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基于双轴车辆无量纲响应的桥梁频率子空间识别

Subspace Identification of Bridge Frequencies Based on the Dimensionless Response of a Two-Axle Vehicle.

作者信息

Quan Yixin, Zeng Qing, Jin Nan, Zhu Yipeng, Liu Chengyin

机构信息

School of Civil and Environmental Engineering, Harbin Institute of Technology (Shenzhen), Shenzhen 518055, China.

Guangdong Provincial Key Laboratory of Intelligent and Resilient Structures for Civil Engineering, Shenzhen 518055, China.

出版信息

Sensors (Basel). 2024 Mar 18;24(6):1946. doi: 10.3390/s24061946.

DOI:10.3390/s24061946
PMID:38544209
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10974147/
Abstract

As an essential reference to bridge dynamic characteristics, the identification of bridge frequencies has far-reaching consequences for the health monitoring and damage evaluation of bridges. This study proposes a uniform scheme to identify bridge frequencies with two different subspace-based methodologies, i.e., an improved Short-Time Stochastic Subspace Identification (ST-SSI) method and an improved Multivariable Output Error State Space (MOESP) method, by simply adjusting the signal inputs. One of the key features of the proposed scheme is the dimensionless description of the vehicle-bridge interaction system and the employment of the dimensionless response of a two-axle vehicle as the state input, which enhances the robustness of the vehicle properties and speed. Additionally, it establishes the equation of the vehicle biaxial response difference considering the time shift between the front and the rear wheels, theoretically eliminating the road roughness information in the state equation and output signal effectively. The numerical examples discuss the effects of vehicle speeds, road roughness conditions, and ongoing traffic on the bridge identification. According to the dimensionless speed parameter of the vehicle, the ST-SSI ( < 0.1) or MOESP ( ≥ 0.1) algorithm is applied to extract the frequencies of a simply supported bridge from the dimensionless response of a two-axle vehicle on a single passage. In addition, the proposed methodology is applied to two types of long-span complex bridges. The results show that the proposed approaches exhibit good performance in identifying multi-order frequencies of the bridges, even considering high vehicle speeds, high levels of road surface roughness, and random traffic flows.

摘要

作为桥梁动态特性的重要参考,桥梁频率识别对桥梁健康监测和损伤评估具有深远影响。本研究提出了一种统一方案,通过简单调整信号输入,利用两种基于子空间的不同方法,即改进的短时随机子空间识别(ST-SSI)方法和改进的多变量输出误差状态空间(MOESP)方法来识别桥梁频率。该方案的一个关键特性是对车桥相互作用系统进行无量纲描述,并将双轴车辆的无量纲响应用作状态输入,这增强了车辆特性和速度的鲁棒性。此外,它考虑前后轮之间的时间偏移建立了车辆双轴响应差异方程,从理论上有效消除了状态方程和输出信号中的路面不平度信息。数值算例讨论了车速、路面不平度条件和交通流量对桥梁识别的影响。根据车辆的无量纲速度参数,应用ST-SSI(<0.1)或MOESP(≥0.1)算法从双轴车辆单次通过的无量纲响应中提取简支梁桥的频率。此外,将所提出的方法应用于两种大跨度复杂桥梁。结果表明,即使考虑高车速、高路面不平度和随机交通流,所提出的方法在识别桥梁多阶频率方面仍表现出良好的性能。

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本文引用的文献

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Smartphone Application for Structural Health Monitoring of Bridges.桥梁结构健康监测的智能手机应用程序。
Sensors (Basel). 2022 Nov 4;22(21):8483. doi: 10.3390/s22218483.
2
Embedded Sensors for Structural Health Monitoring: Methodologies and Applications Review.嵌入式传感器在结构健康监测中的应用:方法与应用综述。
Sensors (Basel). 2022 Oct 30;22(21):8320. doi: 10.3390/s22218320.
3
Scanning of Bridge Surface Roughness from Two-Axle Vehicle Response by EKF-UI and Contact Residual: Theoretical Study.基于扩展卡尔曼滤波-联合迭代法和接触残余量的双轴车辆响应扫描桥面粗糙度:理论研究
Sensors (Basel). 2022 Apr 29;22(9):3410. doi: 10.3390/s22093410.