Risk assessment of the spanish national railway system

The principal risks in the railway industry are mainly associated with collisions, derailments and level crossing accidents. An understanding of the nature of previous accidents on the railway network is required to identify potential causes and develop safety systems and deploy safety procedures. Risk assessment is a process for determining the risk magnitude to assist with decision-making. We propose a three-step methodology to predict the mean number of fatalities in railway accidents. The first is to predict the mean number of accidents by analyzing generalized linear models and selecting the one that best fits to the available historical data on the basis of goodness-offit statistics. The second is to compute the mean number of fatalities per accident and the third is to estimate the mean number of fatalities. The methodology is illustrated on the Spanish railway system. Statistical models accounting for annual and grouped data for the 1992-2009 time period have been analyzed. After identifying the models for broad and narrow gauges, we predicted mean number of accidents and the number of fatalities for the 2010-18 time period.

Lateral Dynamic Models for High-Speed Railway Bridges and Vehicles

The analysis of the running safety of railway vehicles on viaducts subject to strong lateral actions such as cross winds requires coupled nonlinear vehicle-bridge interaction models, capable to study extreme events. In this paper original models developed by the authors are described, based on finite elements for the structure, multibody and finite element models for the vehicle, and specially developed interaction elements for the interface between wheel and rail. The models have been implemented within ABAQUS and have full nonlinear capabilities for the structure, the vehicle and the contact interface. An application is developed for the Ulla Viaduct, a 105 m tall arch in the Spanish high-speed railway network. The dynamic analyses allow obtaining critical wind curves, which define the running safety conditions for a given train in terms of speed of circulation and wind speed

Líneas ferroviarias en terrenos evaporíticos : medidas a adoptar en fase de proyecto, obra y explotación frente a los procesos de disolución

El fin último de una infraestructura es prestar un servicio, manteniendo unas condiciones mínimas de servicio. En el caso de una obra lineal ferroviaria será permitir el paso de trenes por ella de manera ininterrumpida según la programación establecida por la empresa explotadora, y manteniendo principalmente los estándares de seguridad y confort. No considerar durante el diseño y la construcción todos los factores que van a influir durante el mantenimiento de la infraestructura conllevará actuaciones adicionales en fase de mantenimiento, que en muchos casos no serán las más idóneas por la incompatibilidad de su ejecución con la explotación, y siempre serán mucho más costosas desde el punto de vista económico. Un factor a considerar será la posibilidad de disolución de los terrenos evaporíticos si la infraestructura transcurre sobre ellos. En España, durante los últimos 25 años se han llevado a cabo la modernización de la red ferroviaria española, dirigida hacia su especialización en aquellos ámbitos territoriales y tipo de servicio en los que reporta una mayor utilidad económico-social de tal manera que se ha potenciado la Alta Velocidad y las Cercanías. En esta tesis se estudian un compendio de tramos representativos de línea de Alta Velocidad construidos sobre terrenos evaporíticos, determinando los problemas surgidos y medidas adoptadas en el proyecto, en la construcción y en la fase de explotación, concluyendo con la eficacia de las mismas. Además, se analiza el fenómeno de las disoluciones en los terrenos evaporíticos desde el punto de vista teórico, con el fin de definir todos y cada uno de los factores que tienen un efecto. Partiendo de este análisis se sugiere un procedimiento en el que se contemplan los estudios y acciones a realizar a lo largo de las diferentes fases del desarrollo de una línea ferroviaria. The ultimate goal of an infrastructure is to provide service, maintaining minimum service conditions. Regarding rail corridor engineering work, the uninterrupted passage of trains will be allowed according to the established schedule of the operating company and mainly by maintaining safety standards and comfort. Not taking into account all the factors that are going to have an influence on the maintenance of the infrastructure during the design and the construction stage, will lead to additional actions during its maintenance, which in many cases will not be ideal due to incompatibilities with its implementation and exploitation, and they will always be more costly from an economic point of view. One factor to consider is the dissolution of the evaporite terrain if the infrastructure runs above it. In Spain, during the last 25 years, the upgrading of the Spanish railway network has taken place; directed towards the specialization of those territorial areas and type of service that yield better economical and social benefits, in such a way that the high-speed networks and the commuter train have been enhanced. This thesis studies a compendium of representative sections of high-speed railways built on evaporite terrains, determining the issues encountered and measures taken on the project, construction and operation phase, concluding with their effectiveness. Moreover, the phenomenon of the dissolutions in the evaporite terrains is analyzed from a theoretical point of view, in order to define all the factors that exert an effect. On the basis of this analysis, a protocol is suggested which contemplates studies and activities to be implemented throughout the different phases in the development of a railway line.

Train scheduling and rolling stock assignment in high speed trains

The Train Timetabling Problem (TTP) has been widely studied for freight and passenger rail systems. A lesser effort has been devoted to the study of high-speed rail systems. A modeling issue that has to be addressed is to model departure time choice of passengers on railway services. Passengers who use these systems attempt to travel at predetermined hours due to their daily life necessities (e.g., commuter trips). We incorporate all these features into TTP focusing on high-speed railway systems. We propose a Rail Scheduling and Rolling Stock (RSch-RS) model for timetable planning of high-speed railway systems. This model is composed of two essential elements: i) an infrastructure model for representing the railway network: it includes capacity constraints of the rail network and the Rolling-Stock constraints; and ii) a demand model that defines how the passengers choose the departure time. The resulting model is a mixed-integer programming model which objective function attempts to maximize the profit for the rail operator