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Multi-physics analysis of a novel circular pantograph catenary system for high-speed trains

Multi-physics analysis of a novel circular pantograph catenary system for high-speed trains
Multi-physics analysis of a novel circular pantograph catenary system for high-speed trains
Purpose
In high-speed trains, the energy is supplied from a high voltage catenary to the vehicle via a pantograph catenary system (PCS). Carbon pantograph strips must maintain continuous contact with the wire to ensure safety and reliability. The contact is often confined to a particular spot, resulting in excessive wear due to mechanical and thermal damage, exacerbated by the presence of an electric arc and associated electrochemical corrosion. The effectiveness and reliability of the PCS impacts on the performance and safety of HSTs, especially under high-speed conditions. To alleviate some of these adverse effects, this paper aims to propose a configuration where a circular PCS replaces the currently used pantograph strips.

Design/methodology/approach
Two dynamic multi-physics models of a traditional PCS with a carbon strip and a novel PCS with a circular pantograph strip catenary system are established, and the electrical and mechanical characteristics of these two systems are compared. Moreover, a PCS experimental platform is designed to verify the validity and accuracy of the multi-physics model.

Findings
A novel circular pantograph system is proposed in this paper to alleviate some of the shortcomings of the traditional PCS. Comparing with a traditional PCS, the circular PCS exhibits superior performance in both electromagnetic and thermal aspects.

Originality/value
The paper offers a new technical solution to the PCS and develops a dedicated multi-physics model for analysis and performance prediction with the aim to improve the performance of the PCS. The new system offers numerous benefits, such as less friction heat, better heat dispersion and improved catenary-tracking performance.
Circular pantograph strip system, High-speed train, Multi-physics modelling, Pantograph catenary system, Pantograph strip
0332-1649
95-108
Xiao, Song
6ffa9657-513e-4b86-86a2-e560d3c09c72
Luo, Yuanpei
8bf37e8e-3ee3-4337-97df-9350b1791505
Wu, Jingchi
b3bb15fe-d2ab-4c82-9f97-1d5fbc150e1e
Zhang, Can
d248e399-21ab-4bfb-bc48-3373f0775d15
Rao, Yang
0dd9723b-9182-4896-acf2-6eb1b197e51e
Wu, Guangning
bfc77dce-7b97-40eb-863a-b4041cd3ebcf
Sykulski, Jan
d6885caf-aaed-4d12-9ef3-46c4c3bbd7fb
Xiao, Song
6ffa9657-513e-4b86-86a2-e560d3c09c72
Luo, Yuanpei
8bf37e8e-3ee3-4337-97df-9350b1791505
Wu, Jingchi
b3bb15fe-d2ab-4c82-9f97-1d5fbc150e1e
Zhang, Can
d248e399-21ab-4bfb-bc48-3373f0775d15
Rao, Yang
0dd9723b-9182-4896-acf2-6eb1b197e51e
Wu, Guangning
bfc77dce-7b97-40eb-863a-b4041cd3ebcf
Sykulski, Jan
d6885caf-aaed-4d12-9ef3-46c4c3bbd7fb

Xiao, Song, Luo, Yuanpei, Wu, Jingchi, Zhang, Can, Rao, Yang, Wu, Guangning and Sykulski, Jan (2020) Multi-physics analysis of a novel circular pantograph catenary system for high-speed trains. COMPEL: The International Journal for Computation and Mathematics in Electrical and Electronic Engineering, 40 (2), 95-108. (doi:10.1108/COMPEL-01-2020-0014).

Record type: Article

Abstract

Purpose
In high-speed trains, the energy is supplied from a high voltage catenary to the vehicle via a pantograph catenary system (PCS). Carbon pantograph strips must maintain continuous contact with the wire to ensure safety and reliability. The contact is often confined to a particular spot, resulting in excessive wear due to mechanical and thermal damage, exacerbated by the presence of an electric arc and associated electrochemical corrosion. The effectiveness and reliability of the PCS impacts on the performance and safety of HSTs, especially under high-speed conditions. To alleviate some of these adverse effects, this paper aims to propose a configuration where a circular PCS replaces the currently used pantograph strips.

Design/methodology/approach
Two dynamic multi-physics models of a traditional PCS with a carbon strip and a novel PCS with a circular pantograph strip catenary system are established, and the electrical and mechanical characteristics of these two systems are compared. Moreover, a PCS experimental platform is designed to verify the validity and accuracy of the multi-physics model.

Findings
A novel circular pantograph system is proposed in this paper to alleviate some of the shortcomings of the traditional PCS. Comparing with a traditional PCS, the circular PCS exhibits superior performance in both electromagnetic and thermal aspects.

Originality/value
The paper offers a new technical solution to the PCS and develops a dedicated multi-physics model for analysis and performance prediction with the aim to improve the performance of the PCS. The new system offers numerous benefits, such as less friction heat, better heat dispersion and improved catenary-tracking performance.

Text
10-1108_COMPEL-01-2020-0014 - Version of Record
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More information

e-pub ahead of print date: 4 May 2020
Published date: 2020
Additional Information: Funding Information: This work was supported in part by the National Natural Science Foundation for Distinguished Young Scholars of China under Grant 51707166 and in part by the Scientific Research Project of Central University Grant 2682018CX16, as well as the Sichuan Science and Technology General Project Grant 2019YJ0213. Publisher Copyright: © 2020, Emerald Publishing Limited. Copyright: Copyright 2021 Elsevier B.V., All rights reserved.
Keywords: Circular pantograph strip system, High-speed train, Multi-physics modelling, Pantograph catenary system, Pantograph strip

Identifiers

Local EPrints ID: 450837
URI: http://eprints.soton.ac.uk/id/eprint/450837
ISSN: 0332-1649
PURE UUID: 3a973e10-a314-46a3-b3e0-fa018d828c01
ORCID for Jan Sykulski: ORCID iD orcid.org/0000-0001-6392-126X

Catalogue record

Date deposited: 13 Aug 2021 16:59
Last modified: 17 Mar 2024 02:33

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Contributors

Author: Song Xiao
Author: Yuanpei Luo
Author: Jingchi Wu
Author: Can Zhang
Author: Yang Rao
Author: Guangning Wu
Author: Jan Sykulski ORCID iD

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