Seismic Response of a Large-Span Steel Truss Arch Bridge under Nonuniform Near-Fault Ground Motions

IF 3.1 3区 工程技术 Q2 CONSTRUCTION & BUILDING TECHNOLOGY Buildings Pub Date : 2024-07-25 DOI:10.3390/buildings14082308
Zhen Liu, Xingliang Ma, Junlin Lv
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Abstract

The ground motion in the near-fault region of an earthquake is characterized by exceptional energy levels, powerful velocity impulses, substantial spatial variability, and notable permanent displacement. These unique attributes can dramatically escalate structural damage. Steel truss arch bridges, being critical components of transportation networks, are particularly vulnerable to these phenomena due to their extensive stiffness spans. Such factors are difficult to accurately simulate. In this study, real near-fault ground motions that incorporate spatial variability effects and pulse effects are used to excite the long-span arch bridge, thereby striving to realistically reproduce the structural damage sustained by the bridge under the simultaneous influence of near-fault spatial variability and pulse effects. This study adopts an arch bridge with a span closely approximating the spacing between stations (200 m) of the SMART seismic array as a case study. The near-fault ground motions, characterized by spatial variability and captured by the array, are selected as seismic samples, while the far-field ground motions recorded by the same array serve as a comparative reference. The seismic excitations are then input into the bridge case study, following the spatial correspondence of the stations, using a large-scale finite element program to obtain the structural response. Upon analyzing the seismic response of crucial positions on the bridge, it became evident that the arch foot of the bridge is more susceptible to the spatial variability in near-fault ground motion, whereas the vault experiences a greater impact from the high-energy velocity pulse. Specifically, under nonuniform seismic conditions, the internal force at the base of the bridge arch increased significantly, averaging a rise of 18.69% compared to uniform excitation conditions. Conversely, the displacement and internal force response at the top of the arch exhibited more modest increases of 6.48% and 10.33%, respectively. Under nonuniform excitation, the vault’s response to near-fault earthquakes increased by an average of 20.35% com-pared to far-field earthquakes, while the arch foot’s response rose by 11.55%. In contrast, under uniform excitation, the vault’s response to near-fault earthquakes was notably higher, increasing by 25.04%, while the arch foot’s response showed a minor increase of only 2.28%. The study has revealed significant differences in the sensitivity of different parts of long-span arch bridges to near-fault earthquake characteristics. This finding is of great importance for understanding the behavior of long-span arch bridges under complex earthquake conditions. Specifically, the arch foot of the bridge is more sensitive to the spatial variability of near-fault ground motions, while the arch crown is more significantly affected by high-energy velocity pulses, providing new insights for bridge seismic design. Furthermore, the differences in response between the arch crown and arch foot under different earthquake excitations also reveal the complexity and diversity of bridge structural responses.
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大跨度钢桁架拱桥在非均匀近断层地震动下的地震响应
地震近断层区地面运动的特点是能量超常、速度脉冲强、空间变化大、永久位移显著。这些独特的属性会极大地加剧结构损坏。钢桁架拱桥是交通网络的重要组成部分,由于其跨度大、刚度大,特别容易受到这些现象的影响。这些因素很难准确模拟。本研究采用包含空间变异效应和脉冲效应的真实近断层地震动来激励大跨度拱桥,从而力求真实再现拱桥在近断层空间变异效应和脉冲效应同时影响下所遭受的结构破坏。本研究以跨度接近 SMART 地震阵列台站间距(200 米)的拱桥为案例。选择具有空间变异性并由阵列捕捉到的近断层地面运动作为地震样本,而由同一阵列记录的远场地面运动作为对比参考。然后,按照各台站的空间对应关系,将地震激励输入桥梁案例研究,使用大型有限元程序获得结构响应。在分析桥梁上关键位置的地震响应后发现,桥梁的拱脚更容易受到近断层地面运动空间变化的影响,而拱顶则受到高能速度脉冲的更大影响。具体而言,在非均匀地震条件下,桥拱底部的内力显著增加,与均匀激励条件相比平均增加了 18.69%。相反,拱顶的位移和内力响应则表现出较为温和的增长,分别为 6.48% 和 10.33%。在非均匀激励条件下,拱顶对近断层地震的响应与远场地震相比平均增加了 20.35%,而拱脚的响应增加了 11.55%。相比之下,在均匀激励下,拱顶对近断层地震的响应明显更高,增加了 25.04%,而拱脚的响应仅略微增加了 2.28%。这项研究揭示了大跨度拱桥不同部位对近断层地震特征敏感性的显著差异。这一发现对于理解大跨度拱桥在复杂地震条件下的行为具有重要意义。具体来说,拱桥的拱脚对近断层地震动的空间变化更为敏感,而拱顶受高能速度脉冲的影响更为显著,这为桥梁抗震设计提供了新的启示。此外,拱冠和拱脚在不同地震激励下的响应差异也揭示了桥梁结构响应的复杂性和多样性。
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来源期刊
Buildings
Buildings Multiple-
CiteScore
3.40
自引率
26.30%
发文量
1883
审稿时长
11 weeks
期刊介绍: BUILDINGS content is primarily staff-written and submitted information is evaluated by the editors for its value to the audience. Such information may be used in articles with appropriate attribution to the source. The editorial staff considers information on the following topics: -Issues directed at building owners and facility managers in North America -Issues relevant to existing buildings, including retrofits, maintenance and modernization -Solution-based content, such as tips and tricks -New construction but only with an eye to issues involving maintenance and operation We generally do not review the following topics because these are not relevant to our readers: -Information on the residential market with the exception of multifamily buildings -International news unrelated to the North American market -Real estate market updates or construction updates
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