库岸塔柱状危岩的压裂耦合损伤-突变失稳预测

位于三峡库区巫峡段消落带的塔柱状危岩,其底部多损伤因素的耦合作用下常呈压裂诱发座溃整体失稳模式,危岩底部耦合损伤至突变机制是研究该类库岸危岩体失稳预警的关键科学问题.以三峡库区库岸巫峡段箭穿洞塔柱状危岩体为例,将危岩体简化为中上部非劣化区和下部劣化区的二元地质力学模型,基于应变等价原理获得其危岩体下部劣化区的荷载效应、溶蚀效应、干湿循环弱化效应的耦合损伤本构模型和总损伤度演化方程,根据地质力学模型概化为等效弹簧模型转化为力-位移的耦合损伤本构方程;基于能量平衡原理和突变理论建立了塔柱状危岩的耦合损伤-折叠突变模型,获取了其失稳判据和临界位移的表达式.通过案例分析结果表明:该危岩体突变失稳时的系统控制变量为-0.0073,预测模型计算理论的突变起点垂向位移为42.2mm,终止点位移为60.5mm,当监测数据危岩体最大垂向累积位移为26.2mm时,小于突变起始位移时就采用及时治理措施,与危岩未失稳的状态吻合.其研究成果可为三峡库区灰岩地区库岸塔柱状压溃型危岩的监测预警与防治提供重要的理论支撑.

掘进巷道过陷落柱围岩控制技术研究

针对掘进巷道过陷落柱期间围岩变形量大、支护困难和顶板淋水严重的问题,以华阳一矿81214回风巷为研究对象,采用理论分析和现场试验的研究方法,对过陷落柱期间巷道围岩特征和巷道原支护存在的问题进行分析,提出了“超前注浆+顶板全锚索+双层金属网+喷浆”的掘进巷道过陷落柱围岩综合控制措施。现场试验结果表明:采用综合控制措施后,过陷落柱段巷道顶底板最大下沉量为41.64 mm,巷帮最大位移量为20.31 mm,围岩变形控制效果显著,确保了巷道稳定性和工作面生产安全。

Energy conversion and deposition behaviour in gravitational collapse of granular columns

The high-density gravitational collapse of granular columns is very similar to the movements of large collapsing columns in nature. Based on the development of dangerous columnar rock mass in fields, granular column collapse boundary condition in the physical experiments of this study is a new type of boundary conditions with a single free face and a three-dimensional deposit. Physical experiments have shown that the mobility of small particles during the collapse of granular columns was greater than that of large particles. For example, when particle size was increased from 5 to 15 mm, deposit runout was decreased by about 16.4%. When a column consisted of two particle types with different sizes, these particles could mix in the vicinity of layer interfaces and small particles might increase the mobility of large particles. In the process of collapse, potential and kinetic energy conversion rate is fluctuated. By increasing initial aspect ratio a, the ratio of the initial height of column to its length along flow direction,potential and kinetic energy conversion rate is decreased. For example, as a was increased from 0.5 to 4, the ratio of maximum kinetic energy obtained and total potential energy loss was decreased from47.6% to 7.4%. After movement stopped, an almost trapezoidal body remained in the column and a fanlike or fan-shaped accumulation was formed on the periphery of column. Using multiple exponential functions of the aspect ratio a, the planar morphology of the collapse deposit of granular columns could be quantitatively characterized. The movement of pillar dangerous rock masses with collapse failure mode could be evaluated using this granular column experimental results.

Modeling and cyclic behavior of segmental bridge column connected with shape memory alloy bars

This paper examines the quasi-static cyclic behavior, lateral strength and equivalent damping capacities of a system of post-tensioned segmental bridge columns tied with large diameter martensitic Shape Memory Alloy （SMA） link-bars. Moment-curvature constitutive relationships are formulated and analysis tools are developed for the PT column, including a modified four-spring model prepared for the SMA bars. The suggested system is exemplified using a column with an aspect ratio of 7.5 and twelve 36.5 mm diameter NiTi martensitic SMA bars. A post-tensioning force of 40% to 60% of the tendon yield strength is applied in order to obtain a self re-centering system, considering the residual stress of the martensitie SMA bars. The cyclic response results show that the lateral strength remains consistently around 10% of the total vertical load and the equivalent viscous damping ratios reach 10%-12% of critical. When large diameter NiTi superelastic SMA bars are incorporated into the column system, the cyclic response varies substantially. The creep behavior of the superelastic SMA bar is accounted for since it affects the re-centering capability of the column. Two examples are presented to emphasize the modeling sensitivities for these special bars and quantify their cyclic behavior effects within the column assembly.

Numerical analysis of seepage flow characteristic of collapse column under the influence of mining

Based on the importance of fractured rock mass seepage research, in order to analyze seepage flow characteristics of collapse column under the influence of mining, a method by embedding fractured rock mass flow solid coupling relationship into FLAC3D internal flow models is presented according to fluid-solid coupling theory and strength criterion. A calculation model of numerical analysis was established, and the influences of mining pressure and plastic damage to pore water pressure and seepage vector change rule were studied. The results show that collapse column is the main channel of confined water seepage upward. The impact is not big when the workface is away from the collapse column. But when the workface is nearing a collapse column, there will be a seepage channel on a side near the workface, in which seepage vector and head are comparatively large. With workface pushing through collapse column, the seepage channel transfers to the other side of the column. In addition, when the plastic damage area within the collapse column breaks through, a "pipeline flow" will be formed within the column, and seepage field will change remarkably and the possibility of water bursting will be greater.

Investigation of long-wavelength elastic wave propagation through wet bentonite-filled rock joints

The saturation of the compacted bentonite buffer in the deep geological repository can cause bentonite swelling,intrusion into rock fractures,and erosion.Inevitably,erosion and subsequent bentonite mass loss due to groundwater inflow can aggravate the overall integrity of the engineered barrier system.Therefore,the coupled hydro-mechanical interaction between the buffer and rock during groundwater inflow and bentonite intrusion should be evaluated to guarantee the long-term safety of deep geological disposal.This study investigated the effect of bentonite erosion and intrusion on the elastic wave propagation characteristics in jointed rocks using a quasi-static resonant column test.Jointed rock specimens with different joint conditions(i.e.joint surface saturation and bentonite filling)were prepared using granite rock discs sampled from the Korea Underground Research Tunnel(KURT)and Gyeongju bentonite.The long-wavelength longitudinal and shear wave velocities were measured under different normal stress levels.A Hertzian-type power model was used to fit the wave velocities,and the relationship between the two fitted parameters provided the trend of joint conditions.Numerical simulations using three-dimensional distinct element code(3DEC)were conducted to better understand how the long-wavelength wave propagates through wet bentonite-filled rock joints.

深埋岩溶隧道爆破开挖对围岩损伤及渗流特性的影响

深埋岩溶隧道开挖会造成围岩特殊的损伤破坏形式,并且损伤区也会影响围岩渗流场及隧道边界的涌水状况,对深埋岩溶隧道爆破开挖作用下围岩的损伤及渗流特性有重要的研究意义。为了研究爆破开挖对深埋岩溶隧道围岩损伤及渗流的影响规律,基于COMSOL Multiphysics软件建立数值模型并嵌入应力-渗流-损伤耦合方程式进行计算,采用解析法计算了简化条件下岩溶隧道开挖时围岩的应力分布,并与数值计算结果进行比较。结果表明:解析法与数值法计算的围岩应力分布有一致性,爆炸荷载使靠近溶洞侧隧道肩部及脚部区域会产生较大的拉应力;爆破后会在隔水岩柱形成“齿”状损伤区,同时引起肩部及脚部区域流速的增加,其可作为判断溶洞方位的参考依据;溶洞净距减小、洞径及水压增加会引起“齿”延伸倾角及最大涌水位置变化、隧道边界涌水量的增加,可根据“齿”延伸方向判断损伤区检测的合理方位,根据最大涌水位置变化、隧道边界涌水量的变化,合理调整涌水防治措施强度及重点防治部位。研究成果可为溶洞位置判定、隧道损伤区检测以及边界涌水防治措施提供参考。

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。

近场脉冲型地震作用下附加支撑双柱式摇摆桥墩的抗震性能研究

为了解决摇摆桥墩承载力和耗能能力不足的问题,该文提出一种附加人字形支撑的双柱式摇摆桥墩结构,支撑为纯耗能支撑或自复位耗能支撑,支撑通过连接装置安装在双柱式摇摆桥墩的盖梁和承台之间。为了研究新型附加人字形支撑双柱式摇摆桥墩的抗震性能,对其进行拟静力分析,将双柱式现浇桥墩和双柱式纯摇摆桥墩作为对比模型,研究附加纯耗能支撑和自复位耗能支撑双柱式摇摆桥墩的滞回性能;分别对这四种桥墩结构进行动力时程分析,探究这四种桥墩在近场对称脉冲、近场非对称脉冲和远场无脉冲地震动作用下的动力响应。研究结果表明:附加支撑的双柱式摇摆桥墩中的墩柱仍具有摇摆机制,可有效避免墩身出现塑性铰发生严重的损伤破坏,同时附加的支撑可以显著提高桥墩的承载能力和耗能能力,有效降低桥墩结构的位移响应,特别是自复位耗能支撑还可额外为桥墩提供自恢复力,有效提高结构的抗震性能。

摩擦耗能型摇摆柱节点抗震性能研究

基于可恢复功能的概念,提出了一种摩擦耗能型摇摆柱节点。阐述了该节点的构造形式并研究了其抗震性能。通过试验和数值模拟,分析了轴压比、弹簧刚度等参数对节点抗震性能的影响及节点在余震和修复情况下的韧性。研究结果表明,在±3%层间位移角内,节点呈现出低损伤特性,摇摆柱始终保持弹性。在轴向力作用下,滞回曲线呈明显的“旗帜形”,节点具有良好的自复位性能,最大残余转角仅为0.23%。通过重新拧紧螺栓,节点性能即可恢复至震损前水平,实现抗震韧性。弹簧刚度的增大可以显著提高节点的抗弯承载力;增大轴压比可以提高节点的“屈服”弯矩和极限弯矩。在轴向力作用下节点属于典型的半刚性连接,并确定了节点初始转动刚度的取值范围。针对该节点提出了一个简化的恢复力模型,理论结果与试验结果吻合度较好,为进一步对整体结构进行分析和设计奠定了基础。

柱脚不同连接形式钢框架-摇摆墙结构抗震性能对比分析

增设摇摆墙后框架结构地震下柱脚仍会发生一定程度的塑性损伤,将柱脚设置为铰接或提离后有望减轻上述缺陷。以三层、六层和九层钢框架为基准模型,分别建立柱脚固接、铰接及提离三种框架-摇摆墙结构模型并进行动力弹塑性时程分析,对比各结构最大侧向位移、层间位移角、峰值加速度、层间剪力、墙体剪力和弯矩等;进一步建立耗能连梁固接和铰接的对比模型,研究连梁连接方式对结构抗震性能的影响。结果表明:三层模型中柱脚固接时侧向位移、层间位移角、加速度、层间剪力及摇摆墙墙体剪力的控制效果最优,六层、九层模型中分别对应柱脚提离和柱脚铰接效果最好;摇摆墙墙体剪力图和弯矩图分别呈现“C形”和“反C形”,柱脚固接时墙体弯矩均为最小,与层数无关。柱脚固接耗能连梁两端采用固接最优,柱脚铰接和柱脚提离时耗能连梁两端采用铰接形式效果更优。此分析可为框架-摇摆墙结构进一步推广应用提供参考。

外置耗能角钢的摇摆-自复位桥梁双柱墩地震易损性分析

为评估设置耗能角钢的摇摆-自复位桥梁双柱墩的抗震能力,本文建立该结构的有限元分析模型,分别定义和量化双柱墩不同损伤状态和损伤指标。本文从太平洋地震工程研究中心选取16条近断层地震动,基于增量动力分析,得到该结构的地震响应。基于最小二乘法,对得到的增量动力分析曲线进行对数回归分析,计算结构不同损伤状态的超越概率及易损性曲线。研究表明:当地面峰值加速度为0.1 g时,外置耗能角钢与耗能钢筋屈服的超越概率分别为34%和22%;当峰值加速度为0.4 g时,外置耗能角钢与耗能钢筋失效的超越概率分别为6%和11%,而预应力筋未屈服;当峰值加速度为1.0 g时,外置耗能角钢和耗能钢筋失效的概率分别达到85%和91%,桥墩发生倒塌的概率为46%。

基于静力试验的柱端铰型受控摇摆钢筋混凝土框架地震响应数值分析

柱端铰型受控摇摆钢筋混凝土框架(CR-RCFC)是一种新型的可恢复功能结构,通过摇摆节点的构造来“弱化”结构整体抗侧刚度,从而达到减小地震响应的目的。CR-RCFC结构在振动台试验中呈现了在中震和大震作用下“主体构件免损伤,耗能构件易更换”的韧性抗震效果。振动台试验后进行低周反复静载试验得到拆除阻尼器后的CR-RCFC结构柱铰节点弯矩-转角滞回曲线和转动刚度等抗震性能参数。利用静力试验得到的结构抗震性能参数进行结构地震响应数值模拟,将数值模拟结果与振动台试验结果进行对比分析。对比分析结果表明:通过静力试验数据可以精确得到CR-RCFC结构节点抗震性能参数,根据该抗震性能参数进行的数值模拟结果与振动台试验结果吻合较好。

基于模型试验的某矿区地下开采过程中采场稳定性研究

目的:围岩稳定性是岩土工程界重要研究内容之一,较差的围岩可能会使地下工程如隧道、矿井等发生坍塌。因此,为了确保地下工程的安全施工和稳定性,对围岩稳定性的研究至关重要。方法:本研究在充分调查某矿区某矿段采场结构参数及对地压控制研究分析后,基于矿体的赋存条件、地质产状以及顶底板的实际情况,选取了某矿段中比较有代表性的剖面,采用相似模型试验的方法,围绕点柱控顶建立室内相似试验模型,对该矿地下开采过程中采场的稳定性进行模拟分析。结果:随着矿体倾角的增大,围岩变形随之增大。在完全空场条件下,即只留中段矿柱,不留点柱,顶板会发生大面积破坏,并有可能出现地表塌陷,造成安全事故。结论:本研究要预留点柱控制地压,防治冲击地压。意义:研究成果对指导该矿区矿体的安全开采和利用具有重要的理论和实践意义。

支撑与基础刚接的摇摆钢支撑框架结构抗震性能研究

为了使摇摆钢支撑框架结构具备耗能能力,更好地控制结构在地震作用下的摇摆幅值,提出在摇摆钢支撑两侧框架柱的柱脚位置设置耗能装置,同时简化摇摆钢支撑与基础之间的构造,支撑与基础采用刚性连接。应用有限元软件ABAQUS建立支撑与基础刚接的摇摆钢支撑框架结构模型,对模型进行低周往复加载,得到了其破坏模式,分析了耗能柱脚剪切板开孔间距、剪切板厚度和中心钢支撑跨度等设计参数对其滞回性能的影响,给出了结构设计参数的建议取值和极限承载力计算公式。分析结果表明:支撑与基础刚接的摇摆钢支撑框架结构滞回性能良好,破坏模式合理;在水平荷载作用下,耗能柱脚率先进入塑性耗能,塑性变形充分,耗能能力强;加载过程中,高强度螺栓未达到极限强度,连接方式可靠;随着开孔间距、剪切板厚度和支撑跨度的增加,结构在相同侧移比下的抗侧承载力和刚度提高,但是耗能能力有所下降;公式计算结果与有限元结果吻合较好,可供实际工程参考。

连柱摇摆钢支撑抗震性能研究

为了提高连柱摇摆钢支撑的耗能能力,提出了支撑跨柱脚采用开椭圆孔截面的新型构造措施。采用有限元分析软件ABAQUS建立连柱摇摆钢支撑框架结构模型,进行了低周往复加载,对比分析了耗能连梁长度、框架跨度、框架高度等不同设计参数对结构抗震性能的影响。分析结果表明:连柱摇摆钢支撑主要由耗能连梁及耗能柱脚进入塑性来耗散能量,结构具有合理的破坏模式;连柱摇摆钢支撑结构具有较好的耗能能力,滞回曲线为饱满的梭形;结构的极限承载能力随着耗能连梁长度的增加呈现出先增大后减小的趋势,结构的累积滞回耗能能力也逐渐降低;耗能连梁应宜采用剪切屈服型,建议耗能连梁长度的取值范围为(1.2~1.5)Mp/Vp;增大框架跨度和减小框架高度等可以显著提升结构的耗能能力、刚度和承载能力。基于小变形假定和虚功原理,分析了连柱摇摆钢支撑结构在极限状态的典型屈服机制,推导出极限承载力计算公式,与有限元计算结果比较吻合,验证了公式的合理性,可为工程应用提供参考。

屈服摇摆消能双层框架墩结构横桥向地震反应分析

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