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Bridge frequency identification using multi-contact responses computed from multi-DOF moving vehicle by nodal distribution method and enhanced integration algorithm

•New theoretical framework for computing multi-wheelset responses for a moving vehicle with multi degrees of freedom.•The nodal distribution method is capable of computing single-DOF wheelset response from multi wheelset responses.•The enhanced integration algorithm can efficiently compute the wheel...

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Bibliographic Details
Published in:Computers & structures 2024-08, Vol.299, p.107397, Article 107397
Main Authors: Yang, Y.B., Mo, X.Q., Shi, K., Gao, S.Y., Tian, S.K.
Format: Article
Language:English
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Summary:•New theoretical framework for computing multi-wheelset responses for a moving vehicle with multi degrees of freedom.•The nodal distribution method is capable of computing single-DOF wheelset response from multi wheelset responses.•The enhanced integration algorithm can efficiently compute the wheelset contact response.•The contact response enables bridge frequencies to be extracted without the interference from vehicle’s frequencies.•The present method excels in accuracy, efficiency and robustness. This paper presents for the first time a top-down procedure for calculating the multi contact responses from the response of a multi DOF vehicle (containing two bogies and four wheelsets), which can be measured or simulated. Two key steps are involved. First, the nodal distribution method was devised for distributing the vehicle’s responses to those of the four wheelsets. Then by treating the wheelset as a single-DOF system, the contact response is calculated exactly by the enhanced integration algorithm for each time step. Two scenarios are studied. In Scenario 1, the vehicle is kept stationary on the rails, but excited differently via the contact points, by which the transmission of vibration from the wheelsets up to the vehicle components and down again by the present method is validated. In Scenario 2, the vehicle is set to move over a simple bridge, by which the contact responses are shown to outperform the vehicle’s responses in extracting the bridge frequencies, due to the fact that the vehicle’s frequencies were totally eliminated. In addition, the present method has been demonstrated to be of excellent accuracy, efficiency and robustness in each application.
ISSN:0045-7949
DOI:10.1016/j.compstruc.2024.107397