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无伸缩缝桥梁的动力特性计算与试验研究 总被引:2,自引:0,他引:2
福建省永春县上坂大桥是目前我国修建桥长最大,采用整体式桥台的无伸缩缝桥梁。本文通过该桥的动力试验研究了该桥在天然脉动荷载作用下的自振特性,采用结构分析软件ANSYS建立全桥的空间模型,计算该桥的自振特性,与实测结果进行了分析比较。实桥试验还测试了无障碍行车试验和跳车试验这2种车辆激振作用下桥梁的强迫振动特性,并把实测的荷载冲击系数与新桥规的计算结果进行比较。研究结果有助于对该类桥梁动力特性的认识,有利于进一步开展无伸缩缝桥梁的抗震性能研究。 相似文献
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根据平顶山市城东河路湛河桥主桥—斜靠式拱桥的结构特点,采用M IDAS/C ivil有限元软件,建立了该桥的空间有限元计算模型,进行了不同吊杆损伤情况下的桥梁动力特性计算,通过对比桥梁在完好状态和不同吊杆损伤情况下的桥梁动力特性,得出结论:吊杆损伤对斜靠式拱桥的低阶自振频率总体影响较小,但对桥梁整体竖向自振频率和扭转自振频率相对影响较大,吊杆损伤导致桥梁竖向和扭转自振频率降低;主拱吊杆损伤比稳定拱吊杆损伤对该桥的自振频率影响大,跨中吊杆损伤比1/4跨处吊杆损伤对该桥自振频率影响大。计算结果对正确认识斜靠式拱桥在不同状态下的结构动力特征,合理评价桥梁运营阶段的健康状况提供了参考和基础性数据。 相似文献
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空间组合桥梁体系的动力特性分析 总被引:4,自引:2,他引:4
以一拟建的某空间组合桥梁体系为研究对象,采用ANSYS程序,建立该组合桥梁体系的空间结构分析模型,利用子空间迭代法计算结构的自振周期和振型,由结构的动力特性分析可以把握整座桥的受力特点,从而为复杂空间组合桥梁的模型建立和类似桥梁结构设计提供依据。 相似文献
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5跨连续中承式钢管混凝土拱桥抗震性能分析 总被引:12,自引:0,他引:12
钢管混凝土拱桥由于桥型优美在城市桥梁中得到广泛应用,对某正在设计的5跨连续巾承式钢管混凝土拱桥进行了动力特性和抗震性能分析,根据该桥的结构特点,建立了’该桥的空间有限元分析模型,计算桥梁的自振特性,基于反应谱方法计算了该桥在横向、纵向水平地震反应,计算结果表明:该桥拱肋的面外刚度相对较小,在桥梁振动中首先出现拱肋的面外振动;桥梁的竖向振动表现为拱肋与桥面的整体竖向振动,其基频明显比拱肋面外振动大;主拱肋的轴力由横桥向地震动控制,其他内力由纵桥向地震动控制;地震作用对弯矩的影响较大,故主拱的内力计算应考虑地震力的影响;在设计计算中除常规关键点应作为控制点外,内外拱连接处也应作为控制点。计算结果已为该桥的抗震设计提供了参考。 相似文献
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伸缩缝刚度对大跨度悬索桥动力特性的影响 总被引:1,自引:1,他引:0
伸缩缝作为大跨度桥梁与引桥之间的重要连接构件,其抗推刚度及可能存在的变异性对主桥及引桥动力特性的影响不可忽略。本文建立了大跨度悬索桥及引桥的有限元模型,采用弹簧单元模拟加劲梁与引桥箱梁之间的伸缩缝,分析伸缩缝刚度对悬索桥及引桥自振特性及其地震响应的影响规律。分析结果表明:伸缩缝刚度对加劲梁的横弯振型、竖弯与纵飘耦合振型的频率有明显的影响;伸缩缝刚度的变化会导致加劲梁与引桥的振型相互耦合,同时这些振型的频率发生相应的突变,当伸缩缝刚度较大时,加劲梁两个竖弯与纵飘的耦合振型解耦成为独立的竖弯和纵飘振型;当引桥与悬索桥加劲梁的纵飘振型发生耦合时,在纵向和竖向地震作用下的悬索桥及引桥的地震响应达到最小。伸缩缝刚度对悬索桥动力特性影响的分析可为悬索桥的模态参数确认、损伤识别、抗震性能分析提供有价值的借鉴。 相似文献
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因大跨径悬索桥梁具有较大的跨越尺度,同时墩柱基础所处场地条件也存在差异,所以对其进行地震响应分析时需考虑局部场地效应。为了正确分析场地效应对大跨度桥梁的地震响应,以某悬索桥为研究背景,采用MIDAS/CIVIL有限元软件,建立该悬索桥的有限元模型,在考虑地震动的局部场地效应情况下列举9种不同的计算工况,对大跨度悬索桥进行时程分析,通过控制一个塔墩处场地类别,改变另一个塔墩处的场地类别来分析场地效应对桥梁跨中位移和弯矩的影响。研究结果显示:场地效应对悬索桥的跨中位移和弯矩存在一定影响,不同的场地条件对桥梁同一位置的破坏程度不同。 相似文献
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The dynamic responses of the Tsing Ma suspension bridge and the running behaviors of trains on the bridge under turbulent
wind actions are analyzed by a three-dimensional wind-train-bridge interaction model. This model consists of a spatial finite
element bridge model, a train model composed of eight 4-axle identical coaches of 27 degrees-of-freedom, and a turbulent wind
model. The fluctuating wind forces, including the buffeting forces and the self-excited forces, act on the bridge only, since
the train runs inside the bridge deck. The dynamic responses of the bridge are calculated and some results are compared with
data measured from Typhoon York. The runnability of the train passing through the Tsing Ma suspension bridge at different
speeds is researched under turbulent winds with different wind velocities. Then, the threshold curve of wind velocity for
ensuring the running safety of the train in the bridge deck is proposed, from which the allowable train speed at different
wind velocities can be determined. The numerical results show that rail traffic on the Tsing Ma suspension bridge should be
closed as the mean wind velocity reaches 30 m/s. 相似文献
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钢筋混凝土加劲桁架悬索桥的模态分析 总被引:8,自引:0,他引:8
采用ANSYS软件对钢筋混凝土土加劲架悬索桥进行有限元分析,提出较为准确的建模方法和最优初始应变的取值条件,使计算结果能满足工程分析精度要求。在此基础上进行了模态分析,计算了钢筋混凝土加劲杵架悬索桥的动力特征及主要结构参数对动力学特性的影响,并对福建三明下洋悬索桥进行实桥测试与分析比较,研究结果有助于对该类悬索桥力学性能的认识。 相似文献
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The classical continuum model for the linear vertical vibrations of a suspension bridge (Bleich et al., 1950 [1]) is re-examined. The primary objective of the study is to extend the definitive analytical and numerical results of Irvine and Caughey (1974) [2], Irvine and Griffin (1976) [3] and Irvine (1980, 1981) [4], [5] for the natural frequencies, mode shapes, and modal participation factors for an extensible suspension cable, which depend on one dimensionless parameter related to the elasticity of the cable, to the case of a stiffened suspension bridge in which the response depends also on a second dimensionless parameter related to the stiffness of the girder. The continuum suspension bridge model is also used to understand the pattern of variation of mode shapes as a function of cable elasticity and girder stiffness, which has been shown by West et al. (1984) [6] to be considerably more complex than that for a suspension cable. Finally, the threshold amplitudes of free vibrations that would result in the incipient slackening of the hangers are determined. 相似文献
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The geological condition may vary largely from one support to another for a long span bridge. The effect of geological variability and spatial variation produced by propagation and coherence loss of seismic ground motion on the response of long span suspension bridges is investigated in this article. The case of Jiangyin Yangtse River Bridge, a suspension bridge with a main span of 1385 m, is studied in detail. Numerical results show that the geological difference at the supports has a significant effect on the seismic response of long span suspension bridges and, that it is unacceptable to neglect the difference. The effect of the propagation of seismic ground motion on the response of long span suspension bridges is far more important than that of the coherence loss. The response of bridges varies greatly with the horizontal apparent velocity in a very complex way, and there is a critical horizontal velocity for a given response quantity. 相似文献
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Non-linear buffeting response analysis of long-span suspension bridges with central buckle 总被引:1,自引:1,他引:0
The rigid central buckle employed in the Runyang Suspension Bridge (RSB) was the first time it was used in a suspension bridge in China. By using a spectral representation method and FFT technique combined with measured data,a 3D fluctuating wind field considering the tower wind effect is simulated. A novel FE model for buffeting analysis is then presented,in which a specific user-defined Matrix27 element in ANSYS is employed to simulate the aeroelastic forces and its stiffness or damping matrices are parameterized by wind velocity and vibration frequency. A nonlinear time history analysis is carried out to study the influence of the rigid central buckle on the wind-induced buffeting response of a long-span suspension bridge. The results can be used as a reference for wind resistance design of long-span suspension bridges with a rigid central buckle in the future. 相似文献
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大跨度悬索桥几何非线性主要来自3个方面:缆索垂度效应、梁柱效应、大位移引起的几何形状变化。鉴于地震波高频成分振幅大,低频成分振幅小的特点,很难对地震作用下大跨度悬索桥几何非线性的影响做出定性判断。目前大跨度桥梁的几何非线性研究主要集中在斜拉桥,且不同的学者得出了不同的结论。本文以逐级加大振幅的Ⅳ类场地多条地震波为激励,通过对称与非对称的2座典型大跨度悬索桥的几何非线性影响对比分析,探讨了几何非线性对大跨度悬索桥重要地震响应量的影响程度及其原因,并提出了相应的抗震设计参考建议。 相似文献
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对带有双向TMD系统的大跨度悬索桥进行了空间非线性时程响应分析,探讨了TMD参数对抑振效果的影响,分析结果显示,TMD能够增大结构的表观阻尼,有较大的能量耗散作用,加速振荡的衰减,有效地抑振结构的振动,这表明,用TMD技术对大跨度悬索桥的环境振动实施被动控制是一个有效的方法。 相似文献