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高速铁路桥梁无砟轨道系统的力学性能:热荷载作用下的试验与数值研究

Mechanical Performance of a Ballastless Track System for the Railway Bridges of High-Speed Lines: Experimental and Numerical Study under Thermal Loading.

作者信息

Zhang Yingying, Zhou Lingyu, Mahunon Akim D, Zhang Guangchao, Peng Xiusheng, Zhao Lei, Yuan Yahui

机构信息

Department of Civil Engineering, Central South University, 68 South Shaoshan Road, Changsha 410075, China.

Central-South Architectural Design Institute Co., Ltd, 2 Central South 2nd Road, Wuhan 430071, China.

出版信息

Materials (Basel). 2021 May 27;14(11):2876. doi: 10.3390/ma14112876.

DOI:10.3390/ma14112876
PMID:34072051
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8198357/
Abstract

The mechanical performance of China Railway Track System type II (CRTS II) ballastless track suitable for High-Speed Railway (HSR) bridges is investigated in this project by testing a one-quarter-scaled three-span specimen under thermal loading. Stress analysis was performed both experimentally and numerically, via finite-element modeling in the latter case. The results showed that strains in the track slab, in the cement-emulsified asphalt (CA) mortar and in the track bed, increased nonlinearly with the temperature increase. In the longitudinal direction, the zero-displacement section between the track slab and the track bed was close to the 1/8L section of the beam, while the zero-displacement section between the track slab and the box girder bridge was close to the 3/8L section. The maximum values of the relative vertical displacement between the track bed and the bridge structure occurred in the section at three-quarters of the span. Numerical analysis showed that the lower the temperature, the larger the tensile stresses occurring in the different layers of the track structure, whereas the higher the temperature, the higher the relative displacement between the track system and the box girder bridge. Consequently, quantifying the stresses in the various components of the track structure resulting from sudden temperature drops and evaluating the relative displacements between the rails and the track bed resulting from high-temperature are helpful in the design of ballastless track structures for high-speed railway lines.

摘要

本项目通过对一个四分之一比例的三跨试件在热荷载作用下进行试验,研究了适用于高速铁路(HSR)桥梁的中国铁路轨道系统II型(CRTS II)无砟轨道的力学性能。通过实验和数值模拟两种方式进行应力分析,后者采用有限元建模。结果表明,轨道板、水泥乳化沥青(CA)砂浆和道床中的应变随温度升高呈非线性增加。在纵向方向上,轨道板与道床之间的零位移截面靠近梁的1/8L截面,而轨道板与箱梁桥之间的零位移截面靠近3/8L截面。道床与桥梁结构之间相对竖向位移的最大值出现在跨中四分之三截面处。数值分析表明,温度越低,轨道结构不同层中产生的拉应力越大;而温度越高,轨道系统与箱梁桥之间的相对位移越大。因此,量化突然降温导致的轨道结构各部件中的应力,以及评估高温导致的钢轨与道床之间的相对位移,有助于高速铁路无砟轨道结构的设计。

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本文引用的文献

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