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风与行人荷载耦合作用下大跨双连结构的动力响应及振动适用性分析

Dynamic response and vibration suitability analysis of the large-span double-connected structure under coupled wind and pedestrian loads.

作者信息

Yang Shuwang, Wang Gang, Xu Qiang, He Junfu, Yang Minghao, Zhang Zhiyuan

机构信息

College of Architecture and Engineering, Liaocheng University, Liaocheng, 252000, China.

China Railway 17th BureauGroup 1st Engineering Co., Ltd, Qingdao, 266000, China.

出版信息

Sci Rep. 2024 Oct 3;14(1):23023. doi: 10.1038/s41598-024-73223-z.

DOI:10.1038/s41598-024-73223-z
PMID:39362966
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11450158/
Abstract

Modern buildings increasingly utilize lightweight, high-strength materials and feature high-rise, large-span structural designs. These structures often exhibit low natural frequencies and are susceptible to resonance from low-frequency dynamic loads such as wind and pedestrian loads. This paper focuses on a large-span double-connected structure and analyzes its dynamic response under the combined effects of wind and pedestrian loads. First, a finite element model of the structure was created using ANSYS, and model validity verification and modal analysis were performed. Second, a Fourier-based pedestrian model was used to simulate pedestrian loads and generate time-range data. The pulsating wind speed was generated from the Davenport spectrum using the harmonic superposition method. Wind load time-range data were calculated for different heights using Bernoulli's theorem. Finally, the solution yields information about the dynamic response of the structure. The study revealed maximum vertical comfort ratings in the connecting corridor were achieved when crowd density did not exceed 0.3 persons/m. The connecting corridor's most unfavorable horizontal comfort level was evaluated as a medium, except for the 0-degree wind angle condition. This paper provides experience in studying the dynamic response and vibration suitability assessment of the large-span double-connected structure under wind and pedestrian loads.

摘要

现代建筑越来越多地采用轻质、高强度材料,并具有高层、大跨度的结构设计。这些结构的固有频率往往较低,容易受到风荷载和行人荷载等低频动态荷载的共振影响。本文聚焦于一个大跨度双连结构,分析其在风荷载和行人荷载共同作用下的动力响应。首先,使用ANSYS创建了该结构的有限元模型,并进行了模型有效性验证和模态分析。其次,采用基于傅里叶的行人模型来模拟行人荷载并生成时域数据。利用谐波叠加法从 Davenport 谱生成脉动风速。使用伯努利定理计算不同高度处的风荷载时域数据。最后,求解得出该结构动力响应的相关信息。研究表明,当人群密度不超过0.3人/平方米时,连接走廊的垂直舒适度评级最高。除风向角为0度的情况外,连接走廊最不利的水平舒适度等级被评估为中等。本文为研究大跨度双连结构在风荷载和行人荷载作用下的动力响应及振动适用性评估提供了经验。

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本文引用的文献

1
Design and characteristics analysis of a new vibration reduction system for in service long span transmission tower.一种新型在役大跨输电塔减振系统的设计与特性分析
Sci Rep. 2022 Jul 5;12(1):11373. doi: 10.1038/s41598-022-15659-9.