Track-Bridge Interaction of CWR on Chinese Large-Span Bridge of High-Speed Railway

The track-bridge interaction is a fundamental concern in the field of railway engineering, which plays an important role in the optimization design of railway bridges, especially for heavy-haul railway and high-speed railway bridges. This paper systematically introduces the research status of the CWR track-bridge interaction for large-span bridges of high-speed railway in China. The evolution process of the track-bridge interaction model from the simplest elastic bar and linear longitudinal resistance model to the complex beam-rail interaction model considering the loading history is described. In this paper, the modeling methods of the track-bridge interaction model for five types of long-span railway bridges, namely simply supported beam bridge, continuous beam bridge, cable-stayed bridge, arch bridge, and suspension bridge, are systematically introduced, and the characteristics of longitudinal force distribution under the track-bridge interaction are analyzed. This paper discusses the practical application of the theory of the track-bridge interaction on extra-large-span bridges from the aspects of system dynamic performance evaluation and system safety evaluation. The practical application of track-bridge interaction theory under special conditions such as earthquake load, complex temperature load, shrinkage and creep load, and superposition of multiple loads is emphasized. It provides guidance for the further improvement of the track-bridge interaction model and the design of large-span high-speed railway bridges in the future.

Automated summary

This paper systematically introduces the research status and modeling methods of the track-bridge interaction for large-span bridges of high-speed railway in China, and analyzes the characteristics of longitudinal force distribution. The practical application of the track-bridge interaction theory on extra-large-span bridges and under special conditions is discussed. It provides guidance for the improvement of the track-bridge interaction model and the design of large-span high-speed railway bridges in the future.