Investigations on the Effects of Rail Longitudinal Forces in Train-Track Dynamic Interaction

IF 1.4 4区工程技术 Q3 ENGINEERING, CIVIL

Periodica Polytechnica-Civil Engineering Pub Date : 2023-10-26 DOI:10.3311/ppci.22964

Amirhesam Taghipour, Jabbar Ali Zakeri, Seyed Ali Mosayebi

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引用次数: 0

Abstract

Nowadays, attention to railways has been increased as one of the important transportation methods. Various factors can cause longitudinal forces on the railway tracks, so the most important factors are the temperature changes due to the rail contraction and expansion (thermal forces), train braking system forces and acceleration, etc. Increasing longitudinal force can lead to buckling phenomena in railway tracks. In this paper, the effects of tensile and compressive longitudinal forces on the parameters of rail, sleeper, and ballast layers under vertical moving loads are investigated by using the finite element method. In this regard, by performing sensitivity analyses for different values of longitudinal forces and train speeds dynamic responses (displacement, velocity, and acceleration) of railway track components like rail, sleeper, and ballast have been studied. The results show that increasing the values of longitudinal axial force from –2000 [kN] up to 2000 [kN] as well as increasing the train speed from 10 [m/s] (36 [km/h]) up to 100 [m/s] (360 [km/h]) increases the rail displacement and velocity in the range of 25% up to 37% also the rail acceleration in the range of 9% up to 14%. The velocity and acceleration of the sleeper also the ballast velocity increase in the range of 24% up to 30% and 7% up to 9%, respectively, by increasing the speed of the train from 10 [m/s] (36 [km/h]) to 100 [m/s] (360 [km/h]) in all three modes without applying axial force, considering compressive and tensile one in the train-track interaction system.

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列车-轨道动力相互作用中钢轨纵向力影响的研究

如今，铁路作为一种重要的交通方式，越来越受到人们的重视。各种因素都会对铁路轨道产生纵向力，因此最重要的因素是由于钢轨收缩和膨胀引起的温度变化(热力)、列车制动系统的力和加速度等。纵向力的增大会导致轨道的屈曲现象。本文采用有限元方法，研究了纵向拉伸和压缩力对垂直移动荷载作用下钢轨、轨枕和道砟层参数的影响。为此，通过对纵向力和列车速度的不同值进行敏感性分析，研究了钢轨、轨枕、道砟等铁路轨道部件的动态响应(位移、速度、加速度)。结果表明，纵向轴向力从-2000 [kN]增加到2000 [kN]，列车速度从10 [m/s] (36 [km/h])增加到100 [m/s] (360 [km/h])，使轨道位移和速度增加25% ~ 37%，使轨道加速度增加9% ~ 14%。当列车速度从10 [m/s] (36 [km/h])增加到100 [m/s] (360 [km/h])时，考虑到列车-轨道相互作用系统中的压缩力和拉伸力，在所有三种模式下，轨枕的速度和加速度以及道砟速度分别增加了24%至30%和7%至9%。

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来源期刊

Periodica Polytechnica-Civil Engineering 工程技术-工程：土木

CiteScore

3.40

自引率

16.70%

发文量

审稿时长

12 months

期刊介绍： Periodica Polytechnica Civil Engineering is a peer reviewed scientific journal published by the Faculty of Civil Engineering of the Budapest University of Technology and Economics. It was founded in 1957. Publication frequency: quarterly. Periodica Polytechnica Civil Engineering publishes both research and application oriented papers, in the area of civil engineering. The main scope of the journal is to publish original research articles in the wide field of civil engineering, including geodesy and surveying, construction materials and engineering geology, photogrammetry and geoinformatics, geotechnics, structural engineering, architectural engineering, structural mechanics, highway and railway engineering, hydraulic and water resources engineering, sanitary and environmental engineering, engineering optimisation and history of civil engineering. The journal is abstracted by several international databases, see the main page.