列车通行和锤击作用下的平板轨道性能。不同地点的测量和连续土壤下轨道相互作用的计算

IF 0.8 4区工程技术 Q4 ACOUSTICS

International Journal of Acoustics and Vibration Pub Date : 2020-09-30 DOI:10.20855/ijav.2020.25.31622

L. Auersch, S. Said

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引用次数: 1

摘要

这一贡献旨在通过比较测量和计算，并通过比较十多个不同测量地点的不同轨道类型，对平板轨道的振动行为进行概述。理论上，连续土上的轨迹是用频波数域法计算的。在实验中，检波器测量结果转化为位移结果。考虑了轨道行为的两个方面，轨道的频率相关的顺应性，通过锤击测量，以及在通过轴载荷下的挠度。理论上，对单个轴的响应可以计算，而在实验中，只能测量整个列车的通过。为了进行理论与实验的比较，将计算得到的单轴下的挠度叠加得到整列列车的响应。因此，板条轨道特性与道砟轨道特性完全不同，道砟轨道特性中每个轴都可以在时间历史中看到。平板轨道具有更全面的特性，在轨道响应中只能找到一个完整的转向架，而且相邻的两个转向架并没有完全分开。对不同轨道元件(钢轨、轨枕、轨道板、基础层)的测量以及与可能共振的频率相关的遵从性，可获得有关轨道元件特性的进一步信息。计算结果表明，土对履带板位移的幅度和宽度有主要影响。在测量结果中，分析了以下参数:平板轨道与道砟轨道、不同类型的平板轨道、损坏的平板轨道、不同的列车、不同测点的开关、空轨枕、弹性层、砂浆层、不同地方的不同土壤。最后，对正常和某些特殊(破损、浮板)轨的实测结果与计算结果吻合较好。

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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Slab Track Behaviour under Train Passage and Hammer Impact - Measurements at Different Sites and Calculated Track Interaction with Continuous Soils

This contribution intends to give an overview on the vibration behaviour of slab tracks in comparison of measurements and calculations and also by comparison of different track types at more than ten different measuring sites. In theory, tracks on continuous soil are calculated by the frequency-wavenumber domain method. In experiment, geophone measurements are transformed to displacement results. Two aspects of track behaviour are considered, the frequency-dependant compliance of the track, measured by hammer impact, and the deflection under a passing axle load. In theory, the response to a single axle can be calculated, whereas in experiment, only the passage of the whole train can be measured. For comparison of theory and experiment, the calculated deflection under a single axle is superposed to get the response of the whole train. As a result, the slab track characteristics are completely different from the ballast track characteristics where each axle can be seen in the time histories. The slab track has a more global behaviour where only a whole bogie can be found in the track response and moreover, the two neighbouring bogies are not completely separated. The measurement of the different track elements (rail, sleeper, track plate, base layer) and the frequency-dependant compliances with possible resonances yield further information about the properties of the track elements. The calculations show that the soil has the dominant influence on the amplitudes and the width of the track-plate displacements. In the measurement results, the following parameters are analysed: slab track vs. ballast track, different types of slab tracks, damaged slab tracks, different trains, switches at different measuring points, voided sleepers, an elastic layer, the mortar layer, and different soils at different places. Finally, a good agreement between measured and calculated results is found for the normal and some special (damaged, floating) slab tracks.

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来源期刊

International Journal of Acoustics and Vibration ACOUSTICS-ENGINEERING, MECHANICAL

CiteScore

1.60

自引率

10.00%

发文量

审稿时长

12 months

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