岩土力学 ›› 2025, Vol. 46 ›› Issue (9): 2773-2791.doi: 10.16285/j.rsm.2024.1424CSTR: 32223.14.j.rsm.2024.1424

• 基础理论与实验研究 • 上一篇    下一篇

循环加卸载下裂隙砂岩声−热响应特征及前兆规律

刘一鸣1, 2,李振1, 3,冯国瑞4, 5,杨鹏6,白锦文4,黄炳雄1,李东7   

  1. 1. 太原理工大学 安全与应急管理工程学院,山西 太原 030024;2. 共青团临县委员会 山西 吕梁 033200; 3. 安徽理工大学 安徽省关闭/废弃矿井资源开发利用工程研究中心,安徽 淮南 232001;4. 太原理工大学 矿业工程学院,山西 太原 030024; 5. 山西能源学院,山西 晋中 030600;6. 山西工程科技职业大学 安全与应急管理学院,山西 晋中 030619; 7. 华北科技学院 矿山安全学院,河北 廊坊 065201
  • 收稿日期:2024-11-14 接受日期:2025-02-26 出版日期:2025-09-10 发布日期:2025-09-04
  • 通讯作者: 李振,男,1988年生,博士,副教授,博士生导师,主要从事矿山岩体力学与矿井瓦斯抽采研究。E-mail: lizhen3345@163.com
  • 作者简介:刘一鸣,男,2001年生,硕士研究生,主要从事岩体力学与矿井瓦斯抽采研究。E-mail: liuyiming0033@163.com
  • 基金资助:
    国家自然科学基金项目(No.52474141);国家自然科学青年科学基金项目(A类延续资助)(No.52525401);山西省基础研究计划(No.202403021211069);安徽省关闭/废弃矿井资源开发利用工程研究中心开放课题(No.EUCMR202402);三晋英才青年拔尖人才项目。

Acoustic-thermal response characteristics and precursor law of fissured sandstone under cyclic loading and unloading

LIU Yi-ming1, 2, LI Zhen1, 3, FENG Guo-rui4, 5, YANG Peng6, BAI Jin-wen4, HUANG Bing-xiong1, LI Dong7   

  1. 1. College of Safety and Emergency Management Engineering, Taiyuan University of Technology, Taiyuan, Shanxi 030024, China; 2. Communist Youth League Linxian Committee, Lüliang, Shanxi 033200, China; 3. Anhui Engineering Research Center of Exploitation and Utilization of Closed/Abandoned Mine Resources, Anhui University of Science and Technology, Huainan, Anhui 232001, China; 4. College of Mining Engineering, Taiyuan University of Technology, Taiyuan, Shanxi 030024, China; 5. Shanxi Institute of Energy, Jinzhong, Shanxi 030600, China; 6.College of Safety and Emergency Management, Shanxi Vocational University of Engineering Science and Technology, Jinzhong, Shanxi 030619, China; 7. College of Mine Safety, North China Institute of Science and Technology, Langfang, Hebei 065201, China
  • Received:2024-11-14 Accepted:2025-02-26 Online:2025-09-10 Published:2025-09-04
  • Supported by:
    This work was supported by the National Natural Science Foundation of China (52474141), the Young Scholar Program (Category A Continuation Funding) of National Natural Science Foundation of China (52525401), the Fundamental Research Program of Shanxi Province (202403021211069), the Open Project of Anhui Engineering Research Center of Exploitation and Utilization of Closed/Abandoned Mine Resources (EUCMR202402) and the Top Young Talents of Shanxi“Three Jin”Talents Program.

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摘要: 岩体损伤破坏是其内部裂隙萌生、扩展、归合的必然结果,此过程中可由声发射和红外辐射信号变化表征,因此研究裂隙岩体损伤破坏过程的声−热响应特征具有重要意义。为探究循环加卸载下裂隙砂岩破坏过程中裂纹扩展的声−热响应特征及其前兆规律,开展了含不同倾角预制裂隙砂岩的循环加卸载试验,分析了裂纹扩展过程的声−热响应特征,揭示了声、热各类信号的前兆规律,提出了声−热裂纹演化变异系数指标。主要结论如下:(1)随裂隙倾角增大,剪切作用对试样的破坏效果越来越显著,红外和声发射信号在加卸载过程中皆表现出明显的阶段性特征。(2)随循环加卸载次数的增加,各类声、热信号前兆规律随之出现,具体表现为:预制裂隙周边均出现较大能量声发射定位点,红外热像则出现温度异常带;平均红外温度出现突变,声发射计数突增,声发射上升时间与振幅之比RA、振铃计数与持续时间之比AF值在卸载阶段仍有较大值及较密集分布。(3)红外温度与声发射RA、AF异常出现最早,声发射定位次之,声发射计数再次之,红外热像最晚,声发射定位和热像异常还可以从空间上预警裂纹产生。(4)提出了裂纹演化的声−热变异系数指标,该指标综合了裂纹演化特征并优化了权重比率,可反映区段时间内声、热参数波动的大小,进一步表征裂纹演化的剧烈程度,该指标避免了单一声信号的滞后性和单一红外信号的空间局限性。相关研究可为岩体灾变机制、岩层控制、地质灾害防治等提供重要参考。

关键词: 岩石力学, 裂隙岩石, 裂纹扩展, 声发射, 热红外, 变异系数

Abstract: The damage and failure of a rock mass is the inevitable consequence of the initiation, propagation, and coalescence of internal cracks within it. This process can be characterized by changes in acoustic emission and infrared radiation signals, highlighting the importance of studying the acoustic-thermal response characteristics of the damage evolution in fissured rock masses. To investigate the acoustic-thermal response characteristics of crack extension and its precursor law during the cyclic loading and unloading of fissured sandstone, tests were conducted on prefabricated fissured sandstone with varying crack inclination angles. The study analyzed the acoustic-thermal response characteristics of crack propagation, identified precursor laws of various acoustic and thermal signals, and proposed a coefficient of variation index to quantify crack evolution. The main conclusions are as follows: 1) As fissure dip angles increases, the shear-induced damage effect on the specimen becomes more pronounced, with infrared and acoustic emission signals exhibiting distinct stage characteristics during loading and unloading. 2) With increasing cyclic loading and unloading cycles, precursor laws of acoustic and thermal signals became evident, characterized by prefabricated cracks forming around high-energy acoustic emission localization points, accompanied by infrared thermal image temperature anomalies; a sudden change in acoustic emission counts, RA(the ratio of acoustic emission rise time to amplitude), and AF(the ratio of ring counts to duration time) values during unloading, with these parameters maintaining higher values and more concentrated distributions. 3) Infrared temperature and acoustic emission RA, AF anomalies appear earliest, followed by acoustic emission localization. Acoustic emission counts show changes later, with infrared thermal images being the latest indicators. Acoustic emission localization and thermal image anomalies can provide spatial early warnings of crack formation. 4) A novel acoustic-thermal coefficient of variation (CV) index is proposed to quantify crack evolution. This index integrates crack evolution characteristics, optimizes weighting ratios, and reflects fluctuations in acoustic and thermal parameters over time, thereby characterizing crack evolution intensity. It overcomes the limitations of single acoustic or infrared signals, such as hysteresis and spatial constraints. This research provides valuable references for understanding rock disaster mechanisms, rock control strategies, and geological disaster prevention and mitigation.

Key words: rock mechanics, fissured rocks, crack propagation, acoustic emission, thermal infrared, coefficient of variation

中图分类号: TU452
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