[1]冉惟可.电气化铁路隧道内接触网电缆挂架优化及安装形式研究[J].高速铁路技术,2023,14(01):43-47.[doi:10.12098/j.issn.1674-8247.2023.01.008]
 RAN Weike.A Study on Optimization and Installation Form of Cable Hanger of Overhead Contact System in Electrified Railway Tunnels[J].HIGH SPEED RAILWAY TECHNOLOGY,2023,14(01):43-47.[doi:10.12098/j.issn.1674-8247.2023.01.008]
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电气化铁路隧道内接触网电缆挂架优化及安装形式研究()
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《高速铁路技术》[ISSN:1674-8247/CN:51-1730/U]

卷:
14卷
期数:
2023年01期
页码:
43-47
栏目:
出版日期:
2023-03-10

文章信息/Info

Title:
A Study on Optimization and Installation Form of Cable Hanger of Overhead Contact System in Electrified Railway Tunnels
文章编号:
1674-8247(2023)01-0043-05
作者:
冉惟可
中铁二院工程集团有限责任公司,成都610031
Author(s):
RAN Weike
China Railway Eryuan Engineering Group Co. ,Ltd. ,Chengdu 610031 ,China
关键词:
牵引供电 接触网 电缆挂架 隧道 电气化铁路
Keywords:
traction power supplyoverhead contact systemcable hangertunnelelectrified railway
分类号:
U225.4
DOI:
10.12098/j.issn.1674-8247.2023.01.008
文献标志码:
A
摘要:
电气化铁路隧道内电缆的安装结构及敷设形式直接影响供电设施的可靠性,是确保列车牵引供电安全的关键。为保障隧道内27.5kV电缆的长期稳定运行,本文在分析传统电缆挂架和安装形式的基础上,提出了基于复合材料的新型电缆挂架,从结构形式、力学性能、施工效率、工程经济性等方面探讨了新型电缆挂架的特点,分析了隧道内电缆安装的不同形式的优缺点和适用范围。研究成果可为电气化铁路隧道内电缆挂架选用及安装形式设计提供借鉴。
Abstract:
The installation structure and laying form of cables in electrified railway tunnels directly affect the reliability of power supply facilities and are the key to ensuring the safety of train traction power supply. In order to ensure the long-term stable operation of 27. 5 kV cable in the tunnel,this paper put forward a new type of cable hanger based on composite mate-rials on the basis of analyzing the traditional cable hanger and installation form,discussed its characteristics from the aspects of structural form,mechanical properties,construction efficiency,and engineering economy,and analyzed the advantages and disadvantages and application scope of different forms of cable installation in the tunnel. The results can provide a refer-ence for the selection and installation form design of cable hangers in electrified railway tunnels.

参考文献/References:

[1]王志强,贺毅,尹磊,等. 复合材料制品在铁路牵引供电系统中的应用[J]. 电气时代,2021(11): 48 - 49. WANG Zhiqiang,HE Yi,YIN Lei,et al. Application of Composite Products in Railway Traction Power Supply System[J]. Electric Age,2021(11): 48 - 49.
[2]肖云涛,高江涛. 电气化铁路27. 5 kV单相交流交联聚乙烯绝缘电缆的改进[J]. 电线电缆,2020(2): 17 - 19. XIAO Yuntao,GAO Jiangtao. Structural Improvement of 27. 5 kV Single Phase AC XLPE Insulated Cable for Electrified Railway[J]. Wire & Cable,2020(2): 17 - 19.
[3]孟思明,易丹. 高速铁路27. 5kV电力电缆数字化运维与智能监测系统技术研究[J]. 现代计算机,2021(21): 86 - 89,94. MENG Siming,YI Dan. Research on the Technology of Digital Maintenance and Intelligent Monitoring System for 27. 5 kV Power Cable of High Speed Railway[J]. Modern Computer,2021(21):86 - 89,94.
[4]许云升. 铁路27. 5kV高压电缆绝缘在线监测探讨[J]. 电气化铁道,2021,32(4): 50 - 52,56. XU Yunsheng. Discussion on Online Monitoring of Railway 27. 5 kV High Voltage Cable Insulation[J]. Electric Railway,2021,32(4):50 - 52,56.
[5]贺毅,代文平,肖琨. 铁道27. 5kV电缆接头芯温监测系统方案研究[J]. 电气技术,2020,21(2): 114 - 118. HE Yi,DAI Wenping,XIAO Kun. Research on the System Scheme for Core Temperature Monitoring of Cable Joints which Used in Electric Railway[J]. Electrical Engineering,2020,21(2): 114 -118.
[6]缪晓宇,胡豪,杨佳,等. 三相电缆护层的感应电压影响因素分析[J]. 高速铁路技术,2019,10(6): 41 - 44,86. MIAO Xiaoyu,HU Hao,YANG Jia,et al. Analysis on Influencing Factors of Induced Voltage of Three-Phase Cable Sheath[J]. High Speed Railway Technology,2019,10(6): 41 - 44,86.
[7]崔艳龙,邓洪,郭琦沛. 基于分布式光纤的电气化铁路27. 5 kV智能电缆研究[J]. 电气化铁道,2020,31(4): 6 - 9. CUI Yanlong,DENG Hong,GUO Qipei. Research on Distributed Optical Fiber Based 27. 5 kV Intelligent Cables for Electrified Railway [J]. Electric Railway,2020,31(4): 6 - 9.
[8]靳忠福. 高速铁路全电缆贯通线精确故障定位关键技术分析[J]. 铁道科学与工程学报,2021,18(3): 596 - 604. JIN Zhongfu. Analysis of Key Techniques for Accurate Fault Location of High-Speed Railway Full Cable through Line[J]. Journal of Railway Science and Engineering,2021,18(3): 596 - 604.
[9]陶宇航,张熹,宫祥龙. 10kV电缆故障测距及定位典型案例分析[J]. 电气技术,2022,23(2): 88 - 93. TAO Yuhang,ZHANG Xi,GONG Xianglong. Typical Cases Analysis of 10 kV Cable Fault Location [J]. Electrical Engineering,2022, 23(2): 88 - 93.
[10]沈建辉,邵岩,谭磊,等. 电气化铁路27. 5 kV供电电缆绝缘状态检测现状及发展综述[J]. 电气化铁道,2021,32(S1): 114 -117. SHEN Jianhui,SHAO Yan,TAN Lei,et al. Review on the Current Situation and Development of Insulation State Detection of 27. 5 kV Power Supply Cable in Electrified Railway[J]. Electric Railway, 2021,32(S1): 114 - 117.
[11]张凉永. 高速铁路全电缆电力贯通线的电容电流及其容性无功补偿分析[J]. 高速铁路技术,2015,6(1): 27 - 31,37. ZHANG Liangyong. Analysis of Capacitive Current and Capacitive Reactive Compensation in the Medium-Voltage of All-Cable through Line on High-Speed Railway[J]. High Speed Railway Technology, 2015,6(1): 27 - 31,37.
[12]谷元平. 山区高铁27. 5kV高压电缆安装方式研究[J]. 自动化与仪器仪表,2018(4): 80 - 84. GU Yuanping. Installation Schemes Research of 27. 5 kV HV Cable for High-Speed Railway in Mountainous Area[J]. Automation &Instrumentation,2018(4): 80 - 84.

备注/Memo

备注/Memo:
收稿日期:2022-06-23
作者简介:冉惟可(1978-),男,高级工程师。
基金项目:中铁二院工程集团有限责任公司科技发展计划项目(KDNQ212002)
更新日期/Last Update: 2023-03-10