首页|期刊导航|煤田地质与勘探|不同浸水状态煤岩组合体动力响应特征与破坏机制

不同浸水状态煤岩组合体动力响应特征与破坏机制OA

Dynamic response characteristics and failure mechanism of coal-rock combination under different immersion conditions

中文摘要英文摘要

[背景]实际工程中的防水煤柱通常会遭受来自上覆岩层不同程度大小的动载作用,且其内部水分布具有非均匀性,传统"含水率"指标虽能反映整体含水量,却难以刻画浸水空间的非均匀特性,故明确不同浸水状态下煤岩体的动力破坏机制对稳定性分区控制具有重要意义.[方法]基于此,制备完全浸水、单侧浸水、不浸水3种不同浸水状态下的煤岩组合体,采用高速摄像、DIC、CT扫描等方法,开展SHPB试验及FLAC-PFC3D耦合数值模拟,分别从宏观和细观角度对比其各受0.3、0.5、0.7 MPa冲击气压下的应力应变、裂纹扩展、能量分配、力链结构演化特征.[结果和结论](1)煤岩组合体的惯性约束效应和应变率强化效应使其峰值应力和弹性模量随冲击气压增大而增大,但浸水软化则具有削弱作用.(2)浸水软化让裂纹尖端更易发生转向,形成曲折的复合拉剪路径,而干燥煤体则保持脆性张拉破裂.随着冲击气压增大,主裂纹逐渐向界面靠近,损伤程度从微观向宏观演进,裂纹类型由单一向复合发展.(3)相同浸水状态下,中、高强度冲击气压大小的改变,对反射能、耗散能和透射能的占比影响较小.反之,相同冲击气压下,不同浸水状态却显著影响着各部分能量占比.(4)浸水作用促进力链退化,使冲击气压驱动体系从均匀耗能向局部承载转变,且随着冲击气压增大与浸水体积减小,煤岩组合体将从拉伸破坏转变成剪切破坏为主导.研究成果可为动载防水煤柱稳定性分区控制提供理论基础.

[Background]In practical engineering,the waterproof coal pillar usually suffers from different degrees of dynamic load from the overlying strata,and its internal water distribution is non-uniform.Although the traditional"wa-ter content"index can reflect the overall water content,it is difficult to describe the non-uniform characteristics of the soaking space.Therefore,it is of great significance to clarify the dynamic failure mechanism of coal and rock mass un-der different immersion conditions for stability zoning control.[Methods]On this basis,the coal-rock combined bodies under three different forms of immersion,namely:complete immersion,unilateral immersion,and non-immersion were prepared.These specimens were then subjected to split hopkinson pressure bar testing combined with high-speed photo-graphy,digital image correlation(DIC),and CT scanning,supplemented by FLAC-PFC3D coupled numerical simula-tions.Thereafter,the evolutionary characteristics of stress-strain,crack propagation,energy distribution,and force chain structure of these specimens under impact pressure of 0.3 MPa,0.5 MPa,and 0.7 MPa were compared from macroscop-ic and mesoscopic angles.[Results and Conclusions](1)Due to inertial confinement and strain-rate strengthening,the peak stress and elastic modulus of the specimens increase with impact pressure,but are reduced by water-induced soften-ing.(2)The softening of water immersion makes the crack tip more likely to turn,forming a tortuous composite tensile-shear path,while the dry coal keeps brittle tensile fracture.With the increase of impact pressure,the main crack will gradually approach the interface,the damage degree will evolve from micro to macro,and the crack morphology will de-velop from single to composite.(3)Under the same immersion condition,the change of medium and high impact pres-sure has little effect on the proportion of reflection energy,dissipation energy and transmission energy.On the contrary,under the same impact pressure,different immersion states significantly affect the energy proportion of each part.(4)The immersion effect promotes the degeneration of the force chain,resulting in the transformation of the impact pressure-driven system from uniform energy consumption to local load carrying,and the failure mode of coal-rock combined bodies will change from tensile failure to shear failure with the increase of the impact pressure and the decrease of the immersion volume.The research results can provide a theoretical basis for the stability zoning control of dynamic load waterproof coal pillar.

张向阳;童治鹏;段云刚;杨伟昆;陈建本;许林峰

安徽理工大学深部煤炭安全开采与环境保护全国重点实验室,安徽淮南 232001||安徽理工大学矿业工程学院,安徽淮南 232001安徽理工大学深部煤炭安全开采与环境保护全国重点实验室,安徽淮南 232001||安徽理工大学矿业工程学院,安徽淮南 232001淮南矿业(集团)有限责任公司,安徽淮南 232001安徽理工大学深部煤炭安全开采与环境保护全国重点实验室,安徽淮南 232001||安徽理工大学矿业工程学院,安徽淮南 232001淮南矿业(集团)有限责任公司,安徽淮南 232001安徽理工大学深部煤炭安全开采与环境保护全国重点实验室,安徽淮南 232001||安徽理工大学矿业工程学院,安徽淮南 232001

矿业与冶金

煤岩组合体浸水状态分离式霍普金森压杆(SHPB)冲击气压动力响应分区控制

coal-rock combinationimmersion conditionsplit hopkinson pressure barimpact pressuredynamic re-sponseregional control

《煤田地质与勘探》 2026 (4)

190-203,14

安徽省自然科学基金面上项目(2508085ME131)深部煤炭安全开采与环境保护全国重点实验室开放基金重点项目(2025ZD004)安徽理工大学高层次人才科研基金项目(2024yjcr159)

10.12363/issn.1001-1986.26.01.0021

评论