共查询到17条相似文献,搜索用时 125 毫秒
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地震作用下立式储液罐罐壁“象足”变形仿真分析 总被引:1,自引:0,他引:1
基于ANSYS软件建立了考虑液体晃动和罐底提离立式储液罐有限元模型,分别进行了水平地震和竖向地震作用下罐壁“象足”变形分析。分析表明:立式储液罐罐壁“象足”变形主要是由罐壁纵向压应力超过临界应力而产生的局部屈曲破坏,并非强度破坏。因罐底提离导致的罐底与基础反复撞击加大了作用在罐壁上的应力,使罐壁底部“象足”变形不断发展,最终导致罐壁撕裂。在完全相同地震加速度作用下,水平地震作用比竖向地震作用罐壁更早更容易进入屈曲状态,产生“象足”变形。 相似文献
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地震作用下立式储液罐罐壁"象足"变形仿真分析 总被引:2,自引:0,他引:2
基于ANSYS软件建立了考虑液体晃动和罐底提离立式储液罐有限元模型,分别进行了水平地震和竖向地震作用下罐壁"象足"变形分析.分析表明:立式储液罐罐壁"象足"变形主要是由罐壁纵向压应力超过临界应力而产生的局部屈曲破坏,并非强度破坏.因罐底提离导致的罐底与基础反复撞击加大了作用在罐壁上的应力,使罐壁底部"象足"变形不断发展,最终导致罐壁撕裂.在完全相同地震加速度作用下,水平地震作用比竖向地震作用罐壁更早更容易进入屈曲状态,产生"象足"变形. 相似文献
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为了研究桩土、隔震层与罐体相互作用对15×104m3隔震储罐地震响应的影响,桩与隔震层采用弹簧-阻尼单元,罐体采用壳单元,流体采用势流体单元,基于ADINA建立数值仿真分析模型,在8度E1 Centro地震动激励下,应用Newmark数值积分方法进行地震响应分析.结果表明:隔震储罐基底剪力和基底弯矩相对于非隔震储罐明显降低,储罐罐壁加速度沿罐壁高度方向近乎平动,但对波高的控制效果不明显;除罐壁顶部外,动液压力明显降低;隔震后,罐壁有效应力和环向应力减震效应明显,对轴向应力和径向应力影响较小,建议从安全角度考虑,储罐非隔震设计时不考虑桩土作用,隔震设计时考虑桩土对罐体的影响. 相似文献
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水平地震作用下无锚固储罐应力与应变响应分析 总被引:1,自引:0,他引:1
在考虑地基与储罐相互作用的情况下,采用有限元法对储罐在水平地震荷载作用下的应力及应变反应进行了数值计算。对3×104m3和2×103m3罐壁应力及应变的分析结果表明:环向、轴向应力及应变的分布形式呈现出明显的下部大上部小的特点,在偏底部的位置出现应力和应变的峰值;储液罐在水平地震作用下“象足”变形是由纵向压应力达到屈曲临界应力导致的屈曲破坏,不是强度破坏,即破坏属于失稳破坏而非强度破坏。 相似文献
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《地震工程与工程振动》2015,(5)
立式浮顶储罐在强震作用下会发生罐壁屈曲、卡顶、浮顶下沉等震害。为降低储罐地震响应,以1 000 m3储罐为原型,按1:5的几何相似比设计缩尺模型,并以隔震周期为0.5 s进行并联隔震装置设计,给出其力学本构关系。采用模拟地震振动台试验方法,选取四种不同频谱特性的地震动对模型罐进行地震响应分析,结果表明:隔震层顶部加速度卓越频率有所降低,周期延长;隔震后储罐加速度、层间位移及动应力地震响应明显降低,但晃动波高有所放大;三向地震激励与单向地震激励相比,加速度地震响应明显放大,对晃动波高影响较小。建议储罐抗震减震设计时应考虑三向地震作用。 相似文献
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大型LNG储罐中,铝吊顶是位于其内罐顶部,挂载保温绝热材料以形成封闭低温储存环境的大跨悬挂结构。铝吊顶在强震下的响应可能影响到储罐的安全和正常运作,值得研究和分析。建立了包含对瓦楞型新型铝吊顶精细化建模的大型LNG储罐的有限元分析模型,分析了在不同类型及强度的地震激励下,铝吊顶的响应特征及规律。重点探讨了储罐基础隔震对其地震响应的影响。研究分析发现:储罐基础隔震后,吊顶主共振区后移,水平和竖向自振周期均延长0.5 s,节点水平位移减小约29.9%~40.0%,杆件应力减小约27.2%~32.5%。基于增量动力分析法(IDA)对铝吊顶进行的地震易损性分析,结果表明:在不同地震作用下,吊顶的薄弱部位为边缘吊杆区域,其材料的强度富余量较大,整体发生掉落的可能性较小;吊顶在强震中产生的水平晃动较小,与周边密封材料发生碰撞的可能性较小,建议当前设计中吊顶边缘与内罐壁的留缝距离可适当缩小以提高保冷效果。 相似文献
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双层岛式地铁车站结构地震反应分析 总被引:2,自引:2,他引:0
以深圳某双层两跨岛式地铁车站为工程背景,考虑水平地震和水平、竖向地震耦合2种工况,采用ANSYS分析软件,研究SSI(土与结构相互作用)效应下结构的水平位移特征和内力响应规律.结果表明:与水平地震工况相比,耦合地震作用下结构最大内力增幅较大,由于竖向惯性荷载作用,产生最大内力位置不同;周围土体介质的变形与结构在震动中的变形关系密切;沿车站侧墙高度的相对水平位移在2种地震工况作用下的变化不容忽视,不可忽略竖向地震的影响,耦合地震作用下的相对水平位移可用线性曲线拟合.研究成果可为地铁车站的抗震设计提供参考. 相似文献
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A method for analyzing the earthquake response of elastic, cylindrical liquid storage tanks under vertical excitations is presented. The method is based on superposition of the free axisymmetrical vibrational modes obtained numerically by the finite element method. The validity of these modes has been checked analytically and the formulation of the load vector has been confirmed by a static analysis. Two forms of ground excitations have been used: step functions and recorded seismic components. The radial and axial displacements are computed and the corresponding stresses are presented. Both fixed and partly fixed tanks are considered to evaluate the effect of base fixation on tank behaviour. Finally, tank response under the simultaneous action of both vertical and lateral excitations is calculated to evaluate the relative importance of the vertical component of ground acceleration on the overall seismic behaviour of liquid storage tanks. 相似文献
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A hybrid analytical and FEM is proposed to investigate the nonlinear sloshing in a floating‐roofed oil storage tank under long‐period seismic ground motion. The tank is composed of a rigid cylindrical wall and a flat bottom, whereas the floating roof is treated as an elastic plate undergoing large deflection. The contained liquid is assumed to be inviscid and incompressible, and the flow is assumed to be irrotational. The method of analysis is based on representation of the liquid motion by superposing the analytical modes that satisfy the Laplace equation and the rigid wall and bottom boundary conditions. The FEM is then applied to solve the remaining kinematic and dynamic boundary conditions at the moving liquid surface coupled with the nonlinear equation of motion of the floating roof. This requires only the discretization of the liquid surface and the floating roof into finite elements, thus leading to a computationally efficient and accurate method compared with full numerical analysis. As numerical examples to illustrate the applicability of the proposed method, two oil storage tanks with single‐deck type floating roofs damaged during the 2003 Tokachioki earthquake are studied. It is shown that the nonlinear oscillation modes with the circumferential wave numbers 0, 2 and 3 caused by the finite liquid surface elevation as well as the membrane action due to large deflection of the deck produce excessively large stresses in the pontoon, which may cause the catastrophic failure of pontoon followed by the submergence of the roof. Copyright © 2012 John Wiley & Sons, Ltd. 相似文献
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Sandip Kumar Saha Vasant A. Matsagar Arvind K. Jain 《Bulletin of Earthquake Engineering》2016,14(4):1153-1175
Seismic fragility curves for fixed-base and base-isolated liquid storage tanks are developed under non-stationary earthquakes, and their seismic performance are compared. The correlation between different earthquake intensity measure (IM) parameters and peak response quantities of the base-isolated liquid storage tanks are investigated. The failure criteria are chosen based on (1) the elastic buckling strength of the tank wall, which is defined in terms of critical base shear and critical overturning moment, and (2) in terms of the critical isolation displacement. The uncertainty involved is considered in the earthquake characteristics. Non-stationary earthquake ground motions are generated using Monte Carlo (MC) simulation. Influence of the isolator characteristic parameters and modeling approaches on the seismic fragility of the base-isolated liquid storage tanks is also investigated. Peak ground acceleration is found to be the well correlated IM parameter with the peak response quantities of the base-isolated liquid storage tanks. Substantial decrease in the seismic fragility of the base-isolated liquid storage tanks is observed as compared to the fixed-base tanks. Significant influence of the isolator characteristic parameters on the seismic fragility of the base-isolated liquid storage tanks are reported in the present study. 相似文献
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A common effective method to reduce the seismic response of liquid storage tanks is to isolate them at base using base-isolation systems. It has been observed that in many earthquakes, the foregoing systems significantly affect on the whole system response reduction. However, in exceptional cases of excitation by long-period shaking, the base-isolation systems could have adverse effects. Such earthquakes could cause tank damage due to excessive liquid sloshing. Therefore, the numerical seismic response of liquid storage tanks isolated by bilinear hysteretic bearing elements is investigated under long-period ground motions in this research. For this purpose, finite shell elements for the tank structure and boundary elements for the liquid region are employed. Subsequently, fluid–structure equations of motion are coupled with governing equation of base-isolation system, to represent the whole system behavior. The governing equations of motion of the whole system are solved by an iterative and step-by-step algorithm to evaluate the response of the whole system to the horizontal component of three ground motions. The variations of seismic shear forces, liquid sloshing heights, and tank wall radial displacements are plotted under various system parameters such as the tank geometry aspect ratio (height to radius), and the flexibility of the isolation system, to critically examine the effects of various system parameters on the effectiveness of the base-isolation systems against long-period ground motions. From these analyses, it may be concluded that with the installation of this type of base-isolation system in liquid tanks, the dynamic response of tanks during seismic ground motions can be considerably reduced. Moreover, in the special case of long-period ground motions, the seismic response of base-isolated tanks may be controlled by the isolation system only at particular conditions of slender and broad tanks. For the case of medium tanks, remarkable attentions would be required to be devoted to the design of base-isolation systems expected to experience long-period ground motions. 相似文献
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液压阻尼系统控制浮放立式储罐提离失稳 总被引:1,自引:0,他引:1
立式圆柱储罐在油田、石油化工等企业用途广泛,多用作存贮易燃、易爆介质,一旦遭遇震害,后果将十分严重。本文针对浮放立式储罐地震响应的提离失稳问题,采用液压阻尼系统(HDS)用以控制储罐的提离反应,建立了安装HDS储罐的力学分析模型并进行了数值计算,对安装HDS后储罐的提离反应进行了分析。仿真计算结果表明:HDS可以有效地减小提离应力,从而地震烈度可以降低1度进行储罐的提离设计。 相似文献
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浮放储罐三维地震反应有限元分析 总被引:1,自引:0,他引:1
针对立式储罐,考虑液固耦合效应、地基与储罐结构的相互作用,采用有限元分析方法,对储罐在三维地震荷载作用下动反应进行了数值分析。分析结果表明:储罐三维地震加速度反应较一维地震加速度反应增加、提离高度明显放大、储罐轴向应力增加、基底剪力与弯矩增大。 相似文献
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The seismic response of an isolated vertical, cylindrical, extra-large liquefi ed natural gas (LNG) tank by a multiple friction pendulum system (MFPS) is analyzed. Most of the extra-large LNG tanks have a fundamental frequency which involves a range of resonance of most earthquake ground motions. It is an effective way to decrease the response of an isolation system used for extra-large LNG storage tanks under a strong earthquake. However, it is diff icult to implement in practice with common isolation bearings due to issues such as low temperature, soft site and other severe environment factors. The extra-large LNG tank isolated by a MFPS is presented in this study to address these problems. A MFPS is appropriate for large displacements induced by earthquakes with long predominant periods. A simplifi ed fi nite element model by Malhotra and Dunkerley is used to determine the usefulness of the isolation system. Data reported and statistically sorted include pile shear, wave height, impulsive acceleration, convective acceleration and outer tank acceleration. The results show that the isolation system has excellent adaptability for different liquid levels and is very effective in controlling the seismic response of extra-large LNG tanks. 相似文献