基于三维离散元的岩爆突变点处动力行为与能量演化研究

基于三维离散元的岩爆突变点处动力行为与能量演化研究
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                        魏蕤1魏蕤
同济大学土木工程学院
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赵程2赵程
同济大学土木工程学院
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钱源1钱源
同济大学土木工程学院
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作者单位:同济大学土木工程学院
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中图分类号:TU45.
基金项目:国家自然科学基金(U196510013，U22A20597)

Study on the dynamic behavior and energy evolution at rockburst mutation moment based on DEM

Author:

WEI Rui ^¹
WEI Rui
School of Civil Engineering,Tongji University,Shanghai
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zhaocheng ^²
zhaocheng
同济大学土木工程学院
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QIAN Yuan ^¹
QIAN Yuan
School of Civil Engineering,Tongji University,Shanghai
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Affiliation:

1.School of Civil Engineering,Tongji University,Shanghai;2.同济大学土木工程学院

Fund Project:

National Natural Science Foundation of China (NO.U196510013，NO. U22A20597)

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摘要:

岩爆失稳时刻的灾变启动机制是揭示岩爆机理的关键。为此参考失稳理论和刚度理论设计了岩爆体-围岩组合试样的三维离散元数值模型,并通过二次开发实现了系统能量演化过程的可视化,成功模拟了岩爆的抛掷现象。据此研究了系统失稳的时序特征和能量演化规律,结果表明：灾变启动时刻岩爆体到达峰值应力略早于围岩体,岩爆体峰值后自身的破裂软化形成了对围岩体的主动卸荷,使其应力由增变降。被卸荷的围岩体发生向岩爆体的快速回弹变形,并通过做功使自身储存的弹性能向岩爆体汇聚,两者的能量被岩爆体瞬间一并释放,引发块体的抛掷。在此过程中两子系统相互作用形成的正反馈调节机制,使破裂过程逐步加快,最终引发动态失稳。研究成果可为岩爆的机理的深入揭示提供理论参考和技术支持。

关键词:岩爆;突变点;动力行为;能量演化;离散元

Abstract:

The dynamic behavior and energy evolution of rockburst at the moment of sudden instability are the key to reveal rockburst formation mechanism. Based on the instability theory and stiffness theory, a combination model consists of rockburst body and its surrounding rock was established using the three-dimension discrete element method (DEM). With it the energy evolution process of the system is visualized through secondary development and the ejection phenomenon of rockburst is simulated successfully. Based on the numerical simulation, the time sequence characteristics and energy evolution laws of instability of the system are studied. The results show that the rockburst rock body reaches the peak stress slightly earlier than the surrounding rock body. The rupture and softening of the rockburst body after the peak stress results in the unloading of the surrounding rock body, and causes its stress changes from increase to decreases. The surrounding rock mass then has a rapid rebound deformation to the rockburst body, and the elastic energy stored in the surrounding rock body converges to the rockburst body. In this process, the positive feedback regulation mechanism formed by the interaction of the two subsystems accelerates the fracture processes and finally leads to dynamic instability. The research results can provide theoretical reference and technical support for further revealing the rockburst mechanism.

Key words:Rockburst; Dynamic instability; Evolutionary processes; Initiation mechanism; Discrete Element Method

参考文献

[1] 钱七虎. 岩爆、冲击地压的定义、机制、分类及其定量预测模型[J]. 岩土力学, 2014,35(01): 1-6.QIAN Q H. Definition, mechanism, classification and quantitative forecast model for rockburst and pressure bump [J]. Rock and Soil Mechanics, 2014,35(1): 1-6. (in Chinese)

[2] GAO F Q, Kaiser P K, Stead D, et al. Strainburst phenomena and numerical simulation of self-initiated brittle rock failure [J]. International Journal of Rock Mechanics and Mining Sciences, 2019,116: 52-63.

[3] XIAO Y X, FENG X T, LI S J, et al. Rock mass failure mechanisms during the evolution process of rockbursts in tunnels [J]. International Journal of Rock Mechanics and Mining Sciences, 2016,83: 174-181.

[4] 兰恒星, 张宁, 李郎平, 等. 川藏铁路可研阶段重大工程地质风险分析[J]. 工程地质学报, 2021,29(02): 326-341.LAN H X, ZHANG N, LI L P, et al. Risk analysis of major engineering geological hazards for Sichuan-Tibet railway in the phase of feasibility study [J]. Journal of Engineering Geology, 2021,29(2): 326-341. (in Chinese)

[5] 宫凤强, 潘俊锋, 江权. 岩爆和冲击地压的差异解析及深部工程地质灾害关键机理问题[J].工程地质学报,2021,29(04):933-961.GONG F Q, PAN J F, JIANG Q. The difference analysis of rock burst and coal burst and key mechanisms of deep engineering geological hazards [J]. Journal of Engineering Geology, 2021,29(4): 933-961. (in Chinese)

[6] 何满潮, 苗金丽, 李德建, 等.深部花岗岩试样岩爆过程实验研究[J].岩石力学与工程报,2007(05):865-876.HE M C, MIAO J L, LI D J, et al. Experimental study on rockburst processes of granite specimen at great depth [J]. Chinese Journal of Rock Mechanics and Engineering, 2007,26(5): 865-876. (in Chinese)

[7] Li S J, Feng X T, Li Z H, et al. In situ monitoring of rockburst nucleation and evolution in the deeply buried tunnels of Jinping II hydropower station [J]. Engineering Geology, 2012,137: 85-96.

[8] 顾金才, 范俊奇, 孔福利, 等. 抛掷型岩爆机制与模拟试验技术 [J]. 岩石力学与工程学报, 2014,33(06): 1081-1089.GU J C, FAN J Q, KONG F L, et al. Mechanism of ejective rockburst and model testing technology [J]. Chinese Journal of Rock Mechanics and Engineering, 2014,33(6): 1081-1089. (in Chinese)

[9] 章梦涛.冲击地压失稳理论与数值模拟计算[J].岩石力学与工程学报,1987(03):197-204.ZHANG M T. Instability theory and mathematical model for coal / rock bursts [J]. Chinese Journal of Rock Mechanics and Engineering, 1987(03):197-204. (in Chinese)

[10] Li C C, Zhao T B, Zhang Y B, et al. A study on the energy sources and the role of the surrounding rock mass in strain burst [J]. International Journal of Rock Mechanics Mining Sciences, 2022,154.

[11] 刘建新, 唐春安, 朱万成, 等. 煤岩串联组合模型及冲击地压机理的研究 [J].岩土工程学,2004(02):276-280.LIU J X, TANG C A, ZHU W C, et al. Rock-coal model for studying the rockburst [J]. Chinese Journal of Geotechnical Engineering, 2004,26(2): 276-280. (in Chinese)

[12] 王来贵, 习彦会, 潘纪伟, 等. 动力弹射型岩爆发生机理及反馈机制[J]. 辽宁工程技术大学学报(自然科学版), 2016. 35(04): 365-370.WANG L G, XI Y H, PAN J W, et al. Occurrence and feedback mechanism of dynamic ejection rock-burst [J]. Journal of Liaoning Technical University （Natural Science Edition），2016，35(4)：365-370. (in Chinese)

[13] 向鹏, 纪洪广, 蔡美峰, 等. 抛掷型岩爆震源体能量动态释放机制与几何尺度特征[J]. 岩土力学, 2018,39(02): 457-466.XIANG P, JI H G, CAI M F, et al. Dynamic energy release mechanism and geometric scale feature of ejection rockburst source [J]. Rock And Soil Mechanics, 2018,39(2): 457-466. (in Chinese)

[14] WANG J, APEL D B, PU Y, et al. Numerical modeling for rockbursts: A state-of-the-art review [J]. Journal of Rock Mechanics and Geotechnical Engineering, 2021,13(2): 457-478.

[15] 赵菲, 何满潮, 李德建, 等. 真三轴卸载煤爆实验破坏特征演化分析[J]. 地下空间与工程学报, 2019,15(01): 142-150.ZHAO F, HE M C, LI D J, et al. Damage Evolution in the Fracture Process of Coal Burst during True Traxial Unloading Test [J]. Chinese Journal of Underground Space and Engineering, 2019,15(1): 142-150. (in Chinese)

[16] 齐庆新, 陈尚本, 王怀新, 等. 冲击地压、岩爆、矿震的关系及其数值模拟研究[J]. 岩石力学与工程学报, 2003(11): 1852-1858.QI Q X, CHEN S B, WANG H X, et al. Study on the relations among coal bump, rockburst and mining tremor with numerical simulation [J]. Chinese Journal of Rock Mechanics and Engineering, 2003,22(11): 1852-1858. (in Chinese)

[17] 苏国韶, 冯夏庭, 江权, 等. 高地应力下地下工程稳定性分析与优化的局部能量释放率新指标研究[J]. 岩石力学与工程学报, 2006(12): 2453-2460.SU G S, FENG X T, JIANG Q, et al. Study on new index of local energy release rate for stability analysis and optimal design of underground rockmass engineering with high geostress [J]. Chinese Journal of Rock Mechanics and Engineering, 2006,25(12): 2453-2460. (in Chinese)

[18] 田青峰, 袁照辉, 张睿, 等. 高地应力水平岩层隧道岩爆机制研究——以大峡谷隧道为例[J].隧道建设(中英文),2021,41(S1):223-231.TIAN Q F, YUAN Z H, ZHANG R, et al. Rockburst mechanism of Daxiagu tunnel in horizonal rock formation with high crustal stress [J].Tunnel Construction, 2021,41(S1): 223-231. (in Chinese)

[19] GAO F, KANG H, LI J. Numerical simulation of fault-slip rockbursts using the distinct element method [J]. Tunnelling and Underground Space Technology, 2021,110: 103805.

[20] 王之东, 黎立云, 陈滔, 等.矿柱岩爆模型试验中能量释放研究[J].岩土力学,2018,39(S2):177-185.WANG Z D, LI L Y, CHEN T, et al. Study of energy release in model tests on pillar rockburst [J]. Rock and Soil Mechanics, 2018, 39(S2): 177-185. (in Chinese)

[21] WANG J A, PARK H D. Comprehensive prediction of rockburst based on analysis of strain energy in rocks [J]. Tunnelling and Underground Space Technology, 2001,16(1): 49-57.

[22] GONG F Q, WANG Y, LUO S. Rockburst proneness criteria for rock materials: Review and new insights [J]. Journal of Central South University, 2020,27(10): 2793-2821.

[23] 谷明成，何发亮，陈成宗. 秦岭隧道岩爆的研究[J]. 岩石力学与工程学报, 2002(09): 1324-1329.U M C, HE F L, CHEN C Z. Study on rockburst in Qingling tunnel [J]. Chinese Journal of Rock Mechanics and Engineering, 2002,21(9): 1324-1329.

[24] 尚彦军, 张镜剑, 傅冰骏. 应变型岩爆三要素分析及岩爆势表达[J]. 岩石力学与工程学报, 2013,32(08): 1520-1527.SHANG Y J, ZHANG J J, FU B J. Analyses of three parameters for strain mode rockbueat and expression of rockburst potential [J]. Chinese Journal of Rock Mechanics and Engineering, 2013,32(8): 1520-1527. (in Chinese)

[25] LAN H X, MARTIN C D, ANDERSSON J C. Evolution of In Situ Rock Mass Damage Induced by Mechanical–Thermal Loading [J]. Rock Mechanics and Rock Engineering, 2013,46(1): 153-168.

[26] ANDERSSON J C, MARTIN C D, STILLE H. The Äspö Pillar Stability Experiment: Part II—Rock mass response to coupled excavation-induced and thermal-induced stresses [J]. International Journal of Rock Mechanics and Mining Sciences, 2009,46(5): 879-895.

[27] 王来贵，黄润秋，张倬元, 等. 超前强扰诱发岩石力学系统失稳及其防灾意义的探讨[J]. 自然灾害学报, 1997(02): 57-61.WANG L G，HUANG R Q, ZHANG Z Y, et al. Inducing failure of rock mechanics system by advanced great disturbance and it significance for hazard prevention [J].Journal of Natural Disasters, 1997, 6(2) :55-59．(in Chinese)

[28] 徐曾和, 徐小荷, 唐春安. 坚硬顶板下煤柱岩爆的尖点突变理论分析[J]. 煤炭学报, 1995(5): 485-491.Xu Z H, Xu X H, Tang C A. Theoretical analysis of a cusp catastrophe bump of coal pillar under hard rocks [J]. Journal of China Coal Society, 1995, 20(5) : 485-491. (in Chinese)

[29] 林鹏,唐春安,陈忠辉等.二岩体系统破坏全过程的数值模拟和实验研究[J].地震,1999(04):413-418.4LIN P, TANG C A, CHEN Z H, et al. Numerical and Experimental Study of Deformation and Failure Behavior in a Double Rock Specimen System [J].Earthquake,1999(04):413-418 (in Chinese)

[30] 张春生, 陈祥荣, 侯靖, 等. 锦屏二级水电站深埋大理岩力学特性研究[J]. 岩石力学与工程学报,2010,29(10):1999-2009.ZHANG C S, CHEN X R, HOU J, et al. Study of Mechanical behavior of deep-buried marble at Jinping II hydropower station [J]. Chinese Journal of Rock Mechanics and Engineering, 2010,29(10): 1999-2009. (in Chinese)

[31] Itasca, Consulting Group Inc. 3DEC 3 Dimension Distinct Element Code: User’s Manual [M]. Minnesota, USA, 2005.

[32] 谢和平 ,鞠杨 ,黎立云. 基于能量耗散与释放原理的岩石强度与整体破坏准则[J].岩石力学与工程学报,2005(17):3003-3010.XIE H P, JU Y, LI L Y. Criteria for strength and structural failure of rocks [J]. Chinese Journal of Rock Mechanics and Engineering, 2005, 24 (17): 3003-3010. (in Chinese)

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收稿日期:2023-02-04
最后修改日期:2023-03-19
录用日期:2023-04-21
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