2018
DOI: 10.1177/0954409718758502
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Dynamic analysis of the interactions between a low-to-medium-speed maglev train and a bridge: Field test results of two typical bridges

Abstract: The rated suspension gap of a low-to-medium-speed maglev train with electromagnetic suspension is normally 8-10 mm. However, while either passing over a bridge or being stationary on one, the maglev train deforms the bridge and therefore alters the suspension gap. Hence, a problem arises due to coupled vibrations between the maglev train and its supporting bridge. In the study reported here, field experiments were conducted on the Chinese Changsha maglev line, which was the first commercial low-to-medium-speed… Show more

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Cited by 41 publications
(22 citation statements)
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“…For the coupling vibration, Zhang and Huang (2019) established a 10-degree-of-freedoms high-speed maglev train-bridge coupled vibration model using model modification methods and verified it based on the field tests. Based on the Changsha low-tomedium-speed (LMS) maglev commercial line, Li et al (2018b) compared the dynamic response characteristics of the system when LMS maglev trains run on the different bridges considering the track structure (shown in Fig. 22).…”
Section: Maglev Vehicle-bridge Dynamicsmentioning
confidence: 99%
“…For the coupling vibration, Zhang and Huang (2019) established a 10-degree-of-freedoms high-speed maglev train-bridge coupled vibration model using model modification methods and verified it based on the field tests. Based on the Changsha low-tomedium-speed (LMS) maglev commercial line, Li et al (2018b) compared the dynamic response characteristics of the system when LMS maglev trains run on the different bridges considering the track structure (shown in Fig. 22).…”
Section: Maglev Vehicle-bridge Dynamicsmentioning
confidence: 99%
“…This section discusses the effect on the deflection ratio limit of the bridge span length including 15, 20, 25, 30, 35 and 40 m, respectively. In order to clearly discuss only the influence mechanism of the vertical rigidity of the bridge on the acceleration induced by the maglev train, the mass per metre of the bridge needs to remain the same (Han et al, 2009; Li et al, 2018b). Hence, maintaining the cross-sectional shape of the bridge and the girder height (the mass per metre of the bridge remain the same) and adjusting the elastic modulus, the deflection ratios of the bridges are all L /3000.…”
Section: Effect Of the Bridge Span Lengthmentioning
confidence: 99%
“…The FFT results of the side span's acceleration signal showed two frequency peaks (at about 1.95 Hz and 3.6 Hz) and four frequency peaks (at about 2.051, 4.053, 6.055, and 10.11 Hz) corresponding to the free and forced vibration parts, respectively, as shown in Figure 6d. The dominant frequency of the free vibration part is the natural frequency for bridges [24]. Therefore, the first and second fundamental vertical frequencies of the continuous, three-span, rigid-frame bridge corresponding to approximately 2 and 4 Hz, respectively, were obtained by performing spectrum analysis of the measured acceleration data.…”
Section: Dynamic Characteristics Of the Continuous Rigid Frame Bridgementioning
confidence: 99%
“…6d. The dominant frequency of the free vibration part is the natural frequency for bridges [24]. Therefore, the first and second fundamental vertical frequencies of the continuous, three-span, rigid-frame bridge corresponding to approximately 2 and 4 Hz, respectively, were obtained by performing spectrum analysis of the measured acceleration data.…”
Section: Dynamic Characteristics Of the Continuous Rigid Frame Bridgementioning
confidence: 99%