Comprehensive efficient vertical and lateral track dynamic model to study the evolution of rail corrugation in sharp curves

This paper addresses a time/space domain model, extremely efficient in terms of computation, which combines the vertical and lateral dynamics of the track to predict undulatory wear depending on track and vehicle parameters. As it is known, this is a source of noise and vibration that can provoke very high levels. The model is obtained from the transformation of a model in the frequency domain to the time/space domain by means of the rational fraction polynomials method. Multiobjective genetic algorithms are used to minimize the error in fitting receptances and to ensure the stability of the system. This model includes the vertical wheel-rail dynamic interaction with a Hertzian spring, and the FASTSIM algorithm is used to study tangential contact. The model is validated with the experimental corrugation measurements taken on a metro line.

Automated summary

This paper presents a time/space domain model for predicting undulatory wear caused by track and vehicle parameters. The model, obtained through a transformation method, uses multiobjective genetic algorithms for fitting and system stability. The model considers vertical wheel-rail dynamics and uses the FASTSIM algorithm for tangential contact. Experimental corrugation measurements on a metro line confirm the validity of the model.