Design of an optimised wheel profile for rail vehicles operating on two track gauges

This paper sets out an optimum synthesis methodology for wheel profiles of railway vehicles in order to secure good dynamic behaviour with different track configurations. Specifically, the optimisation process has been applied to the case of rail wheelsets mounted on double gauge bogies, that move over two different gauges, which also have different types of rail: the Iberian gauge (1668 mm) and the UIC gauge (1435 mm). Optimisation is performed using Genetic Algorithms and traditional optimisation methods in a complementary way. The objective function used is based on an ideal equivalent conicity curve which ensures good stability on straight sections and also proper negotiation of curves. To this end the curve is constructed in such a way that it is constant with a low value for small lateral wheelset displacements (with regard to stability), and increases as the displacements increase (to facilitate negotiation of curved sections). Using this kind of ideal conicity curve also enables a wheel profile to be secured where the contact points have a larger distribution over the active contact areas, making wear more homogeneous and reducing stresses. The result is a wheel profile with a conicity that is closer to the target conicity for both gauges studied, producing better curve negotiation while maintaining good stability on straight sections of track. The paper shows the resultant wheel profile, the contact curves it produces, and a number of dynamic analyses demonstrating better dynamic behaviour of the synthesised wheel on curved sections with respect to the original wheel.

Diseño de un mecanismo de amplificación para una garra de 1 grado de libertad.

[ES]El presente Trabajo de Fin de Grado tiene la finalidad de contribuir al desarrollo de una línea de investigación mediante la implementación de un mecanismo que amplifique el movimiento de un grado de libertad. Dicho proyecto consiste en optimizar un mecanismo ya existente formado por un músculo neumático de un grado de libertad de forma que se mejore el rango de utilización de dicho mecanismo ampliando la carrera final de éste. Para ello se llevará a cabo un análisis de distintos mecanismos multiplicadores, el diseño de la mejor opción entre todos ellos y la final fabricación de un prototipo funcional. También se llevará a cabo el diseño y fabricación de las piezas auxiliares que, si bien, no forman parte explícita del mecanismo multiplicador, son necesarias para la posterior implantación de dicho mecanismo en el mecanismo ya existente, formado por un mecanismo mecatrónico de cinemática plana 5R dotado de un músculo neumático y una ventosa.