Influence of Turnout Type Selection on Throat Length and Headway of High-Speed Railway Station

被引：0

作者：

Hu C. ^{[1
]}

Wei Y. ^{[1
]}

Yu Z. ^{[1
]}

机构：

[1] School of Traffic and Transportation, Beijing Jiaotong University, Beijing

来源：

Zhongguo Tiedao Kexue/China Railway Science | 2024年 / 45卷 / 03期

关键词：

Headway time; Station carrying capacity; Station throat; Train operation simulation; Turnout type selection;

D O I：

10.3969/j.issn.1001-4632.2024.03.15

中图分类号：

学科分类号：

摘要：

Aiming at problems such as extra-long throat length and long train running distances caused by the use of large number turnouts in high-speed railway stations, based on the clear calculation method of the station throat length and train headway time, simulation calculations were carried out relying on a certain end type high-speed railway station. Firstly, optimization schemes of different turnout type selection were designed, and then the effects of turnout type selection, train speed before entering the station, and the length of the first departure block track section (short for “one departure”) on station throat length and headway time were explored. The results showed that if all or part of No. 12 turnouts were used in the station, the station throat length could be shortened by 30. 66% and 13. 40% respectively, although the headway time of trains would slightly increase compared with that of No. 18 turnouts. Under the condition that the line outside the station was restricted by certain terrain conditions, the limited speed of train interval was 260 km·h-1 when all of No. 12 turnouts were used. The limited speed was 280 km·h-1 when part of No. 12 turnouts were used, then the length of the station throat and the arrival headway could be compressed simultaneously. If all of No. 12 turnouts were used to limit the length of the no-switch area in one departure to no more than 1 000 m and part of No. 12 turnouts were used to limit the length to no more than 1 400 m, the station throat length and departure headway time could be compressed simultaneously. © 2024 Chinese Academy of Railway Sciences. All rights reserved.

引用

页码：159 / 167

页数：8

共 24 条

[1] LI Changhuai, Theoretical Study on the Formulation of High-Speed Railway Turnout Number Standard, High Speed Railway Technology, pp. 1-6, (2020)
[2] ZHANG Yuesong, TIAN Changhai, JIANG Xinliang, Et al., Calculation Method for Train Headway of High Speed Railway, China Railway Science, 34, 5, pp. 120-125, (2013)
[3] TIAN Changhai, ZHANG Shoushuai, ZHANG Yuesong, Et al., Study on the Train Headway on Automatic Block Sections of High Speed Railway, Journal of the China Railway Society, 37, 10, pp. 1-6, (2015)
[4] CHEN Lei, Calculation of Tracking Interval Time of High-Speed Railway Based on Traction Simulation, (2020)
[5] MA Yuhang, Simulation Study for Arrival and Departure Trains at High Speed Yard in Beijing South Railway Station, (2022)
[6] ZHOU L S, TONG L C, CHEN J H, Et al., Joint Optimization of High-Speed Train Timetables and Speed Profiles:a Unified Modeling Approach Using Space-Time-Speed Grid Networks [J], Transportation Research Part B: Methodological, 97, pp. 157-181, (2017)
[7] FU L C, DESSOUKY M., Models and Algorithms for Dynamic Headway Control [J], Computers & Industrial Engineering, 103, pp. 271-281, (2017)
[8] HOU Liming, SUN Pengfei, NIE Yingjie, Et al., A Study on Optimizing High-Speed Railway Tracking Intervals, Railway Transport and Economy, 40, 6, pp. 5-11, (2018)
[9] YANG Xiao, Study on Influence Factors and Test Methods of High- Speed Train Tracking Interval, Railway Transport and Economy, 39, 6, pp. 22-26, (2017)
[10] GAO Guolong, ZHANG Jie, YANG Xiaojun, A Study on the High Speed Railway Signal Block Layout for Long Downhill Grade Line, Railway Transport and Economy, 42, 2, pp. 73-80, (2020)

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