Abstract
Vertical bending vibration modes and rail wave propagation, including the damping characteristics, are the factors that cause rail corrugation. However, the ability to identify actual railways has been limited because of the huge number of sensors required for field tests. In this study, a novel and field-applicable method for identifying rail vibration modes and wave propagation characteristics is developed by multipoint hammering and the reciprocity theorem instead of multipoint measuring. Additionally, the proposed method is applied to an actual rail with a direct fastening track system on a bridge that has corrugation with a wavelength of approximately 0.04 m. As a result, the wavelength (wavenumber)-, group velocity-, and distance damping (attenuation) frequency relationship of the wave propagation is clarified in addition to the rail frequencies and mode shapes up to approximately 1500 Hz, including the pinned-pinned mode. Finally, the identified wavelength-frequency relationships and the measured rail irregularity can empirically demonstrate that the generated corrugation on the rail is produced by wave interference on the two axles in the bogie.
Highlights
Vibration and wave propagation, including the damping of the rails that support the traveling axles, affect the wheel–rail interaction force
In this paper, a method related to rail corrugation has been developed for identifying the vertical bending vibration modes and wave propagation characteristics of rails by field tests
A method related to rail corrugation has been developed for identifying the vertical bending vibration modes and wave propagation characteristics of rails by field tests
Summary
Vibration and wave propagation, including the damping of the rails that support the traveling axles, affect the wheel–rail interaction force. As a result, these can cause real problems on railways, such as rolling noise and rail corrugation [1,2,3,4,5,6,7,8]. Manabe [4] established that rail vertical bending modes and vertical bending wave propagation are related to the growth mechanism of rail corrugation, with a medium wavelength of approximately 0.04 m. This study focuses on the rail’s vibration mode, and wave propagation characteristics in the frequency range of approximately 500–1200 Hz, which is indicated to be caused by this type of wave interference [4], are targeted
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