Accurate computation of dispersion characteristics of guided waves in rails is important during the development of inspection and monitoring systems. Wavenumber versus frequency curves computed by the semi-analytical finite element method exhibit mode repulsion and mode crossing which can be difficult to distinguish. Eigenvalue derivatives, with respect to the wavenumber, are used to investigate these regions. A term causing repulsion between two modes is identified and a condition for two modes to cross is established. In symmetric rail profiles the mode shapes are either symmetric or antisymmetric. Symmetric and antisymmetric modes can cross each other while the modes within the symmetric and antisymmetric families do not appear to cross. The modes can therefore be numbered in the same way that Lamb waves in plates are numbered, making it easier to communicate results. The derivative of the eigenvectors with respect to wavenumber contains the same repulsion term and shows how the mode shapes swop during a repulsion. The introduction of even a small asymmetry appears to lead to repulsion forces that prevent any mode crossings. Measurements on a continuously welded rail track were performed to illustrate a mode repulsion.
Reference:
Loveday, P.W., Long, C.S. and Ramatlo, D.A.M. 2018. Mode repulsion of ultrasonic guided waves in rails. Ultrasonics, vol. 84: 341-349
Loveday, P. W., Long, C. S., & Ramatlo, D. A. (2018). Mode repulsion of ultrasonic guided waves in rails. http://hdl.handle.net/10204/9925
Loveday, Philip W, Craig S Long, and Dineo AM Ramatlo "Mode repulsion of ultrasonic guided waves in rails." (2018) http://hdl.handle.net/10204/9925
Loveday PW, Long CS, Ramatlo DA. Mode repulsion of ultrasonic guided waves in rails. 2018; http://hdl.handle.net/10204/9925.
Copyright: 2017 Elsevier. Due to copyright restrictions, the attached PDF file only contains the abstract of the full text item. For access to the full text item, please consult the publisher's website.
