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

doi:10.13722/j.cnki.jrme.2021.0920

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Abstract In order to study the mechanical properties and energy dissipation laws of coal samples with different length-to-diameter ratios under three-dimensional(3D) coupled static and dynamic loads，four groups of cylinder specimens with a diameter of 50 mm and length-to-diameter ratios of 0.5，0.6，0.8 and 1.0 were respectively used to carry out 3D coupled static and dynamic loading experiment by using the improved split Hopkinson pressure bar(SHPB). The mechanical properties of coal samples with different length-to-diameter ratios were studied from the aspects of dynamic stress and dynamic strain，and the energy of the coal samples after crushed was analyzed. The results show that the dynamic peak stress and the combined peak stress increase as a power function of the strain rate，and the specimens with large length-to-diameter ratio are more sensitive to the strain rate when the length-to-diameter ratio of the samples is in the range of 0.5–1.0. At the same strain rate，the dynamic peak stress and the combined peak stress increase with increasing the length-to-diameter ratio，and the greater the strain rate，the more significant the length-to-diameter ratio effect. The dynamic peak strain and the dynamic maximum strain increase linearly with increasing the strain rate. There is little difference between the strain rate sensitivities of the dynamic peak strain and the dynamic maximum strain with different length-to-diameter ratios. Under the same strain rate，the dynamic peak strain decreases with increasing the length-to-diameter ratio. The dynamic maximum strain, affected by the double factors of the preload and the maximum allowable deformation of the specimens， decreases first and then increases with increasing the length-to-diameter ratio. The larger the length-to-diameter ratio of the samples，the lower the dissipated energy density and the higher the degree of crushing. The failure mode changes from tensile failure to shear failure with increasing the length-to-diameter ratio. The research results are helpful to explore the failure mechanism under the coupled static and dynamic loads，and provide theoretical support for the prevention and control of rockburst.

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	WU Yongzheng1
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	SUN Zhuoyue1
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	FU Yukai1
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Cite this article:

WU Yongzheng1,2,3, et al. Mechanical properties and energy dissipation laws of coal samples with different length-to-diameter ratios under 3D coupled static and dynamic loads[J]. , 2022, 41(5): 877-888.

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https://rockmech.whrsm.ac.cn/EN/10.13722/j.cnki.jrme.2021.0920 OR https://rockmech.whrsm.ac.cn/EN/Y2022/V41/I5/877

[1] 康红普，徐刚，王彪谋，等. 我国煤炭开采与岩层控制技术发展40 a及展望[J]. 采矿与岩层控制工程学报，2019，1(2)：7–39.(KANG Hongpu，XU Gang，WANG Biaomou，et al. Forty years development and prospects of underground coal mining and strata control technologies in China[J]. Journal of Mining and Strata Control Engineering，2019，1(2)：7–39.(in Chinese))
[2] 吴拥政，付玉凯，何杰，等. 深部冲击地压巷道“卸压–支护–防护”协同防控原理与技术[J]. 煤炭学报，2021，46(1)：132–144.(WU Yongzheng，FU Yukai，HE Jie，et al. Principle and technology of “pressure relief-support-protection” collaborative prevention and control in deep rock burst roadway[J]. Journal of China Coal Society，2021，46(1)：132–144.(in Chinese))
[3] WU Y，GAO F，CHEN J，et al． Experimental study on the performance of rock bolts in coal burst-prone mines[J]. Rock Mechanics and Rock Engineering，2019，52(10)：3 959–3 970.
[4] 窦林名，何学秋，REN Ting，等. 动静载叠加诱发煤岩瓦斯动力灾害原理及防治技术[J]. 中国矿业大学学报，2018，47(1)：48–59.(DOU Linming，HE Xueqiu，REN Ting，et al. Mechanism of coal-gas dynamic disasters caused by the superposition of static and dynamic loads and its control technology[J]. Journal of China University of Mining and Technology，2018，47(1)：48–59.(in Chinese))
[5] 姜耀东，赵毅鑫. 我国煤矿冲击地压的研究现状：机制、预警与控制[J]. 岩石力学与工程学报，2015，34(11)：2 188–2 204.(JIANG Yaodong，ZHAO Yixin. State of the art：investigation on mechanism，forecast and control of coal bumps in China[J]. Chinese Journal of Rock Mechanics and Engineering，2015，34(11)：2 188–2 204.(in Chinese))
[6] 潘一山，代连朋. 煤矿冲击地压发生理论公式[J]. 煤炭学报，2021，46(3)：789–799.(PAN Yishan，DAI Lianpeng. Theoretical formula of rock burst in coal mines[J]. Journal of China Coal Society，2021，46(3)：789–799.(in Chinese))
[7] 付玉凯，苗永春，杨威. 煤岩在冲击载荷下的动态力学特性对比分析[J]. 煤炭科学技术，2015，43(11)：6–11.(FU Yukai，MIAO Yongchun，YANG Wei. Comparison analysis on dynamic mechanics features of coal and rock under shock load[J]. Coal Science and Technology，2015，43(11)：6–11.(in Chinese))
[8] 温森，赵现伟，常玉林，等. 基于SHPB的复合岩样动态压缩破坏能量耗散分析[J]. 应用基础与工程科学学报，2021，29(2)：483–492.(WEN Sen，ZHAO Xianwei，CHANG Yulin，et al. Energy dissipation of dynamic failure of mixed rock specimens subject to SHPB compression[J]. Journal of Basic Science and Engineering，2021，29(2)：483–492.(in Chinese))
[9] 余永强，张文龙，范利丹，等. 冲击荷载下煤系砂岩应变率效应及能量耗散特征[J]. 煤炭学报，2021，46(7)：2 281–2 293.(YU Yongqiang，ZHANG Wenlong，FAN Lidan，et al. Strain rate effect and energy dissipation characteristics of sandstone in coal measures under impact loading[J]. Journal of China Coal Society，2021，46(7)：2 281– 2 293.(in Chinese))
[10] 齐庆新，李一哲，赵善坤，等. 我国煤矿冲击地压发展70年：理论与技术体系的建立与思考[J]. 煤炭科学技术，2019，47(9)：1–40.(QI Qingxin，LI Yizhe，ZHAO Shankun，et al. Seventy years development of coal mine rockburst in China：establishment and consideration of theory and technology system[J]. Coal Science and Technology，2019，47(9)：1–40.(in Chinese))
[11] 孟庆彬，韩立军，浦海，等. 应变速率和尺寸效应对岩石能量积聚与耗散影响的试验[J]. 煤炭学报，2015，40(10)：2 386–2 398. (MENG Qingbing. HAN Lijun，PU Hai，et al. Experimental on the effect of strain rate and size on the energy accumulation and dissipation of rock[J]. Journal of China Coal Society，2015，40(10)： 2 386–2 398.(in Chinese))
[12] 刘宝琛，张家生，杜奇中，等. 岩石抗压强度的尺寸效应[J]. 岩石力学与工程学报，1998，17(6)：611–614.(LIU Baochen，ZHANG Jiasheng，DU Qizhong，et al. A study of size effect for compression strength of rock[J]. Chinese Journal of Rock Mechanics and Engineering，1998，17(6)：611–614.(in Chinese))
[13] 梁正召，张永彬，唐世斌，等. 岩体尺寸效应及其特征参数计算[J]. 岩石力学与工程学报，2013，32(6)：1 157–1 166.(LIANG Zhengzhao，ZHANG Yongbin，TANG Shibin，et al. Size effect of rock messes and associated representative element properties[J]. Chinese Journal of Rock Mechanics and Engineering，2013，32(6)：1 157–1 166. (in Chinese))
[14] 尤明庆，邹友峰. 关于岩石非均质性与强度尺寸效应的讨论[J]. 岩石力学与工程学报，2000，19(3)：391–395.(YOU Mingqing，ZOU Youfeng. Discussion on heterogeneity of rock material and size effect on specimen strength[J]. Chinese Journal of Rock Mechanics and Engineering，2000，19(3)：391–395.(in Chinese))
[15] 吕兆兴，冯增朝，赵阳升. 岩石的非均质性对其材料强度尺寸效应的影响[J].煤炭学报，2007，32(9)：917–920.(LV Zhaoxing，FENG Zengchao，ZHAO Yangsheng. Influence of rock inhomogeneity on strength-size effect of rock materials[J]. Journal of China Coal Society，2007，32(9)：917–920.(in Chinese))
[16] 杨圣奇，苏承东，明平美，等. 岩石强度尺寸效应的研究方法和机制的研究[J]. 焦作工学院学报：自然科学版，2002，21(5)：323–325. (YANG Shengqi，SU Chengdong，MING Pingmei，et al. Study on the method and mechanism of size effect of rock strength[J]. Journal of Jiaozuo Institute of Technology：Natural Science，2002，21(5)：323–325.(in Chinese))
[17] 李夕兵. 冲击荷载下岩石能耗及破碎力学性质的研究[硕士学位论文][D]. 长沙：中南工业大学，1986.(LI Xibing. A study on the dynamic properties and energy absorption of rocks[M. S. Thesis][D]. Changsha：Central South University of Technology，1986.(in Chinese))
[18] 洪亮，李夕兵，马春德，等. 岩石动态强度及其应变率灵敏性的尺寸效应研究[J]. 岩石力学与工程学报，2008，27(3)：526–533. (HONG Liang，LI Xibing，MA Chunde，et al. Study on size effect of rock dynamic strength and strain rate sensitivity[J]. Chinese Journal of Rock Mechanics and Engineering，2008，27(3)：526–533.(in Chinese))
[19] 杜晶. 不同长径比下岩石冲击动力学特性研究[硕士学位论文][D]. 长沙：中南大学，2011.(DU Jing. Size effect on the dynamic mechanical properties under impact loads of rock[M. S. Thesis][D]. Changsha：Central South University，2011.(in Chinese))
[20] 平琦，张号，苏海鹏. 不同长度石灰岩动态压缩力学性质试验研究[J]. 岩石力学与工程学报，2018，37(增2)：3 891–3 897.(PING Qi，ZHANG Hao，SU Haipeng. Study on dynamic compression mechanical properties of limestone with different lengths[J]. Chinese Journal of Rock Mechanics and Engineering，2018，37(Supp.2)：3 891–3 897.(in Chinese))
[21] ZHOU Y，XIA K，LI X，et al. Suggested methods for determining the dynamic strength parameters and mode-I fracture toughness of rock materials[J]. International Journal of Rock Mechanics and Mining Sciences，2011，49(1)：105–112.
[22] 李地元，胡楚维，朱泉企. 预制裂隙花岗岩动静组合加载力学特性和破坏规律试验研究[J]. 岩石力学与工程学报，2020，39(6)：1 081– 1 093.(LI Diyuan，HU Chuwei，ZHU Quanqi. Experimental study on mechanical properties and failure laws of granite with an artificial flaw under coupled static and dynamic loads[J]. Chinese Journal of Rock Mechanics and Engineering，2020，39(6)：1 081–1 093.(in Chinese))
[23] ZHAGN X P，WONG L N Y. Cracking processes in rock-like material containing a single flaw under uniaxial compression：a numerical study based on parallel bonded-particle model approach[J]. Rock Mechanics and Rock Engineering，2012，45(5)：711–737.
[24] 卢志国，鞠文君，高富强，等. 结构性煤体间歇性破坏行为的实验及数值模拟研究[J]. 岩石力学与工程学报，2020，39(5)：971–983. (LU Zhiguo，JU Wenjun，GAO Fuqiang，et al. Experimental and numerical simulation research on intermittent failure of structural coal[J]. Chinese Journal of Rock Mechanics and Engineering，2020，39(5)：971–983.(in Chinese))
[25] 郝宪杰，袁亮，郭延定，等. 考虑峰后能量非稳态释放的硬煤脆性度指标[J]. 岩石力学与工程学报，2017，36(11)：2 641–2 649. (HAO Xianjie，YUAN Liang，GUO Yanding，et al. A new brittleness index for hard coal considering unsteady energy release at post-peak stage[J]. Chinese Journal of Rock Mechanics and Engineering，2017，36(11)：2 641–2 649.(in Chinese))
[26] 李夕兵. 岩石动力学基础与应用[M]. 北京：科学出版社，2014：176– 183.(LI Xibing. Rock dynamics fundamentals and applications[M]. Beijing：Science Press，2014：176–183.(in Chinese))
[27] 李夕兵，宫凤强，高科，等. 一维动静组合加载下岩石冲击破坏试验研究[J]. 岩石力学与工程学报，2010，29(2)：251–260.(LI Xibing，GONG Fengqiang，GAO Ke，et al. Test study of impact failure of rock subjected to one-dimensional coupled static and dynamic loads[J]. Chinese Journal of Rock Mechanics and Engineering，2010，29(2)：251–260.(in Chinese))
[28] 吴星辉，蔡美峰，任奋华，等. 不同热处理作用下花岗岩纵波波速和导热能力的演化规律分析[J/OL]. 岩石力学与工程学报， [2021–10–17]. https：//doi.org/10.13722/j.cnki.jrme.2021.0532. (WU Xinghui，CAI Meifeng，REN Fenhua，et al. P-wave evolution and thermal conductivity characteristics in granite under different thermal treatment[J/OL]. Chinese Journal of Rock Mechanics and Engineering，[2021–10–17]. https：//doi.org/10.13722/j.cnki. jrme. 2021.0532.(in Chinese))
[29] 李地元，肖鹏，谢涛，等. 动静态压缩下岩石试样的长径比效应研究[J]. 实验力学，2018，33(1)：93–100.(LI Diyuan，XIAO Peng，XIE Tao，et al. On the effect of length to diameter ratio of rock specimen subjected to dynamic and static compression[J]. Journal of Experimental Mechanics，2018，33(1)：93–100.(in Chinese))
[30] TANG C，THAM L G，LEE P K K，et al. Numerical studies of the influence of microstructure on rock failure in uniaxial compression-part II：constraint，slenderness and size effect[J]. International Journal of Rock Mechanics and Mining Sciences，2000，37(4)：571–583.