斜交梁桥频率间接识别效果的影响参数

doi:10.11835/j.issn.2096-6717.2020.056

首页 > 过刊浏览>2020年第42卷第6期 >119-126. DOI:10.11835/j.issn.2096-6717.2020.056

斜交梁桥频率间接识别效果的影响参数
DOI:
                        10.11835/j.issn.2096-6717.2020.056
                    
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作者:
                        亓兴军亓兴军
山东建筑大学 交通工程学院, 济南 250101;山东建筑大学 山东省高校土木结构防灾减灾协同创新中心, 济南 250101
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肖志全肖志全
山东建筑大学 交通工程学院, 济南 250101
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张荣凤张荣凤
山东建筑大学 交通工程学院, 济南 250101
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中图分类号:U441
基金项目:山东省高等学校土木结构防灾减灾协同创新中心项目（XTM201904）；山东省交通科技计划（2009Y10）

Influence parameters of frequency indirect identification effect for oblique beam bridge

Author:

Qi Xingjun
Qi Xingjun
Institute of Traffic Engineering, Shandong Jianzhu University, Jinan 250101, P. R. China;Shandong Co-Innovation Center for Disaster Prevention and Mitigation of Civil Structures, Shandong Jianzhu University, Jinan 250101, P. R. China
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Xiao Zhiquan
Xiao Zhiquan
Institute of Traffic Engineering, Shandong Jianzhu University, Jinan 250101, P. R. China
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Zhang Rongfeng
Zhang Rongfeng
Institute of Traffic Engineering, Shandong Jianzhu University, Jinan 250101, P. R. China
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摘要:

采用过桥车辆振动响应识别桥梁自振特性的间接测量法能够避免传统动载试验测量桥频方法存在的操作复杂和成本高等缺点。根据车桥耦合振动理论和桥梁间接测量法基本原理，对实际工程中的某一斜交梁桥建立车辆与桥梁耦合振动的有限元模型，采用双轴半车模型模拟测量车辆，提取车辆匀速驶过桥梁时的车辆加速度时程响应，并利用峰值拾取法进行频谱分析，剔除已知的车辆相关频率识别出桥梁的前三阶自振频率，分析了6种不同车速、6种不同车重、8种不同桥梁斜交角度对桥梁频率识别效果的影响特点。结果表明，间接测量法能够有效地识别桥梁比较密集的频率，车速低于20 km/h时，能够较好地识别出斜交梁桥的前3阶频率，车速较高时无法识别桥梁的频率信息；相对较小的车桥质量比对桥梁频率识别有利；斜交梁桥不同的斜交角度基本不影响桥梁频率识别的精度；桥面粗糙时采用差值法仍能较好地识别。数值模拟表明，间接测量法对于不规则斜交梁桥频率仍有较好的识别效果。

关键词:车桥耦合;斜交梁桥;间接测量法;粗糙桥面;自振频率

Abstract:

An indirect measurement method is adopted to identify the bridge's natural vibration characteristics by vibration response of vehicles crossing the bridge,it can avoid the disadvantages of the traditional method of measuring bridge frequency in dynamic load test, such as complicated operation and high cost. Based on the theory of vehicle-bridge coupling vibration and the basic principle of bridge indirect measurement method, the finite element model of vehicle-bridge coupling vibration is established for a skew beam bridge in practical engineering. A biaxial half-car model is used to measure the vehicle and extract the time-history response of the vehicle acceleration when the vehicle passes the bridge at a constant speed. Excluding known vehicle-related frequencies.The first three natural frequencies of the bridge are identified.The influence of six different vehicle speeds, six different vehicle weights and eight different bridge skew angles on the bridge frequency identification is analyzed. The results show that the indirect measurement method can effectively identify the frequency of bridges with high density. When the speed is less than 20 km/h, the third-order frequency of skew beam bridge can be well recognized. When the speed is high, the frequency information of the bridge cannot be recognized.The relatively small ratio of vehicle and bridge mass to bridge frequency identification is advantageous. The accuracy of frequency identification is not affected by the different angle of oblique beam bridge.When the bridge deck is rough, the method of acceleration subtraction can still be used for frequency identification. Numerical simulation shows that the indirect measurement method still has a good recognition effect for the irregular skew beam bridge frequency. To promote the application of motion sensing indirect measurement method in bridge inspection engineering.

Key words:vehicle-bridge coupling;skew girder bridge;indirect method of measurement;rough bridge surface;natural vibration frequency

参考文献

[1] R.克拉夫, J. 彭津. 结构动力学[M]. 北京:高等教育出版社, 2006. CLOUGH R, PENZIEN J. Dynamics of structures[M]. Beijing:Higher Education Press, 2006. (in Chinese)

[2] 夏禾, 张楠. 车辆与结构动力相互作用[M]. 北京:科学出版社, 2005. XIA H, ZHANG N. Dynamic interaction of vehicles and structures[M]. Beijing:Science Press, 2005. (in Chinese)

[3] 李焕兰. 简支梁桥损伤状态下车桥耦合动态响应分析[D]. 辽宁大连:大连海事大学, 2015. LI H L.Dynamic response analysis of vehicle-bridge coupling under damaged state of simply supported girder bridge[D]. Dalian, Liaoning:Dalian Maritime University, 2015.(in Chinese)

[4] BIGGS J. Introduction to structural dynamics[M]. New York:Mc Graw-Hill Book Co, Inc, 1964.

[5] FRBA L. Vibration of solids and structures under moving loads[M]. Dordrecht:Springer Netherlands, 1972.

[6] YANG Y B, LIN C W, YAU J D. Extracting bridge frequencies from the dynamic response of a passing vehicle[J]. Journal of Sound and Vibration, 2004, 272(3/4/5):471-493.

[7] 杨永斌.非传统思维的桥梁监测法[J].桥梁, 2015,66(4):34-36. YANG Y B. Bridge non-traditional monitoring method[J]. Bridge, 2015, 66(4):34-36. (in Chinese)

[8] YANG Y B, YAU J D. Vehicle-bridge interaction element for dynamic analysis[J]. Journal of Structural Engineering, 1997, 123(11):1512-1518.

[9] LIN C W, YANG Y B. Use of a passing vehicle to scan the fundamental bridge frequencies:An experimental verification[J]. Engineering Structures, 2005, 27(13):1865-1878.

[10] 陈上有, 夏禾. 从过桥车辆响应中识别桥梁结构基本自振频率的方法[J]. 工程力学, 2009, 26(8):88-94. CHEN S Y, XIA H. An identification method for fundamental frequency of bridge from dynamic responses due to passing vehicle[J]. Engineering Mechanics, 2009, 26(8):88-94. (in Chinese)

[11] 王希. 由车辆响应识别桥梁固有频率的方法研究[D]. 长沙:中南大学, 2009. WANG X.Identification of natural frequencies of bridges by vehicle response[D]. Changsha:Central South University, 2009. (in Chinese)

[12] MALEKJAFARIAN A, OBRIEN E J. Identification of bridge mode shapes using short time frequency domain decomposition of the responses measured in a passing vehicle[J]. Engineering Structures, 2014, 81:386-397.

[13] KONG X, CAI C S, DENG L, et al. Using dynamic responses of moving vehicles to extract bridge modal properties of a field bridge[J]. Journal of Bridge Engineering, 2017, 22(6):04017018.

[14] YANG Y B, YANG J P. State-of-the-art review on modal identification and damage detection of bridges by moving test vehicles[J]. International Journal of Structural Stability and Dynamics, 2018, 18(2):1850025.

[15] 杨晓天. 桥面不平整下连续梁桥频率的间接识别[D]. 济南:山东建筑大学, 2019. YANG X T. Frequency identification of continuous bridge based on indirect method considering the unevendeck[D]. Jinan:Shandong Jianzhu University, 2019.(in Chinese)

[16] 刘世忠. 双层公路钢桁梁桥车桥耦合振动研究[D]. 西安:长安大学, 2015. LIU S Z.Study on vehicle-bridge coupling vibration of double-deck highway steel truss bridge[D]. Xi'an:Chang'an University, 2015. (in Chinese)

[17] 谢天宇. 桥梁动态讯息间接测量法的多种工况分析研究[D]. 重庆:重庆大学, 2017. XIE T Y. A study on the working conditions analysis for the bridge indirect measurement method[D]. Chongqing:Chongqing University, 2017.(in Chinese)

[18] YANG Y B, LIN C W. Vehicle-bridge interaction dynamics and potential applications[J]. Journal of Sound and Vibration, 2005, 284(1/2):205-226.

[19] CHANG K C, WU F B, YANG Y B. Effect of road surface roughness on indirect approach for measuring bridge frequencies from a passing vehicle[J]. Interaction and Multiscale Mechanics, 2010, 3(4):299-308.

[20] ELHATTAB A. Drive-by bridge damage monitoring:concise review[J]. Civil Engineering Research Journal, 2017, 1(1):25-29. DOI:10.19080/cerj.2017.01.555555.

引用本文

亓兴军,肖志全,张荣凤.斜交梁桥频率间接识别效果的影响参数[J].土木与环境工程学报（中英文）,2020,42(6):119-126. Qi Xingjun, Xiao Zhiquan, Zhang Rongfeng. Influence parameters of frequency indirect identification effect for oblique beam bridge[J]. JOURNAL OF CIVIL AND ENVIRONMENTAL ENGINEERING,2020,42(6):119-126.10.11835/j. issn.2096-6717.2020.056

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收稿日期:2019-12-09
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在线发布日期: 2020-11-26
出版日期: 2020-12-31

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