Experimental and numerical study on vibration and structure-borne noise of high-speed railway composite bridge

In order to investigate the characteristics of train-induced vibration and structure-borne noise of highspeed railway steel-concrete composite bridge, a 5 x 50 m continuous steel-concrete composite bridge is adopted and tested in this paper. The vibration acceleration response and radiated noise of the bridge are measured during the test. The prediction model of vibration and structure-borne noise is further established to explore the radiation spectrum characteristics of the composite bridge. Firstly, the train track-bridge dynamic interaction theory is applied to calculate the vibration response of the bridge under high-speed train loading. The boundary element method (BEM) and Statistical Energy Analysis (SEA) are subsequently combined to predict the full-frequency band noise of the structure. The accuracy of the model is verified through comparison with the measured data. Based on the field test and numerical study, it is found that the dominant frequency range of vibration and structure-borne noise is 20 similar to 1000 Hz. The root mean square (RMS) accelerations of vertical and transverse vibration are lower than 0.5 m/s(2), while local vibration of the steel web can reach 1.0 similar to 2.5 m/s(2). As a result, the acoustical contribution of the web at far-field site can reach 80% of the structure-borne noise. In addition, the setting of the bottom concrete reduces the acceleration level of the bottom plate by 10.75 dB and the radiated noise by 7.16 dB, showing a good effect of vibration and noise reduction. (C)& nbsp;2022 Elsevier Ltd. All rights reserved.

Automated summary

This paper investigates the characteristics of train-induced vibration and structure-borne noise of a high-speed railway steel-concrete composite bridge through testing a 5 x 50 m continuous bridge. Vibration acceleration response and radiated noise are measured, and a prediction model is established to explore the radiation spectrum characteristics. The dominant frequency range of vibration and structure-borne noise is found to be 20 to 1000 Hz. The acoustical contribution of the web at far-field site can reach 80% of the structure-borne noise. The setting of bottom concrete is effective in reducing vibration and noise.