Abstract
Fault detection and isolation of high-speed train suspension systems is of critical importance to guarantee train running safety. Firstly, the existing methods concerning fault detection or isolation of train suspension systems are briefly reviewed and divided into two categories, i.e., model-based and data-driven approaches. The advantages and disadvantages of these two categories of approaches are briefly summarized. Secondly, a 1D convolution network-based fault diagnostic method for high-speed train suspension systems is designed. To improve the robustness of the method, a Gaussian white noise strategy (GWN-strategy) for immunity to track irregularities and an edge sample training strategy (EST-strategy) for immunity to wheel wear are proposed. The whole network is called GWN-EST-1DCNN method. Thirdly, to show the performance of this method, a multibody dynamics simulation model of a high-speed train is built to generate the lateral acceleration of a bogie frame corresponding to different track irregularities, wheel profiles, and secondary suspension faults. The simulated signals are then inputted into the diagnostic network, and the results show the correctness and superiority of the GWN-EST-1DCNN method. Finally, the 1DCNN method is further validated using tracking data of a CRH3 train running on a high-speed railway line.
Highlights
As railway transportation is developing at a considerable speed in many regions worldwide, condition monitoring of high-speed trains is receiving increasing attention, in which, failures of suspension systems will increase the vibration of vehicle components and reduce the running stability, and may even lead to severe accidents, such as derailment [1, 2]
As described in Sect. 1.1.2, track irregularities and wheel wear will affect the vibration signals used for condition monitoring of railway vehicles
In the second phase, an EST-strategy is proposed to improve the robustness of the diagnostic network against wheel wear
Summary
As railway transportation is developing at a considerable speed in many regions worldwide, condition monitoring of high-speed trains is receiving increasing attention, in which, failures of suspension systems will increase the vibration of vehicle components and reduce the running stability, and may even lead to severe accidents, such as derailment [1, 2]. It is of critical importance to diagnose the faults of railway vehicle suspension systems
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call