The maglev vehicle-girder coupled vibration problem has been encountered in many maglev test or commercial lines, which significantly degrade the performance of the maglev train. In previous research on the principle of the coupled vibration problem, it has been discovered that the fundamental model of the maglev girder can be simplified as a series of mass-spring resonators of different but related resonance frequencies, and that the stability of the vehicle-girder coupled system can be investigated by separately examining the stability of each mass-spring resonator – electromagnet coupled system. Based on this conclusion, a maglev test platform, which includes a single electromagnetic suspension control system, is built for experimental study of the coupled vibration problem. The guideway of the test platform is supported by a number of springs so as to change its flexibility. The mass of the guideway can also be changed by adjusting extra weights attached to it. By changing the flexibility and mass of the guideway, the rules of the maglev vehicle-girder coupled vibration problem are to be examined through experiments, and related theory on the vehicle-girder self-excited vibration proposed in previous research is also testified.
[1]
Hui Wang,et al.
Analysis and experimental study on the MAGLEV vehicle-guideway interaction based on the full-state feedback theory
,
2015
.
[2]
Moon-Young Kim,et al.
A parametric study on the dynamics of urban transit maglev vehicle running on flexible guideway bridges
,
2009
.
[3]
Colin H. Hansen,et al.
Review of coupled vibration problems in EMS maglev vehicles
,
2010
.
[4]
Matthew P. Cartmell,et al.
Journal of Sound and Vibration: Editorial
,
2011
.
[5]
Colin H. Hansen,et al.
Suppression of maglev vehicle–girder self-excited vibration using a virtual tuned mass damper
,
2011
.
[6]
Hyung-Suk Han,et al.
Coupled vibration analysis of Maglev vehicle-guideway while standing still or moving at low speeds
,
2015
.