Robustness analysis of bogie suspension components Pareto optimised values
Journal article, 2017

Bogie suspension system of high speed trains can significantly affect vehicle performance. Multiobjective optimisation problems are often formulated and solved to find the Pareto optimised values of the suspension components and improve cost efficiency in railway opera- tions from different perspectives. Uncertainties in the design param- eters of suspension system can negatively influence the dynamics behaviour of railway vehicles. In this regard, robustness analysis of a bogie dynamics response with respect to uncertainties in the suspension design parameters is considered. A one-car railway vehicle model with 50 degrees of freedom and wear/comfort Pareto opti- mised values of bogie suspension components is chosen for the analysis. Longitudinal and lateral primary stiffnesses, longitudinal and vertical secondary stiffnesses, as well as yaw damping are considered as five design parameters. The effects of parameter uncertainties on wear, ride comfort, track shift force, stability, and risk of derailment are studied by varying the design parameters around their respective Pareto optimised values according to a lognormal distribution with different coefficient of variations (COVs). The robustness analysis is carried out based on the maximum entropy concept. The multiplicative dimensional reduction method is utilised to simplify the calculation of fractional moments and improve the computational efficiency. The results showed that the dynamics response of the vehicle with wear/comfort Pareto optimised values of bogie suspension is robust against uncertainties in the design parameters and the probability of failure is small for parameter uncertainties with COV up to 0.1.

bogie

M-DRM

optimisation

probability density function

suspension

Robustness analysis

Author

Milad Mousavi Bideleh Seyed

Dynamics

Vehicle System Dynamics

0042-3114 (ISSN) 1744-5159 (eISSN)

Vol. 55 8 1189-1205

Subject Categories

Mechanical Engineering

Applied Mechanics

Vehicle Engineering

Driving Forces

Sustainable development

Areas of Advance

Transport

DOI

10.1080/00423114.2017.1305115

More information

Created

10/8/2017