低频动载扰动下卸荷煤体力学特性及破坏模式

doi:10.3724/1000-6915.jrme.2025.0582

Abstract
Figure/Table
References (0)
Related Citation (15)

Download: PDF (5401 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS)

Abstract To address rib spalling and roof falls triggered by strong deep mining-induced disturbances, which limit the safe and efficient extraction of deep coal resources, we employed an in-house developed microcomputer-controlled electrohydraulic servo testing system for coal and rock, capable of combined static and dynamic loading with adaptive coupling. Three coupled loading paths were implemented: unloading of confining pressure (SX group), unloading under dynamic disturbance with a variable lower stress limit (BX group), and unloading under dynamic disturbance with a constant lower stress limit (HX group). We characterized the effects of low-frequency dynamic disturbance on the mechanical response and failure modes of coal during the unloading process. The results indicate that: (1) For SX group specimens, peak strain and peak stress positively correlate with confining pressure. After experiencing low-frequency dynamic disturbance, BX and HX group specimens exhibited reduced peak strain, with peak stress decreasing by 4.553% to 8.432% and 0.475% to 6.322%, respectively. Stress-volumetric-strain curves demonstrate dilatancy between 0 and 20 MPa, which initiates before the peak, followed by a compaction mechanism between 30 and 50 MPa. This transition is governed by confining pressure and remains independent of the stress path. (2) The deformation modulus experiences a three-stage evolution during unloading: a logarithmic decline, followed by linear attenuation, and finally an abrupt drop to failure. The instantaneous decay rate follows a U-shaped trajectory. When confining pressure is at or below 30 MPa, the rate of modulus degradation is highly sensitive to unloading. Under confining pressures of 40–50 MPa, low-frequency dynamic disturbances induce a sharp decline in modulus values into negative territory, followed by a rapid rebound. During unloading, the coal sample exhibits a damage mechanism characterized by transient strengthening and progressive deterioration. (3) Macroscopic failure modes are influenced by the level of confining pressure and the stress path. As confining pressure increases, SX group specimens transition from single shear to multiple shear failure, accompanied by a progressive reduction in surface tensile cracks. BX group specimens evolve from multiple shear failure to a combined multiple shear and transverse shear failure, characterized by lamellar scaly tensile and shear composite fragmentation. HX group specimens display multiple shear failure; however, at 30–50 MPa, they also exhibit significant tensile fragmentation and particle-scale pulverization. (4) Compared to SX group specimens, BX and HX group specimens show larger fluctuations in modulus values, with abrupt changes in modulus concentrated during disturbance stages I to II and III to IV, respectively. Based on analyses of acoustic emission RA and AF values, tensile cracking predominates in SX specimens. Along the BX group path, the fraction of tensile cracks increases progressively during confining pressure unloading and the early disturbance stage. Under HX group conditions，at stages III to IV, the proportions of tensile and shear cracks surge simultaneously.

Key words： rock mechanics low-frequency disturbance mechanical properties acoustic emission failure mode

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors

Cite this article:

URL:

https://rockmech.whrsm.ac.cn/EN/10.3724/1000-6915.jrme.2025.0582 OR https://rockmech.whrsm.ac.cn/EN/Y2026/V45/I1/155

1] 袁亮，吴劲松，杨科. 煤炭安全智能精准开采关键技术与应用[J]. 采矿与安全工程学报，2023，40(5)：861–868.(YUAN Liang，WU Jingsong，YANG Ke. Key technology and its application of coal safety intelligent precision mining[J]. Journal of Mining and Safety Engineering，2023，40(5)：861–868.(in Chinese))
[2] 袁亮，张通，王玥晗，等. 深部煤炭资源安全高效开采科学问题及关键技术[J]. 煤炭学报，2025，50(1)：1–12.(YUAN Liang，ZHANG Tong，WANG Yuehan，et al. Scientific issues and key technologies for safe and efficient mining of deep coal resources[J]. Journal of China Coal Society，2025，50(1)：1–12.(in Chinese))
[3] 刘超，田加宝，戚靖骅，等. 多元扰动行为下深部高应力煤体扩容与压实特性[J]. 煤炭科学技术，2025，53(10)：125–137.(LIU Chao，TIAN Jiabao，QI Jinghua，et al. Dilatancy and compaction characteristics of deep high-stressed coal under multiple disturbance behaviors[J]. Coal Science and Technology，2025，53(10)：125–137.(in Chinese))
[4] 吴文达. 浅埋煤层群上部遗留煤柱联动失稳压架机理与控制研究[博士学位论文][D]. 徐州：中国矿业大学，2020.(WU Wenda. Study on the mechanism and control of the support crushing disaster caused by interactive failure of upper residual pillars in shallow multiple coal seam[Ph. D. Thesis][D]. Xuzhou：China University of Mining and Technology，2020.(in Chinese))
[5] 吕凯，何富连，许旭辉，等. 异形载荷–弹性基础基本顶板结构破断特征及稳定性分析[J]. 岩石力学与工程学报，2023，42(4)：930–947.(LV Kai，HE Fulian，XU Xuhui，et al. Fracture characteristics and stability analysis of main roof plate structure with special-shaped load and elastic foundation[J]. Chinese Journal of Rock Mechanics and Engineering，2023，42(4)：930–947.(in Chinese))
[6] 刘殿柱，高全臣，王鑫尧. 上下交叉隧道爆破振动特性研究[J]. 北京理工大学学报，2020，40(12)：1 267–1 274.(LIU Dianzhu，GAO Quanchen，WANG Xinyao. Study on blasting vibration characteristics of up and down cross tunnels[J]. Transactions of Beijing Institute of Technology，2020，40(12)：1 267–1 274.(in Chinese))
[7] 牛同会. 分段水力压裂弱化采场坚硬顶板围岩控制技术研究[J]. 煤炭科学技术，2022，50(8)：50–59.(NIU Tonghui. Study on surrounding rock control technology for weakened hard roof of stope by staged hydraulic fracturing[J]. Coal Science and Technology，2022，50(8)：50–59.(in Chinese))
[8] 袁亮. 深部采动响应与灾害防控研究进展[J]. 煤炭学报，2021，46(3)：716–725.(YUAN Liang. Research progress of mining response and disaster prevention and control in deep coal mines[J]. Journal of China Coal Society，2021，46(3)：716–725.(in Chinese))
[9] 胡少斌，王恩元，沈荣喜. 深部煤岩动力扰动响应特征及数值分析[J]. 中国矿业大学学报，2013，42(4)：540–546.(HU Shaobin，WANG Enyuan，SHEN Rongxi. Characteristics of dynamic disturbance response in deep coal and rock and its numerical analysis[J]. Journal of China University of Mining Technology，2013，42(4)：540–546.(in Chinese))
[10] 金解放，徐虹，余雄，等. 动荷载和含水率对红砂岩破坏及能耗特性的影响[J]. 岩土力学，2022，43(12)：3 231–3 240.(JIN Jiefang，XU Hong，YU Xiong，et al. Effect of dynamic load and water content on failure and energy dissipation characteristics of red sandstone[J]. Rock and Soil Mechanics，2022，43(12)：3 231–3 240. (in Chinese))
[11] 金解放，张琦，袁伟，等. 具有轴向静应力的变截面岩石应力波频散特性[J]. 中南大学学报：自然科学版，2021，52(8)：2 622–2 633.(JIN Jiefang，ZHANG Qi，YUAN Wei，et al. Dispersion characteristics of stress wave of rod with variable cross-sectional areas under axial static stress[J]. Journal of Central South University：Science and Technology，2021，52(8)：2 622–2 633.(in Chinese))
[12] 王家臣，王兆会，唐岳松，等. 千米深井超长工作面顶板分区破断驱动机制与围岩区域化控制研究[J]. 煤炭学报，2023，48(10)：3 615–3 627.(WANG Jiachen，WANG Zhaohui，TANG Yuesong，et al. Regional failure mechanism of main roof and zonal method for ground control in kilometer-deep longwall panel with large face length[J]. Journal of China Coal Society，2023，48(10)：3 615–3 627.(in Chinese))
[13] WU W X，GONG F Q，JIAN Q. Strength weakening effect of high static pre-stressed granite subjected to low-frequency dynamic disturbance under uniaxial compression[J]. Transactions of Nonferrous Metals Society of China，2022，32(7)：2 353–2 369.
[14] 文志杰，黄景，蒋宇静，等. 动静组合循环加载试验系统研制及试验[J]. 中南大学学报：自然科学版，2021，52(8)：2 817–2 827. (WEN Zhijie，HUANG Jing，JIANG Yujing，et al. Development and experiment of a coupled static-dynamic cyclic loading test system[J]. Journal of Central South University：Science and Technology，2021，52(8)：2 817–2 827.(in Chinese))
[15] WEN X Z，FENG G R，GUO J，et al. Strength deterioration mechanism of sandstone subjected to low-frequency dynamic disturbance under the varying static pre-stress levels[J]. Rock Mechanics and Rock Engineering，2025，DOI：https://doi.org/10.1007/s00603-025-04914-w.
[16] WEN X Z，FENG G R，GUO J，et al. Dynamic characteristics of coal specimens with varying static preloading levels under low-frequency disturbance load[J]. Journal of Central South University，2024，31(8)：2 644–2 657.
[17] ZHOU X，LIU X，WANG X，et al. Failure characteristics and mechanism of coal under the coupling between different confining pressures and disturbance loading[J]. Bulletin of Engineering Geology and the Environment，2023，82(12)：442.
[18] 杨英明，陶春梅，郭奕宏，等. 动静组合加载下煤体损伤及力学特性研究[J]. 采矿与安全工程学报，2019，36(1)：198–206.(YANG Yingming，TAO Chunmei，GUO Yihong，et al. Analysis on damage and mechanical properties of coal under coupled static-dynamic loading[J]. Journal of Mining and Safety Engineering，2019，36(1)：198–206.(in Chinese))
[19] 杨圣奇，杨景，孙博文，等. 基于围压因素的分级应力扰动下砂岩损伤破裂特性试验研究[J]. 岩石力学与工程学报，2024，43(3)：542–555.(YANG Shengqi，YANG Jing，SUN Bowen，et al. Experimental study on damage and fracture characteristics of sandstone under graded stress disturbance based on confining pressure factor[J]. Chinese Journal of Rock Mechanics and Engineering，2024，43(3)：542–555.(in Chinese))
[20] 杨永波，周哲. 分级循环荷载下保护层开采扰动煤岩强度及裂隙特性研究[J]. 浙江大学学报：工学版，2022，56(12)：2 445–2 453. (YANG Yongbo，ZHOU Zhe. Strength and fracture characteristics of coal rock disturbed by protective layer mining under graded cyclic loading[J]. Journal of Zhejiang University：Engineering Science，2022，56(12)：2 445–2 453.(in Chinese))
[21] 侯志强，王宇，刘冬桥，等. 三轴疲劳–卸围压条件下大理岩力学特性试验研究[J]. 岩土力学，2020，41(5)：1 510–1 520.(HOU Zhiqiang，WANG Yu，LIU Dongqiao，et al. Experimental study of mechanical properties of marble under triaxial unloading confining pressure after fatigue loading[J]. Rock and Soil Mechanics，2020，41(5)：1 510–1 520.(in Chinese))
[22] 尹光志，李星，鲁俊，等. 深部开采动静载荷作用下复合动力灾害致灾机理研究[J]. 煤炭学报，2017，42(9)：2 316–2 326.(YIN Guangzhi，LI Xing，LU Jun，et al. Disaster-causing mechanism of compound dynamic disaster in deep mining under static and dynamic load conditions[J]. Journal of China Coal Society，2017，42(9)：2 316–2 326.(in Chinese))
[23] 冯帆，谢志伟，陈绍杰，等. 真三轴卸载–动力扰动下含裂隙砂岩破坏特性研究[J]. 岩石力学与工程学报，2025，44(3)：618–637.(FENG Fan，XIE Zhiwei，CHEN Shaojie，et al. Investigation on the failure characteristics of fissured sandstone under true triaxial unloading and dynamic disturbance condition[J]. Chinese Journal of Rock Mechanics and Engineering，2025，44(3)：618–637.(in Chinese))
[24] 鲁细根，纪洪广，余小妹，等. 三轴卸荷条件下煤体力学特性和能量耗散演化[J]. 哈尔滨工业大学学报，2022，54(2)：90–98.(LU Xigen，JI Hongguang，YU Xiaomei，et al. Mechanical characteristics and energy dissipation evolution of coal under triaxial unloading[J]. Journal of Harbin Institute of Technology，2022，54(2)：90–98.(in Chinese))
[25] ZOU P，FAN H，LIU H Q，et al. Experimental study on energy evolution and damage characteristics of unloading coal under cyclic loading[J]. Scientific Reports，2025，15(1)：16630.
[26] 吴拥政，孙卓越，付玉凯. 三维动静加载下不同长径比煤样力学特性及能量耗散规律[J]. 岩石力学与工程学报，2022，41(5)：877–888.(WU Yongzheng，SUN Zhuoyue，FU Yukai. Mechanical properties and energy dissipation laws of coal samples with different length-to-diameter ratios under 3D coupled static and dynamic loads[J]. Chinese Journal of Rock Mechanics and Engineering，2022，41(5)：877–888.(in Chinese))
[27] 陈静曦. 动、静载作用下裂纹扩展的异同点[J]. 岩土力学，1990，11(2)：73–77.(CHEN Jingxi. Similarities and differences of crack expanding under dynamic and static loadings[J]. Rock and Soil Mechanics，1990，11(2)：73–77.(in Chinese))
[28] 朱传奇，王磊，刘怀谦，等. 不同应变率下松软煤体动态压缩力学特征[J]. 煤炭科学技术，2025，53(4)：244–254.(ZHU Chuanqi，WANG Lei，LIU Huaiqian，et al. Dynamic compression mechanical properties of soft coal under different strain rates[J]. Coal Science and Technology，2025，53(4)：244–254.(in Chinese))
[29] FAIRHURST C E，HUDSON J A. 单轴压缩试验测定完整岩石应力–应变全曲线ISRM建议方法草案[J]. 岩石力学与工程学报，2000，19(6)：802–808.(FAIRHURST C E，HUDSON J A. Draft ISRM recommended method for determining complete stress-strain curve of intact rock by uniaxial compression test[J]. Chinese Journal of Rock Mechanics and Engineering，2000，19(6)：802–808.(in Chinese))
[30] LIU Z W，MA L J，DENG J J，et al. Triaxial experimental study on mechanical behavior，acoustic emission characteristics，and energy evolution of coral sand grouting consolidated body under different confining pressures[J]. Case Studies in Construction Materials，2025，22：e04600.
[31] 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))
[32] 刘汉香，叶刁瑜，别鹏飞，等. 循环加卸载过程中灰岩微细观损伤特征的试验研究[J]. 岩土力学，2024，45(3)：685–696.(LIU Hanxiang，YE Diaoyu，BIE Pengfei，et al. Experimental study of microscopic and mesoscopic damage features of limestone under cyclic loading and unloading[J]. Rock and Soil Mechanics，2024，45(3)：685–696.(in Chinese))
[33] 文晓泽，冯国瑞，王朋飞，等. 高静应力与低频扰动耦合作用下砂岩的力学响应特征[J]. 岩土力学，2022，43(12)：3 426–3 436.(WEN Xiaoze，FENG Guorui，WANG Pengfei，et al. Mechanical response of sandstone under coupling action of high static stress and low frequency disturbance[J]. Rock and Soil Mechanics，2022，43(12)：3 426–3 436.(in Chinese))
[34] 刘闽龙，陈士海，石伟民，等. 多次动态扰动下红砂岩时效变形特性研究[J]. 岩土工程学报，2022，44(10)：1 917–1 924.(LIU Minlong，CHEN Shihai，SHI Weimin，et al. Time-dependent deformation characteristics of red sandstone under multiple dynamic disturbances[J]. Chinese Journal of Geotechnical Engineering，2022，44(10)：1 917–1 924.(in Chinese))
[35] 刘众众，王汉鹏，袁亮，等. 用于动静载下含瓦斯煤损伤机制研究的三轴固气耦合试验仪[J]. 采矿与安全工程学报，2022，39(6)：1 272–1 280.(LIU Zhongzhong，WANG Hanpeng，YUAN Liang，et al. Triaxial solid-gas coupling tester for studying the damage mechanism of gas-bearing coal under dynamic and static loads[J]. Journal of Mining and Safety Engineering，2022，39(6)：1 272–1 280. (in Chinese))
[36] WU Y F，WANG Y，LI C H，et al. Effect of loading rate on the mechanical response and energy evolution of skarn rock subjected to constant-amplitude cyclic loading[J]. Journal of Central South University，2025，32(3)：1 117–1 140.
[37] 刘斌，席道瑛，葛宁洁，等. 不同围压下岩石中泊松比的各向异性[J]. 地球物理学报，2002，45(6)：880–890.(LIU Bin，XI Daoying，GE Ningjie，et al. Anisotropy of Poisson's ratio in rock samples under confining pressures[J]. Chinese Journal of Geophysics，2002，45(6)：880–890.(in Chinese))
[38] 李地元，孙志，李夕兵，等. 不同应力路径下花岗岩三轴加卸载力学响应及其破坏特征[J]. 岩石力学与工程学报，2016，35(增2)：3 449–3 457.(LI Diyuan，SUN Zhi，LI Xibing，et al. Mechanical response and failure characteristics of granite under different stress paths in triaxial loading and unloading conditions[J]. Chinese Journal of Rock Mechanics and Engineering，2016，35(Supp.2)：3 449–3 457.(in Chinese))
[39] 范浩，王磊，王连国. 不同应力路径下层理煤体力学特性试验研究[J]. 岩土力学，2024，45(2)：385–395.(FAN Hao，WANG Lei，WANG Lianguo. Experimental study on mechanical properties of bedding coal under different stress paths[J]. Rock and Soil Mechanics，2024，45(2)：385–395.(in Chinese))
[40] 肖福坤，刘刚，秦涛，等. 拉–压–剪应力下细砂岩和粗砂岩破裂过程声发射特性研究[J]. 岩石力学与工程学报，2016，35(增2)：3 458–3 472.(XIAO Fukun，LIU Gang，QIN Tao，et al. Acoustic emission(AE) characteristics of fine sandstone and coarse sandstone fracture process under tension-compression-shear stress[J]. Chinese Journal of Rock Mechanics and Engineering，2016，35(Supp.2)：3 458–3 472.(in Chinese))
[41] Federation of Construction Materials Industries. JCMS–III B5706 Monitoring method for active cracks in concrete by acoustic emission[S]. Japan：Federation of Construction Materials Industries，2003.
[42] GAO S，WU F，GAO R B，et al. Damage behavior of red sandstone subjected to multi-stage constant-amplitude cyclic loading[J]. Journal of Rock Mechanics and Geotechnical Engineering，2025，17(10)：6 548–6 570.
[43] ZHOU X，LIU X，WANG X，et al. Acoustic emission characteristics of coal failure under triaxial loading and unloading disturbance[J]. Rock Mechanics and Rock Engineering，2023，56(2)：1 043–1 061.
[44] WONG T，BAUD P. The brittle-ductile transition in porous rock：A review[J]. Journal of Structural Geology，2012，44：25–53.
[45] 陈旭，肖义，汤明高，等. 多级等幅循环荷载作用下砂岩变形、渗透及声发射特征试验研究[J]. 岩石力学与工程学报，2024，43(8)：1 923–1 935.(CHEN Xu，XIAO Yi，TANG Minggao，et al. Experimental study on deformation，permeability and AE characteristics of sandstone under multi-stage cyclic loading with a constant amplitude[J]. Chinese Journal of Rock Mechanics and Engineering，2024，43(8)：1 923–1 935.(in Chinese))
[46] 曾正文，马瑾，刘力强，等. 岩石破裂扩展过程中的声发射b值动态特征及意义[J]. 地震地质，1995，17(1)：7–12.(ZENG Zhengwen，MA Jin，LIU Liqiang，et al. AE b-value dynamic features during rock mass fracturing and their significances[J]. Seismology and Geology，1995，17(1)：7–12.(in Chinese))
[47] 董陇军，张义涵，孙道元，等. 花岗岩破裂的声发射阶段特征及裂纹不稳定扩展状态识别[J]. 岩石力学与工程学报，2022，41(1)：120–131.(DONG Longjun，ZHANG Yihan，SUN Daoyuan，et al. Stage characteristics of acoustic emission and identification of unstable crack state for granite fractures[J]. Chinese Journal of Rock Mechanics and Engineering，2022，41(1)：120–131.(in Chinese))
[48] BOBET A，EINSTEIN H H. Fracture coalescence in rock-type materials under uniaxial and biaxial compression[J]. International Journal of Rock Mechanics and Mining Sciences，1998，35(7)：863–888.
[49] LOCKNER D A，MOORE D E，RECHES Z E E. Microcrack interaction leading to shear fracture[C]// The 33rd US Symposium on Rock Mechanics(USRMS). [S. l.]：[s. n.]，1992：807–816.
[50] 许永祥，王国法，李明忠，等. 超大采高综放开采煤壁板裂化片帮机理研究[J]. 采矿与安全工程学报，2021，38(1)：19–30.(XU Yongxiang，WANG Guofa，LI Mingzhong，et al. Mechanism of slabbed spalling failure of the coal face in fully mechanized caving face with super large cutting height[J]. Journal of Mining and Safety Engineering，2021，38(1)：19–30.(in Chinese))