High-Speed Ballasted Railway Track Lateral Resistance Characteristics and Reinforcements

被引：0

作者：

Jing G. ^{[1
]}

Jia W. ^{[1
]}

Fu H. ^{[1
]}

Lu W. ^{[2
]}

机构：

[1] Civil Engineering School, Beijing Jiaotong University, Beijing

[2] China Railway Group Limited, Beijing

来源：

Xinan Jiaotong Daxue Xuebao/Journal of Southwest Jiaotong University | 2019年 / 54卷 / 05期

关键词：

Ballast flight; Lateral resistance; Polyurethane; Shoulder ballast;

D O I：

10.3969/j.issn.0258-2724.20170480

中图分类号：

学科分类号：

摘要：

Ballast flight commonly occurs in high speed ballasted railway tracks, and the probability of ballast flight increases with the decrease of shoulder height; thus, reduced shoulder heights or flat shoulders are used in some countries, which result in lateral resistance reduction. The influence of shoulder height on lateral resistance was analysed in this study. Further, two polyurethane reinforcement methods were proposed, including crib-ballast reinforcement and shoulder reinforcement, which increased the lateral resistances of flat shoulder ballasted tracks and met the demands of tamping. A series of in-situ lateral resistance tests were carried out in this research. The results show that compared to a shoulder height of 150 mm, a 30% reduction in lateral resistance occurs in flat shoulders. For polyurethane spraying depths of 200 mm and 300 mm, the corresponding changes observed were 31% and 41% increase in crib-ballast reinforcement, 41% and 60% increase in shoulder reinforcement, and 70% and 100% increase in synthetic reinforcement (both crib-ballast and shoulder). © 2019, Editorial Department of Journal of Southwest Jiaotong University. All right reserved.

引用

页码：1087 / 1092

页数：5

共 18 条

[1] Tutumluer E., Huang H., Hashash Y., Aggregate shape effects on ballast tamping and railroad track lateral stability, AREMA Annual Conference, pp. 17-20, (2006)
[2] Esveld C., Modern Railway Track, pp. 52-58, (2001)
[3] Gao L., Luo Q., Xu Y., Effects of ballast bed section dimension on its lateral resistance, Journal of Southwest Jiaotong University, 49, 6, pp. 954-960, (2014)
[4] Liu H., Xie K., Wang P., Et al., Effect of regional distribution and degradation of ballast resistance on longitudinal force of rail, Journal of Southwest Jiaotong University, 52, 1, pp. 98-105, (2017)
[5] Jing G., Wang Z., Lin J., Mechanical equilibriu m analysis of ballast flight mechanis m and counteracting measures, Journal of Railway Science and Engineering, 6, pp. 96-101, (2014)
[6] Saat M.R., Bedinijacobini F., Tutumluer E., Et al., Identification of high-speed rail ballast flight risk factors and risk mitigation strategies, 10th World Congress on Railway Research, (2013)
[7] Quinn A.D., A full-scale experimental and modelling study of ballast flight under high-speed trains, Proceedings of the Institution of Mechanical Engineers Part f Journal of Rail & Rapid Transit, 224, 2, pp. 61-74, (2010)
[8] Le P.L., Powrie W., Contribution of base, crib, and shoulder ballast to the lateral sliding resistance of railway track: a geotechnical perspective, Proceedings of the Institution of Mechanical Engineers Part F Journal of Rail & Rapid Transit, 225, 2, pp. 113-129, (2011)
[9] Wang Z.J., Jing G.Q., Liu G.X., Analysis on railway ballast-glue micro-characteristics, Applied Mechanics & Materials, 477-478, pp. 535-538, (2013)
[10] Stjepan L., Track stability using ballast bonding method, Slovenski Kongres O Cestah In Prometu, 10, pp. 333-340, (2010)

← 1 2 →