Comparison between Response Spectrum and Time History Method of Dynamic Analysis of Concrete Gravity Dam

Dam structure built to store water has failed with resulting loss of life, social, economic and environmental losses due to seismic vibrations. These vibrations are dynamic in nature. These vibrations must be reduced with proper application of engineering principles and for estimating the behavior of concrete gravity dam dynamic analysis plays an extraordinary role. This paper presents the dynamic time history analysis and response spectrum method of a concrete gravity dam by using STAAD-PRO. Here Finite Element Approach is used to analyze the dam. A concrete gravity dam model is prepared in STAAD-PRO to perform the time history analysis and response spectrum analysis and a comparison is done between both these methods. Concrete gravity dam is a large structure which retains a very large amount of water on its upstream side and it is very crucial for a dam to survive against vibrations of earthquake. So it is a matter of study to check the behaviour of a dam during and after the application of the loading.

Generation and Application of A Standardized Load-Time History to Tubular T-joints in Offshore Platforms

Marine structures are mostly made of metals and always experience complex random loading during their service periods. The fatigue crack growth behaviors of metal materials have been proved from laboratory tests to be sensitive to the loading sequence encountered. In order to take account of the loading sequence effect, fatigue life prediction should be based on fatigue crack propagation（FCP） theory rather than the currently used cumulative fatigue damage（CFD） theory. A unified fatigue life prediction（UFLP） method for marine structures has been proposed by the authors＇ group. In order to apply the UFLP method for newly designed structures, authorities such as the classification societies should provide a standardized load-time history（SLH） such as the TWIST and FALSTAFF sequences for transport and fighter aircraft. This paper mainly aims at proposing a procedure to generate the SLHs for marine structures based on a short-term loading sample and to provide an illustration on how to use the presented SLH to a typical tubular T-joint in an offshore platform based on the UFLP method.

Application of strength reduction method to dynamic anti-sliding stability analysis of high gravity dam with complex dam foundation

Considering that there are some limitations in analyzing the anti-sliding seismic stability of dam-foundation systems with the traditional pseudo-static method and response spectrum method, the dynamic strength reduction method was used to study the deep anti-sliding stability of a high gravity dam with a complex dam foundation in response to strong earthquake-induced ground action. Based on static anti-sliding stability analysis of the dam foundation undertaken by decreasing the shear strength parameters of the rock mass in equal proportion, the seismic time history analysis was carried out. The proposed instability criterion for the dynamic strength reduction method was that the peak values of dynamic displacements and plastic strain energy change suddenly with the increase of the strength reduction factor. The elasto-plastic behavior of the dam foundation was idealized using the Drucker-Prager yield criterion based on the associated flow rule assumption. The result of elasto-plastic time history analysis of an overflow dam monolith based on the dynamic strength reduction method was compared with that of the dynamic linear elastic analysis, and the reliability of elasto-plastic time history analysis was confirmed. The results also show that the safety factors of the dam-foundation system in the static and dynamic cases are 3.25 and 3.0, respectively, and that the F2 fault has a significant influence on the anti-sliding stability of the high gravity dam. It is also concluded that the proposed instability criterion for the dynamic strength reduction method is feasible.

A probability-consistent method based on practical ground surface motion

In this paper, a new method for seismic hazard analysis, the probability-consistent method based on practical ground surface motion is proposed. Time histories on ground surface in the method correspond to earthquakes occurring at potential sources around sites. So of the envelope parameter, response spectrum, peak ground acceleration are of physical sense. Neglecting the response of site soil layers, the method is the same as routine probability-consistent method. The natural seismic acceleration time histories can be used for input wave directly. Generating ground motion is an approximation under lack of data of strong motion. Along with accumulating of the strong motion data around sites, we can describe the seismic environment more objectively.

Seismic displacement demand prediction in non-linear domain: Optimization of the N2 method

In Europe, computation of displacement demand for seismic assessment of existing buildings is essentially based on a simplified formulation of the N2 method as prescribed by Eurocode 8(EC8). However, a lack of accuracy of the N2 method in certain conditions has been pointed out by several studies. This paper addresses the assessment of effectiveness of the N2 method in seismic displacement demand determination in non-linear domain. The objective of this work is to investigate the accuracy of the N2 method through comparison with displacement demands computed using non-linear timehistory analysis(NLTHA). Results show that the original N2 method may lead to overestimation or underestimation of displacement demand predictions. This may affect results of mechanical model-based assessment of seismic vulnerability at an urban scale. Hence, the second part of this paper addresses an improvement of the N2 method formula by empirical evaluation of NLTHA results based on EC8 ground-classes. This task is formulated as a mathematical programming problem in which coefficients are obtained by minimizing the overall discrepancy between NLTHA and modified formula results. Various settings of the mathematical programming problem have been solved using a global optimization metaheuristic. An extensive comparison between the original N2 method formulation and optimized formulae highlights benefits of the strategy.

独塔非对称钢-混混合梁斜拉桥抗震性能研究

【目的】研究独塔非对称钢-混混合梁斜拉桥的抗震性能,并探明非对称结构地震响应的差异。【方法】以长沙香炉洲大桥西汊航道桥为依托,采用MidasCivil软件建立非对称钢-混混合梁斜拉桥全桥有限元模型,分别采用反应谱法和非线性时程分析法对其进行地震响应分析,并重点研究了结构非对称性对斜拉桥辅助墩、过渡墩及其桩基抗震性能的影响。【结果】独塔非对称钢-混混合梁斜拉桥的动力特性和地震响应规律呈现出明显的非对称性,非对称布置的两过渡墩和两辅助墩在地震作用下的内力响应存在较大差异,结构的非对称性对横向地震更加敏感,在抗震设计时应予以重视;除两过渡墩桩基外,长沙香炉洲大桥按照静力计算设计的结构尺寸及配筋形式均能满足各工况地震作用下的抗震性能目标;塔身、墩身在横向+竖向地震作用下的安全储备均大于纵向+竖向地震的,桩基在横向+竖向地震作用下的安全储备几乎都小于纵向+竖向地震的;受结构非对称性的影响,边跨的27#过渡墩桩基总是先于主跨的31#过渡墩桩基发生破坏;在横向地震作用下,受群桩承台影响横向各排桩基地震轴力有较大差异。【结论】从经济性和抗震合理性角度出发,应对独塔非对称钢-混混合梁斜拉桥进行差异化的抗震设计,研究成果可为非对称斜拉桥及其他非对称桥梁结构的抗震设计提供有益参考。

基于位移-速度输入法结构多点激励FPS支座隔震效果研究

受行波效应、相干效应、场地效应的影响,大跨度结构的多点激励地震反应分析非常复杂,且考虑多点激励下对大跨空间网格结构隔震性能的影响是结构工程抗震方向中有重大意义的研究课题。以单层圆柱面大跨度空间网架结构为研究对象,基于直接位移法,应用SAP2000有限元软件建立了多点激励动力反应时程分析模型,进行结构在地震动一致激励和多点激励作用下的动力反应分析计算。结果表明:水平地震动多点激励效应对大跨度空间结构的影响十分显著,需采取使用多点激励输入方式。不设置隔震支座时,多点激励下,支撑柱弯矩与剪力随波速的减小而明显增加,柱顶位移变小,中柱轴力略微上升。基础隔震时,各支撑柱柱顶内力与位移的分配较无隔震时存在差异。边柱的弯矩、剪力及轴力均小于中柱的相应值,但柱顶位移增加明显。柱弯矩减震效率保持在45%~75%,柱剪力减震效率保持在60%~85%;柱顶隔震时,能得到比基础隔震更高的隔震效率,且柱弯矩隔震效率高达90%左右,柱剪力隔震效率保持在85%~90%。柱顶位移显著减小,柱轴力比基础隔震时略有增加。

大跨高墩小半径刚构-连续组合梁桥地震响应分析

为研究大跨高墩小半径刚构-连续组合曲线梁桥的地震响应,以某(40+6×80+40)m的刚构-连续组合梁铁路特大桥为背景进行分析。采用ANSYS建立全桥有限元模型,计算桥梁动力特性,并采用反应谱法和时程分析法对桥梁在地震作用下的内力和位移进行分析。分析结果表明:增大桥墩刚度、采用墩梁固结方式能够提高刚构-连续组合曲线梁桥的整体性,有利于桥梁的抗震;从地震响应(位移、弯矩)综合考虑,对该类桥梁最不利的地震波激励角度为0°、90°(分别对应顺桥向、横桥向),增大横向刚度可减小桥梁结构的横向位移,增大墩底截面面积可减小桥梁结构在水平地震作用下的地震响应;总体上来说,在横桥向地震波激励下该类桥梁横向位移和面外弯矩最大,在顺桥向地震波激励下该类桥梁纵向位移和面内弯矩最大。

考虑土体非线性特性的直埋管道-土体系统的动力反应分析

本文采用二维有限元方法对连续直埋管道在动力荷载作用下的反应进行分析。管道周围土体采用等效线性粘弹性模型 ;为反映管 -土间的相对滑移 ,在管单元与土单元间加入无厚度Goodman接触单元 ;并利用 Wilson- θ法对管 -土系统进行动力时程反应分析。本文研究了输入波频率 ,输入波幅值 ,管道埋深 ,土体类别和管 -土间摩擦系数等因素对埋管动力反应的影响。

基于Blackman-turkey法生成轨道不平顺时程研究

目的为研究城轨交通三维空间振动传播规律,探讨了激励源-轮轨接触面不平顺时程的获取方法.方法采用周期图法,根据功率谱估计轨道谱的傅里叶谱的幅值,再辅以随机相位角,通过傅里叶逆变换(IFFT)得到轨道不平顺时程样本.结果推导了轨道不平顺谱从空间域向频率域的转化关系,研究了依谱密度函数生成时程样本的方法,给出了三种方法生成的美国六级轨道谱对应的时程样本,比较了三种方法的计算效率和精度.结论 Blackman-Turkey法生成的时程无论从精度还是从计算速度方面都优于三角级数法和白噪声滤波法生成的时程样本,生成的不平顺时程可以用于车辆-轨道-路基系统的非线性振动分析.

蒙特卡罗法在起重机金属结构应力-时间历程仿真中的应用

介绍了蒙特卡罗法在起重机结构应力-时间历程仿真中的具体应用,根据起重机操作的实际情况编写了仿真剧本,并通过MATLAB实现了仿真剧本的自动生成,为起重机结构应力-时间历程的仿真分析创造了条件。

流-固耦合问题的精细积分求解法

为了解决流-固耦合动力学求解效率和精度低等问题,提出了增维精细积分法.根据有限元理论推导流-固耦合方程,将流-固耦合方程改写成状态空间形式,在矩阵仅增加1维的情况下将积分运算转化为代数运算,扩大了精细积分法的应用范围,从而得到增维矩阵的流-固耦合精细积分求解.同时,将增维精细积分法与Newmark法的计算结果进行对比,以验证其有效性.结果表明,由于不用求解矩阵H的逆矩阵,增维精细积分法避免了矩阵奇异带来的计算解的不稳定性.增维精细积分法与Newmark法的计算结果较吻合,且其在较大计算时间步长条件下的计算精度较高.

混凝土框架-摇摆墙体系抗震性能研究

框架-摇摆墙为新型受控摇摆体系,可通过墙体有限转动控制结构的侧向变形模式,并使其结构损伤依照预期既定的模式发生与发展,防止局部屈服破坏机制的发生。本文以一个按现行规范设计的10层混凝土框架为例,在其纵向布置4面摇摆墙体,并对其与框架及相同尺寸的框架-剪力墙体系进行静力弹塑性及动力时程分析,以此考察此体系的抗震性能。分析结果表明:框架-摇摆墙较其他两体系可承受较高的地震作用,其主体框架剪力分配与框架体系基本一致,墙体剪力按楼层均匀分配且较小,设计时应予以考虑;在框架体系附加摇摆墙后,其一阶周期变化较小,且由于摇摆墙体的有限转动,主体框架侧向变形受到有效控制,层间变形基本一致,损伤更均匀;框架-摇摆墙体系损伤主要由框架梁承担,耗能分配较为均匀,可改善框架及框架-剪力墙体系局部能量集中现象,易于实现"强柱弱梁"及整体破坏机制,抗震性能更优良。

巨型框-筒结构的地震反应分析

采用空间有限元计算模型和时程分析方法,分析巨型框-筒结构的地震反应,比较巨型框-筒结构与普通框-筒结构的抗震性能.结果表明:两者的受力性能相似,巨型框-筒结构的前2阶自振周期比普通框-筒结构稍大,而其后13阶自振周期均比普通框-筒结构小;两者的振型图相似,第3、6阶振型以扭转为主;迁安地震波、EL Centro地震波和天津宁河地震波作用下,2种结构在控制结构体系的顶点位移、顶层速度、最大楼层加速度相差均不超过7%,而底层剪力、弯矩相差略大,且巨型框-筒的底层最大弯矩均小于普通框-筒;罕遇地震作用下,结构的顶层位移、速度、加速度反应谱相似.说明巨型框-筒结构具有良好的抗震性能,可以用于高层建筑的抗震设计.

桩-土-承台相互作用对城市曲线匝道桥抗震性能的影响

针对城市曲线匝道桥的结构特点,以某一实际工程为背景,采用m法分析了承台侧向土刚度的不同取值对低桩承台基础等效平动及转动刚度的影响。应用线性及非线性时程反应分析方法研究了承台侧向土刚度对结构弹性、弹塑性地震反应以及抗震性能的影响。结果表明:承台侧向土刚度对曲线匝道桥桩基础的切向平动及转动刚度影响较大;随着承台侧向土刚度的增加,桥墩的地震反应逐渐增大,但桩身的地震反应逐渐减小;承台侧向回填土的密实程度对城市曲线匝道桥下部结构塑性铰的产生机制影响较大。

基于能量原理的外钢框架-内剪力墙结构地震响应预测法

利用能量法研究了外钢框架-内剪力墙结构的地震响应.文中设计了一个钢框架结构,将其中跨满布剪力墙,得到外钢框架-内剪力墙结构.对其进行简化,并利用能量法和非线性动力时程分析法对其进行地震响应分析.结果表明,能量法预测的外钢框架-内剪力墙的地震响应与非线性动力时程分析法的计算结果相差不多,可以为实际工程提供参考.

海底盾构隧道-竖井连接部位三维非线性地震反应特性

海底盾构隧道-竖井连接部位在地震作用下易发生损坏。以汕头海湾海底隧道为例,考虑海床土体和混凝土的非线性,利用多点约束与连接单元模拟管环间的螺栓连接,经幅值标定的不同特性的强震记录作为输入基岩地震动,采用动力时程法(纵轴向+横向+竖向震动、纵轴向+竖向震动)与广义反应位移法(纵轴向+横向+竖向震动)对比分析了盾构隧道-竖井连接部位的三维非线性地震反应特性。不同特性的地震动作用下,多点约束与连接单元能有效模拟盾构隧道管环间的变形特性,管环拱顶与外拱肩处的张开量较大;竖井在与竖轴共轭45°方向上的损伤严重、应力集中显著;低频丰富的地震记录激励比高频发育的地震记录激励对该连接部位的影响更大。隧道-竖井接头处的地震变形与应力远大于距离接头较远处隧道管环的地震变形与应力,且横向地震激励的影响不容忽视。两种方法计算的连接部位沿隧道纵向的地震反应特征一致,但广义反应位移法计算的隧道、竖井的地震反应明显大于动力时程法的结果。

基于ANSYS的水闸-地基体系抗震分析

在结构-地基体系动力有限元研究的基础上,针对闸底板结构特殊、受力条件复杂使得其抗震稳定分析难度较大的问题,以某水闸工程为例,考虑地震动水压力作用、闸室结构的空间耦联及闸室结构与地基相互作用的影响,利用通用有限元软件ANSYS对闸室与地基整体结构进行了抗震计算,并对比分析了反应谱法与时程分析法动力计算结果,同时对该水闸的安全稳定性进行了评价。结果表明,闸底板的转折部位承受拉应力较大,配筋及实际施工过程中应予以重点关注。反应谱法与时程分析法的动力分析结果具有一致性,但反应谱法对地基承载力计算的结果比时程分析的结果保守。

地震动差动下高压输电塔-线体系的纵向反应

考虑地震波以有限波速传播时所引起的地震行波效应,基于建立的高压输电塔-线体系空间有限元模型,利用在多点输入下考虑几何非线性的动力时程分析法,研究了体系纵向地震作用下的反应特性,并和一致地震动输入下的反应情况进行比较。结果表明:行波输入既可以增加又可以降低输电塔的地震反应,这与行波波速、地震动性质、输电塔档距以及输电塔-线体系中导(地)线的松紧程度有关;行波输入使导(地)线跨中竖向位移增加十分明显,但使导(地)线跨中纵向位移减小,同时行波输入使导(地)线的轴力增加十分明显。由此得出结论:高压输电塔-线体系地震反应受行波波速影响很大,考虑地震行波效应的影响是十分必要的。

框架-摇摆墙结构阻尼优化设计方法研究

摇摆墙体与主体框架之间存在较大的竖向变形,可于此变形集中部位增设耗能构件,实现保护主体结构的基本损伤机制。提出附加阻尼的框架-摇摆墙结构,并基于等效线性化理论初步计算结构仅附加单一类型阻尼器的阻尼置放量,而后通过定义目标函数,确定可使目标函数最小的同时附加粘滞阻尼与金属阻尼的阻尼器布置方式,得到结论如下:1于弯剪型结构,当仅考虑结构加速度控制时,可沿结构总高布置粘滞阻尼器,而需综合考虑结构楼层位移、加速度时及层间位移角时,可于结构2/3处下部安装金属阻尼器,与其上部1/3处安装粘滞阻尼器;2于剪切型结构,当仅考虑结构层间位移角时,可于结构楼层1/2处下部安装金属阻尼器,与其上部1/2处安装粘滞阻尼器,而需综合考虑结构楼层位移、加速度及层间位移角时,则可于结构1/3处下部安装金属阻尼器,与其上部2/3处安装粘滞阻尼器。