Comparative study on dynamic responses of ballasted and ballastless tracks at critical velocity

IF 4.9 2区工程技术 Q1 ENGINEERING, CIVIL

Transportation Geotechnics Pub Date : 2024-09-01 DOI:10.1016/j.trgeo.2024.101354

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引用次数: 0

Abstract

High-speed railways are becoming ubiquitous worldwide, demanding increased operational speeds. Yet, as trains near critical speeds, dynamic stress and embankment displacement escalate, jeopardizing safety. While significant strides have been made in studying these critical speeds, capturing the dynamic characteristics of all track responses remains elusive. This study presents a coupled train-track-ground model employing a 2.5D finite element approach integrated with a nonlinear soil model to investigate the influence of embankment and foundation properties on the critical speeds for both ballasted and ballastless tracks. The research resulted in the development of unified Dynamic Amplification Factor curves that consistently represent the dynamic behavior of various tracks as observed in multiple studies. Additionally, the applicability of simplified theoretical models for calculating critical speeds, such as the elastic half-space foundation and track-foundation models, was assessed. The findings suggest that the simplified models are suitable only under specific conditions. This research provides valuable perspectives on optimizing train speeds and ensuring the safety of diverse track types.

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有砟轨道和无砟轨道临界速度动态响应比较研究

高速铁路在全球日益普及，运营速度不断提高。然而，当列车接近临界速度时，动态应力和路堤位移会不断增加，从而危及安全。虽然在研究这些临界速度方面取得了长足进步，但捕捉所有轨道响应的动态特性仍然遥遥无期。本研究采用 2.5D 有限元方法与非线性土壤模型相结合，建立了列车-轨道-地面耦合模型，以研究有砟轨道和无砟轨道的路堤和地基特性对临界速度的影响。这项研究开发出了统一的动态放大系数曲线，该曲线能够一致地代表多项研究中观察到的各种轨道的动态行为。此外，还评估了计算临界速度的简化理论模型的适用性，如弹性半空间地基和轨道地基模型。研究结果表明，简化模型仅适用于特定条件。这项研究为优化列车速度和确保不同类型轨道的安全提供了宝贵的视角。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Transportation Geotechnics Social Sciences-Transportation

CiteScore

8.10

自引率

11.30%

发文量

194

审稿时长

51 days

期刊介绍： Transportation Geotechnics is a journal dedicated to publishing high-quality, theoretical, and applied papers that cover all facets of geotechnics for transportation infrastructure such as roads, highways, railways, underground railways, airfields, and waterways. The journal places a special emphasis on case studies that present original work relevant to the sustainable construction of transportation infrastructure. The scope of topics it addresses includes the geotechnical properties of geomaterials for sustainable and rational design and construction, the behavior of compacted and stabilized geomaterials, the use of geosynthetics and reinforcement in constructed layers and interlayers, ground improvement and slope stability for transportation infrastructures, compaction technology and management, maintenance technology, the impact of climate, embankments for highways and high-speed trains, transition zones, dredging, underwater geotechnics for infrastructure purposes, and the modeling of multi-layered structures and supporting ground under dynamic and repeated loads.