Response of an Infinite Beam on a Locally Inhomogeneous and Non-linear Winkler Foundation Excited by a Constant Moving Load

Delft University of Technology

Response of an Infinite Beam on a Locally Inhomogeneous and Non-linear Winkler Foundation Excited by a Constant Moving Load

Faragau, Andrei; van Dalen, Karel

Publication date 2018

Document Version

Accepted author manuscript

Citation (APA)

Faragau, A., & van Dalen, K. (2018). Response of an Infinite Beam on a Locally Inhomogeneous and Non-linear Winkler Foundation Excited by a Constant Moving Load. -. Abstract from 13th World Conference on Computational Mechanics 2018 , New York, United States.

Important note

To cite this publication, please use the final published version (if applicable). Please check the document version above.

Copyright

Other than for strictly personal use, it is not permitted to download, forward or distribute the text or part of it, without the consent of the author(s) and/or copyright holder(s), unless the work is under an open content license such as Creative Commons. Takedown policy

Please contact us and provide details if you believe this document breaches copyrights. We will remove access to the work immediately and investigate your claim.

This work is downloaded from Delft University of Technology.

Response of an infinite beam on a locally inhomogeneous and non-linear

Winkler foundation excited by a constant moving load

Andrei B. Faragau¹, Karel N. van Dalen1

1 _{Faculty of Civil Engineering and Geosciences, Delft University of Technology,}

Stevinweg 1, 2628 CN Delft, The Netherlands

Key Words: Moving-load dynamics; Transition radiation; Infinite, inhomogeneous and

non-linear system; Mixed time-frequency method; Non-reflective boundaries

Transition radiation is emitted when a source moves along a straight line with constant velocity and acts on or near an inhomogeneous medium [1,2]. Transition radiation occurs, for example, when a train crosses an inhomogeneity in the railway track, such as a transition in foundation stiffness. As the velocity of the trains becomes closer to the wave velocity in the subsoil, wave radiation is amplified and may cause plastic deformation in the transition zone.

Studies of transition radiation in finite one-dimensional systems with non-linear foundation behaviour are available in the literature. However, studies that properly account for the infinite extent of the system are not. To this end, the system composed of an infinite beam resting on a locally inhomogeneous and non-linear Winkler foundation, and subjected to a constant moving load is analysed in this paper.

The Winkler foundation is assumed to be piecewise linear, and the system thus behaves linearly between non-linear events. Therefore, the solution can be obtained using a mixed time-frequency method [3]. The use of the Finite Difference Method for the spatial discretization combined with derived non-reflective boundary conditions enables us to simulate the behaviour of an infinite system; the computational domain covers the area with the transition in foundation stiffness. To study the features of the generated wave field in pure form, the load velocity is taken sub-critical, excluding other radiation effects.

Results show that the plastic deformation in the transition zone is a consequence of constructive interference of the excited free waves and the so-called eigenfield that moves with the load. Increasing the load velocity, decreasing the transition length (i.e., smoothness) and/or increasing the foundation stiffness dissimilarity leads to amplified free wave excitation, and consequently to stronger constructive interference and larger plastic deformation. The model and solution method presented in this paper can be used for preliminary design of transition zones in railway tracks. Given the stiffness jump that has to be bridged and the maximum train velocity, the optimum length of the transition zone can be obtained such that minimum damage results in the railway track.

REFERENCES

[1] A.I. Vesnitskii and A.V. Metrikin, Transition radiation in mechanics. Physics-Uspekhi

39, pp. 983-1007, 1996.

[2] K.N. van Dalen, A. Tsouvalas, A.V. Metrikine, and J.S. Hoving. Transition radiation

excited by a surface load that moves over the interface of two elastic layers. International Journal of Solids and Structures 73-74, pp. 99–112, 2015.

[3] J.S. Hoving and A.V. Metrikine. A mixed time-frequency domain method to describe the

dynamic behaviour of a discrete medium bounded by a linear continuum. APM Proceedings, St. Petersburg, Russia, 2015.