Abstract
Current models for the acoustic radiation from railway wheels assume free field radiation. However, slab tracks are increasingly used for new railway lines. The acoustically hard surface of those tracks makes a re-evaluation of the free field assumption relevant, as such a surface can affect the radiation efficiency of an acoustic radiator. The wheel as the acoustic radiator is most conveniently described in a cylindrical coordinate system, thus making use of its axisymmetry. While this is a viable solution for the structural vibrations, for instance by using the curved Waveguide Finite Element formulation, the axisymmetry breaks when including a reflective plane in the calculation of the acoustic radiation. A convenient method to include an infinitely large, reflective plane is by using half-space Green’s functions in combination with the Boundary Element method. This method can be formulated in cylindrical coordinates using the Fourier series BEM (FBEM). However, the FBEM has not yet been combined with half-space Green’s functions. This paper provides a half-space formulation for the FBEM, which enables e.g. the evaluation of sound radiation of railway wheels over reflective surfaces. Finally, it is shown that the assumption of free field radiation for railway wheels is valid, as there is no major contribution of the reflective plane to the radiation efficiency of the wheel. The developed method is validated against laboratory measurements as well as analytical models.
Highlights
A solid has axial symmetry when it can be created by rotating a planar geometry around an axis
The purpose of this paper is to evaluate the influence of sound radiation from railway wheels over reflective planes
This is of practical interest when researching the influence of the acoustically hard surface of slab tracks on the source strength of wheel radiation
Summary
A solid has axial symmetry when it can be created by rotating a planar geometry around an axis. The axisymmetry of objects is often used to downscale numerical models, as simplifying the geometry to its planar representation considerably decreases the degrees of freedom in the system. The comparatively more elaborate element formulation of axisymmetric elements pays off in decreased calculation times. This downscaling is utilised in the following for calculating both structural vibrations as well as sound radiation. Standard axisymmetric finite elements are well established, see e.g. There is a large body of research using a curved waveguide finite element (WFE) formulation for axisymmetric bodies, especially in the field of predicting tyre vibrations and noise [4,5,6,7]. This WFE method is used for calculating the structural response of railway wheel, which is a novel application of this method
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