Dynamic response and failure process of horizontal-layered fractured structure rock slope under strong earthquake

Rock slope with horizontal-layered fractured structure(HLFS)has high stability in its natural state.However,a strong earthquake can induce rock fissure expansion,ultimately leading to slope failure.In this study,the dynamic response,failure mode,and spectral characteristics of rock slope with HLFS under strong earthquake conditions were investigated based on the large-scale shaking table model test.On this basis,multiple sets of numerical calculation models were further established by UDEC discrete element program.Five influencing factors were considered in the parametric study of numerical simulations,including slope height,slope angle,bedding-plane spacing and secondary joint spacing as well as bedrock dip angle.The results showed that the failure process of rock slope with HLFS under earthquake action is mainly divided into four phases,i.e.,the tensile crack of the slope shoulder joints and shear dislocation at the top bedding plane,the extension of vertical joint cracks and increase of shear displacement,the formation of step-through sliding surfaces and the instability,and finally collapse of fractured rock mass.The acceleration response of slopes exhibits elevation amplification effect and surface effect.Numerical simulations indicate that the seismic stability of slopes with HLFS exhibits a negative correlation with slope height and angle,but a positive correlation with bedding-plane spacing,joint spacing,and bedrock dip angle.The results of this study can provide a reference for seismic stability evaluation of weathered rock slopes.

Integrated simulation and monitoring to analyze failure mechanism of the anti-dip layered slope with soft and hard rock interbedding

The significant difference between the mechanical properties of soft rock and hard rock results in the complexity of the failure mode of the anti-dip layered slope with soft and hard rock interbedding.In order to reveal the landslide mechanism,taking the north slope of Fushun West Open-pit Mine as an example,this paper analyzed the failure mechanism of different landslides with monitoring and field surveys,and simulated the evolution of landslides.The study indicated that when the green mudstone(hard rock)of the anti-dip slope contains siltized intercalations(soft rock),the existence of weak layers not only aggravates the toppling deformation of anti-dip layered slope with high dip,but also causes the shear failure of anti-dip layered slope with stable low dip.The shear failure including subsidence induced sliding and wedge failure mainly exists in the unloading zone of the slope.Its failure depth and failure time were far less than that of toppling failure.In terms of the development characteristics of deformation,toppling deformation has the long-term and progressive characteristics,but shear failure deformation has the abrupt and transient characteristics.This study has deepened the understanding of such slope landslide mechanism,and can provide reference for similar engineering.

Groundwater monitoring of an open-pit limestone quarry:Water-rock interaction and mixing estimation within the rock layers by geochemical and statistical analyses

Water-rock interaction and groundwater mixing are important phenomena in understanding hydrogeological systems and the stability of rock slopes especially those consisting largely of moderately watersoluble minerals like calcite. In this study, the hydrogeological and geochemical evolutions of groundwater in a limestone quarry composed of three strata: limestone layer(covering), interbedded layer under the covering layer, and slaty greenstone layer(basement) were investigated. Water-rock interaction in the open-pit limestone quarry was evaluated using PHREEQC, while hierarchical cluster analysis(HCA)and principal component analysis(PCA) were used to classify and identify water sources responsible for possible groundwater mixing within rock layers. In addition, Geochemist's Workbench was applied to estimate the mixing fractions to clarify sensitive zones that may affect rock slope stability. The results showed that the changes in Ca2+and HCO3àconcentrations of several groundwater samples along the interbedded layer could be attributed to mixing groundwater from the limestone layer and that from slaty greenstone layer. Based on the HCA and PCA results, groundwaters were classified into several types depending on their origin:(1) groundwater from the limestone layer(LO),(2) mixed groundwater flowing along the interbedded layer(e.g., groundwater samples L-7, L-11, S-3 and S-4), and(3) groundwater originating from the slaty greenstone layer(SO). The mixing fractions of 41% LO: 59% SO, 64% LO: 36% SO, 43%LO: 57% SOand 25% LO: 75% SOon the normal days corresponded to groundwaters L-7, L-11, S-3 and S-4,respectively, while the mixing fractions of groundwaters L-7 and L-11(61% LO: 39% SOand 93% LO: 7% SO,respectively) on rainy days became the majority of groundwater originating from the limestone layer.These indicate that groundwater along the interbedded layer significantly affected the stability of rock slopes by enlarging multi-breaking zones in the layer through calcite dissolution and inducing high water pressure, tension cracks and potential sliding plane along this layer particularly during intense rainfall episodes.

E24 profile slope stability analysis in Haizhou Opencast Coal Mine of Fuxin

The E24 profile slope analyzed belongs to a series of excavated slopes of the Haizhou Opencast Coal Mine. It seems to be divided into Downslope Part and Upslope Part. Its profile comprises two noticeable coal seams, called the 8# and 9# weak layers, considered as the potential failure surfaces. In consideration of the actual configuration as in the perspective of any modification, assessing the stability of this slope with various profile forms under given conditions, and assessing the risk of instability and quantifying the influence of earthworks or other modifications to the stability of this slope, have constituted the primordial objectives carried out. From assumed potential failure surfaces, any specific profiles and specified slip surfaces are defined. A factor of safety (FoS) is computed for each specified slip surface; the smallest FoS found corresponds to the least favorable slip surface. The safety factor values obtained are compared to the suggested safety factor. Limit equilibrium methods of vertical slices implemented in Slope/W, computer program for slope stability analyses, have been adopted to perform the E24 slope stability analysis. The safety factor values computed with 9# weak layer are lower than for 8#; the factors of safety obtained with Sarma's method are the smallest; more, without groundwater (long term) overall values are greater than those determined under groundwater condition (short term). The lowest safety factor value is found for a profile depending on an adopted earthwork sequence. The E24 profile slope stability analysis shows the instability risk for the deepest weak layer, and also shows the short and long term stability of this slope for the envisaged earth movements. However it demonstrates the existence of instability risk for any earthwork firstly affecting the downslope part.

远距离下保护层开采遗留煤柱对被保护层回采的影响研究

为探究远距离下保护层开采遗留煤柱对被保护层回采效果的影响,以平顶山六矿戊_(8)煤层的戊_(8)-22310机巷和戊_(8)-32010风巷之间遗留宽度为4 m的区段煤柱和丁_(5-6)-22190工作面为研究对象,采用理论分析、数值模拟和现场实测结合的方法,研究了煤柱影响范围、煤柱区域垂直应力分布及影响区相关参数变化规律。结果表明:宽4 m遗留煤柱的影响范围为27.3 m,极限强度为25.9 MPa,塑性区宽度为2.26 m,弹性区宽度为2.68 m;煤柱两侧工作面均回采后,其承载的最大垂直应力87.9 MPa,远超煤柱本身的承载极限;在煤柱影响范围内测得的残余瓦斯含量、压力与卸压保护区无明显差异,并均小于突出危险临界值,煤柱影响区内瓦斯得到较好释放;煤柱影响范围内未产生明显应力集中现象,遗留小煤柱对被保护效果影响较小,保护效果在倾向上有连续性,对被保护层工作面回采影响小。

露天矿顺倾软岩边坡内排追踪压帮治理工程——以贺斯格乌拉南露天煤矿首采区南帮为例

软岩露天煤矿实现安全高效开采的重点是边坡稳定。为解决露天矿顺倾软岩边坡稳定性治理难题,在分析边坡稳定性主控因素的基础上,提出了露天矿顺倾软岩边坡内排追踪压帮治理工程。以贺斯格乌拉南露天煤矿首采区南帮为工程背景,兼顾采场与内排土场边坡稳定性,采用极限平衡法和数值模拟相结合的手段,设计了采场边坡的空间形态,提出了采场与内排土场边坡协同治理方案,可最大限度地安全回收边坡压覆煤炭资源。研究结果表明:弱层暴露长度是露天矿顺倾软岩边坡稳定性的主控因素,控制采场与内排土场间的追踪距离是改善边坡稳定性的有效途径;随着追踪距离的增加,边坡破坏模式从以圆弧为侧界面、弱层为底界面的切层-顺层-剪出滑动逐渐过渡为以圆弧为侧界面、弱层为底界面的切层-顺层滑动,边坡稳定性逐渐下降;内排土场及其与采场构成的复合边坡稳定性随破坏底板弱层回填岩石范围的增大呈指数函数规律提高;贺斯格乌拉南露天煤矿首采区南帮浅部边坡留设40 m运输平盘、15 m保安平盘,底帮深部边坡角29°,追踪距离控制在50 m之内时可满足安全要求;内排土场基底弱层完全破坏并回填岩石倾向长度60 m时可满足安全要求。研究成果为软岩露天煤矿边坡稳定性治理提供了新思路。

《“三下”开采规范》中安全煤(岩)柱留设问题探讨

针对《建筑物、水体、铁路及主要井巷煤柱留设与压煤开采规范》中安全煤(岩)柱设计以及水压对顶板突水控制作用等问题进行探讨。首先分析了规范的附表4-3表头文字,指出保护层厚度的有关规定仅适用于松散含水层(含地表水体),至于基岩含水层下采煤应如何确定保护层厚度则未明确;进而以泥岩与黏性土层均具有阻水功能为桥梁,推导出基岩含水层下采煤可参照“松散层下黏性土层累计厚度大于采厚”条件执行,遵照“就高不就低原则”,基岩含水层下保护层厚度统一取采厚的4倍为宜;既然规范适用条件为单层采厚不大于3.0 m,则附表4-3中“松散层厚度小于采厚”的规定难以理解,建议删除。其次,基于“保护”一词的科学内涵对“保护层”重新定义,即导水裂缝带顶界面到含水层底界面之间的隔水岩层均具有“保护”功能,应统称为保护层H_(b);进而提出了保护系数B_(s)概念,即保护层厚度与单层采厚的比值;松散含水层下保护系数分区阈值(B_(i)=2、3、4、5、6、7),基岩含层下保护系数分区阈值B_(i)=4,据此对顶板水害风险进行等级划分:突水区(B_(s)≤0)、危险区(0<B_(s)<B_(i))、安全区(B_(s)≥B_(i))。此外,借鉴底板突水系数概念,将单位厚度保护层承受的水头压力称为保护层承压系数(T=P/H_(b)),通过对3种煤水结构条件下承压系数的分析,得出第4系松散含水层、非煤系基岩含水层下采煤可以不考虑水压,煤系基岩含水层下采煤随着开采深度增加、水压随之增大而带来突(涌)水风险。最后,分析了底板含水层顶部存在被泥质物充填隔水带时,《“三下”开采规范》给出的底板防水安全煤(岩)柱表达式(h_(a)≥h_(1)+h_(2)+h_(4))与附图相矛盾,正确的表达式应为h_(a)≥h_(1)+h_(2)-h_(4)。

特厚煤层沿空掘巷围岩支卸协同控制技术

针对特厚煤层小煤柱沿空掘巷大范围塑性全煤巷道锚网索的支护难题,以塔山煤矿8204-2小煤柱工作面为工程背景,采用现场实测、理论分析等方法,揭示了锚杆、锚索对沿空大范围塑性全煤巷道的支护机理。锚杆支护主要作用于浅部二次破碎区煤体,形成浅部连续承载结构;锚索主要作用于深部处于三向受力状态的稳定煤体,形成更大范围的连续稳定承载结构;进一步明确了锚杆、锚索有效长度的计算方法,形成了以高预紧力、高强“锚-网-索”支护为基础,以坚硬顶板井下磨料水射流切顶卸压、巷帮大直径钻孔卸压、底板卸压槽卸压为辅的“支卸协同”小煤柱沿空巷道围岩控制技术体系。工程应用结果表明,试验巷道围岩最大变形量小于700 mm,能够满足使用要求。

岩土成层条件下抗滑桩计算的改进有限差分法

滑坡治理工程中抗滑桩可能布置于层状土层、层状岩层,或岩、土成层等各种地质条件下,现行规范对于该问题建议将成层地基按加权平均法换算成等效的当量地基系数,但对于地层差异性较大的岩土成层地基其适用性有待研究。为解决这一问题,基于Euler-Bernoulli梁理论建立抗滑桩受荷段、嵌固段整体受荷分析模型,采用改进有限差分法提出抗滑桩全桩内力求解的统一矩阵运算式,避免常规有限差分方法将桩身分为受荷段和嵌固段及利用滑面处连续性条件求解的复杂迭代过程;基于2个边坡工程抗滑桩治理案例,证明改进有限差分法对岩土成层条件下抗滑桩分析的可靠性,计算用时仅需1.2 s左右,相比已有方法进一步提高抗滑桩分析设计的计算效率。

倾角变化条件下反倾层状斜坡倾倒变形演化研究

倾倒变形是反倾层状岩质边坡的一种典型破坏模式,为了研究不同岩层倾角对反倾层状岩质边坡倾倒变形的影响,以澜沧江上游古水水电站坝前倾倒变形体为原型,从岩层倾角变化的角度出发,利用大型土工离心机试验分析了反倾层状岩质边坡的失稳破坏过程、变形演化特征与最终失稳模式等。结果表明:①反倾层状斜坡的变形演化过程基本概括为岩层压密-坡脚压裂阶段、弯折面形成-部分失稳阶段和弯折面贯通-彻底失稳3个阶段,岩层倾角的改变并不会影响斜坡阶段性演化过程;②岩层倾角越大的斜坡,斜坡形成弯折面所需时间越短,失稳破坏发生后坡体贯通性倾倒破坏深度更大,对应的变形范围越大,折断岩层的破坏程度越剧烈;③岩层倾角变化会导致斜坡的倾倒变形过程与最终失稳模式存在一定差异。倾角较小的55°和70°模型斜坡前部岩层在重力作用下发生明显弯曲倾倒变形,最终以“倾倒-弯曲-滑移”的失稳模式发生破坏;倾角最大的85°斜坡岩层发生的弯曲变形较小,最终以“倾倒-折断-崩塌”的模式发生破坏。研究结果对大型工程项目的顺利开展具有一定指导意义。

古建筑压煤开采对斜坡上覆堆积层变形扰动影响研究

针对缓倾顺层斜坡上覆堆积层的采动稳定性与变形机理的研究,特别是从协调地下资源开采与地上文物古建筑安全防护视角出发的研究处在探索阶段。以山西省宝应寺斜坡堆积层为研究对象,基于地表动态监测与地质过程机制分析,结合数值模拟研究了堆积层稳定性与地表裂缝成因机制,并探讨优化了开采方式。研究表明:①长壁式地下开采是引起堆积层变形的诱因,堆积层软弱特性与斜坡软硬互层结构是其变形内因。堆积层下伏基岩变形模式为垂向挤压水平拉张,对堆积层变形具有放大效果,牵动其产生地裂缝。堆积层变形破坏机制为:坡下采空—覆岩弯曲—侧岩倾倒变形—下伏岩层应力集中—牵动拉裂;②堆积层裂缝分布在上坡方向采空区工作面端部附近,平面上近似平行,呈“之”字或锯齿状。地物裂缝较之地表裂缝数量更多、但规模更小,寺院建筑群受隐伏张性地裂缝影响致地基形变造成地面以上结构开裂;停采后监测期内,堆积体变形速率趋于收敛,残余变形消减,由变形移动转为基本稳定;③完全采空后,堆积层表现为以下错为主的拉张变形,剪应变显现,持续开采条件下堆积层变形程度将加剧。下伏基岩最大主应力增量达1080.75%,拉应力集中;④短壁房式开采留设区段煤柱利于减小堆积层变形。研究为认识地下资源开采扰动斜坡上覆堆积层变形破坏与寻求古建筑压煤开采文物保护解决方案提供了参考。

特厚煤层垂直分层区段窄煤柱围岩稳定性及控制技术

针对特厚煤层垂直分层区段窄煤柱大变形失稳控制难题,采用理论分析、数值模拟及现场试验相结合的方法,对内蒙古老公营子煤矿特厚煤层窄煤柱围岩稳定性及控制技术展开研究。笔者在对窄煤柱内三向应力计算的基础上,基于摩尔−库伦破坏强度得到窄煤柱平面应变的屈服准则,定性分析了窄煤柱破坏特征及损伤程度演化规律,进一步分析了区段窄煤柱失稳机理及其尺寸效应影响规律,最后给出区段窄煤柱围岩控制关键技术,并通过数值模拟及现场试验进行验证。研究成果表明:①窄煤柱中部破坏程度大于两帮,中部自顶端向下煤体破坏程度由严重向轻微发展。随着宽高比增大窄煤柱内破坏程度及严重破坏区域占比逐渐减小,当宽高比大于1∶1,窄煤柱中下部开始出现大范围的轻微破坏区,当宽高比大于5∶3,轻微破坏区占比超过50%。当黏聚力C≥3 MPa,或内摩擦角φ≥20°时,窄煤柱两帮破坏程度转变为轻微。②工作面回采巷道一侧为窄煤柱低强度承载区,在上部高应力作用下,大范围的低应力承载区煤体向巷道位移,造成两帮持续性大变形,进而影响顶板的稳定性。煤柱高度是中、底分层区段窄煤柱稳定的主控因素,窄煤柱宽高比增大,对高强度承载区承载强度影响程度较小,而低强度承载区承载强度增加较明显,合理的窄煤柱宽高比可平衡煤柱内高、低强度承载区比例,并提高承载强度。③分层窄煤柱留设需考虑工作面两侧采空时围岩稳定性,保证煤柱内部高强度承载区范围大于煤柱宽度及高度的一半,并通过联合加强支护措施使煤柱内形成由浅入深的多重联合控制区,共同维护煤柱的自稳能力。

多弱层顺倾软岩边坡控制开采技术

针对多弱层顺倾软岩边坡下部压煤问题,从边坡变形风险可控以及资源回收最大化角度出发,在分析地质资料和弱层层位的基础上,结合单一弱层的控制开采技术,提出了多弱层顺倾软岩边坡控制开采技术;以扎尼河露天矿北端帮边坡为工程背景,基于极限平衡理论,分析了北端帮边坡的稳定性,对多弱层控制的顺倾软岩边坡控制开采方案进行了研究。研究表明:通过多弱层顺倾软岩边坡控制开采技术的实施,可在采场深部增加内排物料形成“中间桥”工艺,对深部弱层形成“压覆”,对整体边坡形成“支撑”,保证边坡沿各弱层滑动均得以控制,实现多弱层顺倾软岩边坡煤炭高效回收以及蠕动形变的稳定性控制。

基于能量演化的反倾层状岩坡多级折断面深度计算模型

多级折断是反倾层状岩质斜坡倾倒过程中普遍发育的一种变形破坏现象。为准确定位反倾层状岩质斜坡倾倒变形过程中多级折断带的埋藏深度,首先从能量守恒角度出发,结合悬臂梁模型,利用外力做功吸收能量与板梁变形释放能量守恒关系推导单层板梁能量平衡方程;在此基础上,根据岩体弹性屈服和弯折破坏2种临界失稳状态,分别推导出2种板梁失稳折断计算模型,并通过改变岩层倾角、斜坡坡角、斜坡高度等参数建立反倾层状岩质斜坡多级折断面深度计算模型;最后,利用离心模型试验和实际工程案例对计算模型的可靠性进行验证。研究结果表明:离心模型试验能够充分揭示反倾层状岩质斜坡倾倒变形过程中存在多级折断现象,整个倾倒变形过程可分为后缘岩体倾倒变形、岩层折断面裂隙逐级形成贯通和斜坡岩体倾倒失稳3个阶段;反倾层状岩坡多级折断面深度计算模型结果与离心模型试验结果、云南某边坡工程案例中各级折断带的埋深相吻合,证明了提出的反倾层状岩坡多级折断面深度计算模型可对离心模型试验和实际工程案例进行较为准确的折断深度定位,且能够根据计算结果判别边坡变形破坏的主要失稳模式。研究成果对反倾层状岩质斜坡的稳定性评价研究及破坏机制分析具有一定的理论和实际意义。

跨煤岩界面穿层压裂裂缝动态扩展特征试验研究

针对跨煤岩界面穿层压裂裂缝动态扩展过程,采用相似材料制作煤岩组合体试件,开展三点弯曲试验、真三轴水力压裂物理模拟试验,分别结合数字散斑技术、声发射监测技术,捕捉裂缝的动态扩展特征,分析裂缝扩展形态及影响因素。结果表明:三点弯曲试验中裂缝可从顶板直接进入煤层,裂缝在界面处未转向,增大预制裂缝长度试件断裂所需的峰值应力降低;真三轴水力压裂试验条件下,由于煤层塑性强,顶板内裂缝高度、长度均大于煤层,顶板内声发射事件比例高于煤层;在裂缝穿层扩展的前提下,增大水平井与煤层顶面距离会导致裂缝穿层扩展时间延长,提高压裂液注入排量可增大裂缝进入煤层的穿透深度,但是易导致缝高失控、缝长降低,提出采用变排量压裂施工,初期压裂液大排量注入促使裂缝纵向穿层,随后降排量促进裂缝在顶板和煤层内横向延伸;多裂缝同步起裂时缝间存在竞争扩展现象,部分裂缝可能无法穿层扩展。研究成果可为掌握裂缝跨煤岩界面穿层扩展特点、优化设计压裂施工参数提供理论支撑。

超厚中风化层高陡边坡稳定性研究

风化作用使岩石强度降低,进而导致边坡岩体的力学性能大幅度下降,因此露天矿山高陡边坡主要以微风化岩体为主,而以中风化岩体为主的边坡通常设计较为平缓,高度也多为30~50 m。对某钼矿完整性好的超厚中风化层高陡边坡稳定性进行研究,采用极限平衡法计算爆破振动力作用下的边坡安全系数,并根据计算结果对边坡参数进行优化,为下一步的设计提供技术支持。结果表明:边坡稳定性主要受到岩石强度和岩体完整性2个方面因素的影响,深部的中风化层如果节理裂隙发育减少,岩体完整性提升,边坡的稳定性也得到改善,完整性好的超厚中风化层也可以设计为高陡边坡。

顺倾软岩露天煤矿到界边坡参数及高效开采技术研究

针对顺倾软岩露天煤矿到界边坡参数问题,从经济、技术及安全等角度出发,结合高效开采技术,基于极限平衡法提出一种基于高效开采技术的顺倾软岩露天煤矿到界边坡参数研究方法,并以扎尼河露天矿为工程背景,对二采区西帮到界边坡参数及高效开采技术进行研究。结果表明:当西帮边坡同帷幕保持50 m安全距离时,边坡沿帷幕破坏的稳定系数满足到界边坡安全储备系数要求;而正常到界边坡参数满足安全储备系数要求但压覆煤量较大,通过对二采区西帮实施预应力锚索加固后,边坡角可提高约7°,资源回收率有极大的提升,剖面1和剖面2在单米宽度下可多采煤炭资源1.09万t、0.97万t,且边坡仍处于稳定状态。研究结果可为类似的顺倾软岩露天煤矿到界边坡参数的确定及原煤开采方法提供借鉴。

葫芦素煤矿上覆岩体运移规律及“上三带”发育高度

为研究大采宽条件上覆岩体运移与离层空间发育规律及“上三带”的关系,以内蒙葫芦素煤矿21406工作面与21101工作面为研究对象。采用多种方法如理论预测、建立模型进行数值模拟、钻探取芯观测岩性与裂隙发育、注水测量漏失量与窥视等方法研究了回采面开采后上覆岩层移动与变形规律与“上三带”发育关系。21406工作面位移呈“中间大、两边小”的分布态势,其运动速度先增加后减小,并在推过钻孔138 m处取得极大值;工作面推过138~178 m的范围内,为离层演化和发育的核心区间,并在322 m开始减弱并发生闭合;离层空间分布在距离煤层约260 m向上区域。21101工作面随着推进距离的增加,裂隙发育范围由“拱形”逐步演化为“马鞍形”,其发育的高度在推进80 m时达到61.6 m的最大值;注水实测导水裂隙带高度为65.39 m,裂采比为22.54倍。离层空间含水层发育在煤层上方260 m以上,远离导水裂隙带范围。本文研究结果为离层注浆与顶板疏放水提供了较为扎实的设计依据。

煤矸石代替粉煤灰充填的研究与应用

“三下”压煤开采时,采用覆岩离层注浆充填工艺,通过注浆材料优化,对煤矸石和粉煤灰两种材料进行采样分析、地面沉降效果分析及经济效益对比,得出了采用煤矸石代替粉煤灰作为原材料进行覆岩离层注浆能够实现经济效益最大化的结论。

煤柱-顶板结构能量演化特征及稳定性研究

煤矿事故的发生大多是由煤柱及其上覆顶板岩层失稳破坏引起的。为了研究不同煤-岩高度比对煤柱-顶板结构变形破坏及能量演化机制的影响,对煤-岩高度比分别为1∶3、1∶2、1∶1、2∶1及3∶1的煤-岩组合体进行了单轴加载及循环加卸载试验,研究了煤-岩结构体变形与能量演化之间的变化关系,利用加卸载响应比对煤-岩组合体的稳定性进行分析,对煤-岩组合体稳定性进行定量评价。结果表明:煤-岩组合体在单轴加载及循环加卸载作用下的峰值强度均随着煤-岩高度比的增加而逐渐降低,煤-岩组合体在循环加卸载作用下的峰值强度均低于单轴加载试验中的峰值强度,煤-岩高度比越大,循环载荷作用下组合体峰值强度降低率越小;组合体输入能、弹性能和耗散能随应力增加呈非线性增加,煤-岩高度比与组合体循环载荷过程中产生的平均弹性应变、平均弹性能、平均残余应变、平均耗散能、总残余应变和加卸载响应呈正比关系,与总弹性应变、总弹性能和总耗散能呈反比关系。