日期: 2025-05-08

  网络出版日期: 2026-04-28

基金资助

中央引导地方科技发展资金项目(23ZYQA319);内蒙古自治区重点研发和成果转化计划项目(2023YFSH0005);中央引导地方科技发展资金项目(2024ZY0008);内蒙古自治区财政出资地质勘查项目(25-1-NY01)

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Bedding Effect of the Mechanical Properties of Coal Based on Nanoindentation Test

  • Zhang Chaopeng ,
  • Chen Lichao ,
  • Ma Daibing ,
  • Li Shibing ,
  • Liu Jingdan
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  • 1. School of Resources and Environmental Engineering, Inner Mongolia University of Technology, Hohhot 010051, P.R. China;
    2. National Key Laboratory of Coal and Coalbed Methane Mining, Jincheng, Shanxi 048012, P.R. China;
    3. Team 149th, Gansu Coalfield Geology Bureau, Lanzhou 730020, P.R. China;
    4. Gansu Coalbed Coal and Coalbed Methane Development Technology Co., Ltd., Lanzhou 730080, P.R. China

Received date: 2025-05-08

  Online published: 2026-04-28

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摘要

为探究层理效应对煤岩力学性能的影响,基于纳米压痕试验对煤岩不同层理方向的微观力学性能展开研究。通过绘制各组试样的荷载-位移曲线,获取不同层理方位煤岩的微观力学参数并分析煤岩破坏模式,进一步探讨煤岩水力压裂裂缝延展规律。研究表明:煤岩的微观结构致密,层理结构清晰,层理间填充有石英等坚硬矿物,伴随一定量的天然微裂缝和自生孔隙发育;通过纳米压痕试验,发现煤岩试样具有明显的各向异性,垂直层理、平行层理、斜交层理煤岩的弹性模量依次为5.02 GPa、4.58 GPa、4.92 GPa,硬度分别为0.38 GPa、0.35 GPa、0.37 GPa;煤岩的弹性模量和硬度大小符合其宏观力学规律;在不同方向上的破坏能量耗散特征方面,垂直层理煤岩所需的断裂能量最大,平行层理煤岩断裂能量耗散最小,断裂韧度依次为0.25、0.22、0.23 MPa·m0.5;煤岩的脆性系数随着不同方向破坏形式的差异而变化;基于纳米压痕试验数据,揭示了不同层理方向下裂缝的扩展特征,垂直层理方向裂缝沿天然缝隙扩展,平行层理裂缝主要沿层理弱面发展,而斜交层理则表现出裂缝在向深部延伸过程中更易产生分支。研究结果可为煤岩的工程应用提供数据支持。

关键词: 纳米压痕; 煤岩力学; 层理; 各向异性; 压裂裂缝延展; 窑街矿区

本文引用格式

张超鹏 , 陈立超 , 马代兵 , 李世兵 , 刘敬丹 . 基于纳米压痕试验的煤岩力学性能层理效应研究[J]. 地下空间与工程学报, 2026 , 22(2) : 583 -591 . DOI: 10.20174/j.JUSE.2026.02.20

Abstract

To explore the influence of coal and rock bedding plane effects on mechanical properties, the micro-mechanical properties of coal and rock with different bedding directions are studied based on nanoindentation tests. By plotting the load-displacement curves of each group of samples, the micro-mechanical parameters of coal and rock with different bedding orientations are obtained and the failure modes of coal and rock are analyzed. Furthermore, the propagation laws of hydraulic fracturing fractures in coal and rock are discussed. The research shows that the microstructure of coal and rock is dense, the bedding structure is clear, and the bedding planes are filled with hard minerals such as quartz, accompanied by a certain amount of natural micro-cracks and developed self-generated pores. Through nanoindentation tests, it is found that the coal and rock samples have obvious anisotropy. The elastic modulus of coal and rock perpendicular to the bedding plane, parallel to the bedding plane, and at an oblique angle to the bedding plane are 5.02 GPa, 4.58 GPa, and 4.92 GPa, respectively, and the hardness is 0.38 GPa, 0.35 GPa, and 0.37 GPa, respectively. The elastic modulus and hardness of coal and rock are consistent with their macroscopic mechanical laws. In terms of the energy dissipation characteristics of failure in different directions, the coal and rock perpendicular to the bedding plane require the largest fracture energy, while the coal and rock parallel to the bedding plane have the smallest fracture energy dissipation. In addition, the fracture toughness is 0.25, 0.22, and 0.23 MPa·m0.5, respectively. The brittleness coefficient of coal and rock varies with the differences in failure forms in different directions. Based on the nanoindentation test data, the propagation characteristics of fractures under different bedding directions are revealed. Fractures in the direction perpendicular to the bedding plane extend along natural fissures, fractures parallel to the bedding plane mainly develop along the weak bedding plane, and fractures at an oblique angle to the bedding plane are more prone to branching during the deep extension process. The research results provide scientific data support for the engineering application of coal and rock, offer important references for engineering design, construction, monitoring and optimization, and have the potential to improve the safety and economy of engineering, contributing to sustainable development.

Key words: nanoindentation; coal mechanics; bedding; anisotropy; fracture extension; Yaojie mining area

参考文献

[1] 赵洪宝, 李振华, 仲淑姮, 等. 单轴压缩状态下含瓦斯煤岩力学特性试验研究[J].采矿与安全工程学报,2010,27(1):131-134.(Zhao Hongbao, Li Zhenhua, Zhong Shuheng, et al. Experimental study of mechanical properties of coal rock containing gas under uniaxial compression[J].Journal of Mining & Safety Engineering,2010,27(1):131-134.(in Chinese))
[2] 段敏克, 蒋长宝, 郭现伟, 等. 真三轴循环载荷作用下煤岩力学及损伤特征试验研究[J].岩石力学与工程学报,2021,40(6):1110-1118.(Duan Minke, Jiang Changbao,Guo Xianwei, et al. Experimental study on mechanical and damage characteristics of coal under cyclic true triaxial loading[J].Chinese Journal of Rock Mechanics and Engineering,2021,40(6):1110-1118.(in Chinese))
[3] 刘恺德,刘泉声,朱元广, 等. 考虑层理方向效应煤岩巴西劈裂及单轴压缩试验研究[J].岩石力学与工程学报,2013,32(2):308-316.(Liu Kaide, Liu Quansheng, Zhu Yuanguang, et al. Experimental study of coal considering directivity effect of Brazil splitting on the underlying bedding plane Uniaxial compression[J].Chinese Journal of Rock Mechanics and Engineering,2013,32(2):308-316.(in Chinese))
[4] 武鹏飞,梁卫国,曹孟涛,等.煤体在不同层理方位Ⅰ型断裂特征试验研究[J].地下空间与工程学报,2017,13(增2):538-545.(Wu Pengfei, Liang Weiguo, Cao Mengtao, et al. Experimental investigation on model Ⅰ fracture characteristics of coal in different stratification orientation[J].Chinese Journal of Underground Space and Engineering,2017,13(Supp.2):538-545.(in Chinese))
[5] Meng J Q, Cao Z H, Zhang S, et al. Micro-mechanical properties and damage mechanisms of coal under cyclic loading: A nanoindentation experiment and molecular dynamics simulation[J].Molecular Simulation,2022,48(4):354-365.
[6] 郭敬杰,李伟,韩祥凯等.基于纳米压痕的构造煤与原生煤结构面力学特性[J].中国矿业大学学报,2024(3):509-523.(Guo Jingjie, Li Wei, Han Xiangkai, et al. Mechanical properties of structural plane of structural coal and primary coal based on nanoindentation[J].Journal of China University of Mining & Technology,2024(3):509-523.(in Chinese))
[7] 蔡益栋,贾丁,邱峰,等.基于纳米压痕的煤岩微观力学特性及其影响因素剖析[J].煤炭学报,2023,48(2):879-890.(Cai Yidong, Jia Ding, Qiu Feng, et al.Micromechanical properties of coal and its influencing factors based on nanoindentation[J].Journal of China Coal Society,2023,48(2):879-890.(in Chinese))
[8] 刘鹏,赵渝龙,聂百胜,等.煤体微观力学特性的纳米压痕实验研究[J].煤炭学报,2024,49(8):3453-3467.(Liu Peng, Zhao Yulong, Nie Baisheng, et al. Experimental study on micromechanical properties of coal by nanoindentation[J].Journal of China Coal Society,2024,49(8):3453-3467.(in Chinese))
[9] Elena K, Svetlana E, Vera K, et al.Effects of coals microscale structural features on their mechanical properties,propensity to crushing and fine dust formation[J].International Journal of Coal Science & Technology,2023,10(2):146-158.
[10] Xie H G, Li X J. Microstructure and nanomechanical characterization of tectonic coal based on SEM, AFM, XRD and DSI[J].Surfaces and Interfaces,2024,46: 104158
[11] Meng J Q, Lyu C H, Wang J, et al. Mechanical properties and failure mechanisms of different rank coals at the nanoscale[J].Fuel,2023,345(1):128209.
[12] Borodich F, Bull S, Epshtein S A. Nanoindentation in studying mechanical properties of heterogeneous materials[J].Journal of Mining Science,2015,51(3):470-476.
[13] Zhang G L, Ranjith P, Lyu Q, et al. Direct evidence of CO2 softening effects on coal using nanoindentation[J].Energy,2022,254:124221.
[14] Fender T, Rouainia M, Vander L, et al. Geomechanical properties of coal macerals; measurements applicable to modelling swelling of coal seams during CO2 sequestration[J].International Journal of Coal Geology, 2020, 228: 103528.
[15] Sun C L, Li G C, Zhang S H, et al. Mechanical and heterogeneous properties of coal and rock quantified and mapped at the microscale[J].Applied Sciences-Basel, 2020, 10(1): 342-342.
[16] Manjunath G, Jha Birendra. Geomechanical characterization of gondwana shale across nano-micro-meso scales[J].International Journal of Rock Mechanics and Mining Sciences,2019,119: 35-45.
[17] 张震,庞学玉,马朝阳,等.水灰比对油井水泥石微观性能影响的试验研究[J].地下空间与工程学报,2023,19(2):521-532.(Zhang Zhen, Pang Xueyu, Ma Chayang, et al.Experimental research on the impact of water-cement ratio on microscopic properties of oil well cement slurry[J].Chinese Journal of Underground Space and Engineering,2023,19(2):521-532.(in Chinese))
[18] 柳先锋.煤表面微结构特征与电磁辐射机理研究[D].北京:中国矿业大学(北京),2018.(Liu Xianfeng.Study on microstructural characteristics of coal surface and the mechanism of electromagnetic radiation[D]. Beijing: China University of Mining & Technology, Beijing, 2018.(in Chinese))
[19] Wu D,Li B,Wu J, et al.Influence of mineral composition on rock mechanics properties and brittleness evaluation of surrounding rocks in soft coal seams[J].ACS OMEGA,2023,9(1):1375-1388.
[20] 王耀城,刘定坤,刘伟,等. 纳米压痕测试技术在GFRP材料中的应用综述[J]. 材料导报,2021,35(19):19214-19222. (Wang Yaocheng, Liu Dingkun, Liu Wei, et al.A Review:Application of nanoindentation testing technology in GFRP materials[J]. Materials Reports,2021,35(19):19214-19222. (in Chinese))
[21] 党发宁,高天晴,原诗晶, 等. 化学环境对灰岩力学性能影响的纳米压痕试验研究[J].岩石力学与工程学报,2022,41(增2):3260-3270.(Dang Fanning, Gao Tianqing, Yuan Shijing, et al. Nanoindentation test study on the influence of chemical environment on the mechanical properties of limestone[J].Chinese Journal of Rock Mechanics and Engineering,2022,41(Supp.2):3260-3270.(in Chinese))
[22] 冯莹,彭宇,徐世烺, 等. 钢纤维砂浆纳米压痕微观断裂性能表征[J].硅酸盐学报,2018,46(11):1593-1602.(Feng Ying, Peng Yu, Xu Shilang, et al. Micro fracture characterization of steel fiber reinforced mortar by nanoindentation[J].Journal of the Chinese Ceramic Society,2018,46(11):1593-1602.(in Chinese))
[23] 董京楠,金衍,陈勉,等.页岩Ⅰ型断裂韧性测试及跨尺度裂缝表征研究[J].地下空间与工程学报,2019,15(增1):205-210.(Dong Jingnan,Jin Yan,Chen Miane,et al.Study on shale fracture toughness and micro-characterizationof mode Ⅰ crack using DCB specimen and SEM method [J].Chinese Journal of Underground Space and Engineering,2019,15(Supp.1):205-210.(in Chinese))
[24] 李晓照,柴博聪,戚承志,等.高温热处理后的脆性岩石蠕变宏细观断裂力学机理[J].地下空间与工程学报,2025,21(5):1514-1524.(Li Xiaozhao, Chai Bocong, Qi Chengzhi,et al.Macro-meso fracture mechanical mechanisms of creep in brittle rocks after high-temperature heat treatment[J].Chinese Journal of Underground Space and Engineering,2025,21(5):1514-1524.(in Chinese))
[25] 何智海,倪雅倩,杜时贵, 等. 纳米压痕技术在岩石材料中的应用与研究进展[J].岩石力学与工程学报,2022,41(10):2045-2066.(He Zhihai, Nie Yaqian, Du Shigui, et al.Application and research progress of nanoindentation technology in rock materials[J].Chinese Journal of Rock Mechanics and Engineering,2022,41(10):2045-2066.(in Chinese))
[26] Gupta I, Sondergeld C, Rai C. Fracture toughness in shales using nano-indentation[J].Journal of Petroleum Science And Engineering,2020,191: 107222.
[27] 陈立超,张典坤,肖宇航,等. 页岩微观力学纳米压痕表征及储层可压裂性评价[J].煤炭学报,2025,50(3):1659-1667.(Chen Lichao, Zhang Diankun,Xiao Yuhang, et al.Nanoindentation characterization of Shale micromechanics and fracturing ability evaluation of reservoir[J].China Coal Society, 2025, 50(3): 1659-1667.(in Chinese))
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