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Research on the Corrosion Prevention of OCS Parts under Complex Environmental Conditions |
YU Gang |
China Railway First Survey and Design Institute Group Co. Ltd, Xi'an, Shaanxi 710043, China |
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Abstract Research purposes: A plateau railway recently started has high relative humidity, which puts forward higher requirements for the anti-corrosion of OCS parts due to the influence of cargo dust in the tunnel and poor equipment maintenance conditions in plateau areas. This paper studies and tests the corrosion influencing factors, adaptability of common anti-corrosion measures and OCS and zinc-nickel infiltration technology of OCS parts, so as to provide reference for the anti-corrosion design of OCS parts in high humidity area of plateau. Research conclusions: (1) The anti-corrosion performance of OCS parts is greatly affected by relative humidity, air temperature, atmospheric medium and other factors. OCS parts in the tunnel are more likely to be corroded due to the joint influence of atmosphere, groundwater and soil. (2) At present, steel OCS parts are treated with hot-dip galvanizing for corrosion protection. A few special work sites have studied and adopted measures such as increasing composite coating, Dacromet corrosion protection. However, affected by the working environment and characteristics of OCS parts, it has great limitations. (3) The anti-corrosion technology of zinc-nickel infiltration coating has the characteristics of high corrosion resistance and high wear resistance. Compared with traditional hot-dip galvanized parts, the anti-corrosion life can be increased by 147%. (4) Relevant technologies and their application in railways in plateau high humidity areas can greatly improve the anti-corrosion performance of OCS parts.
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Received: 18 March 2022
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[1] |
陈敬军,李国良,陈绍华,等.川藏铁路易贡特长隧道设计方案研究[J]. 铁道标准设计,2021(10):140-148.Chen Jingjun,Li Guoliang,Chen Shaohua,etc. Study on Design Scheme of Yigong Extra-long Tunnel of Sichuan-Tibet Railway[J].Railway Standard Design,2021(10):140-148.
|
[2] |
刘莉蓉,雍兴跃,郭奉迎.电气化接触网零部件在典型环境的腐蚀研究[J]. 铁道工程学报,2015(3):81-85.Liu Lirong,Yong Xingyue,Guo Fengying.Research on the Corrosion of Metallic Components of Overhead Contact System in Typical Atmospheric Environment[J].Journal of Railway Engineering Society,2015(3):81-85.
|
[3] |
刘忠. 接触网系统在沿海环境下的适应性研究[J].电气化铁道,2021(2):54-56.Liu Zhong. Study on Adaptability of Overhead Contact System under Coastal Environment[J]. Electric Railway,2021(2):54-56.
|
[4] |
TB/T 2075—2020,电气化铁路接触网零部件[S].TB/T 2075—2020,Fittings for Overhead Contact System in Electrification Railway[S].
|
[5] |
TB/T 2073—2020,电气化铁路接触网零部件技术条件[S].TB/T 2073—2020,Technical Specification of Fittings for Overhead Contact System in Electrification Railway [S].
|
[6] |
胡祥杰,于素芬,李春林.电气化铁路特大桥接触网防腐蚀设计研究[J]. 铁道标准设计,2016(7):140-144.Hu Xiangjie,Yu Sufen, Li Chunlin.Research on Anti-corrosion Design of OCS on Sea-crossing Electric Railway Bridge[J].Railway Standard Design,2016(7):140-144.
|
[7] |
孙传福.张峰.高速铁路接触网钢柱防腐新技术[J]. 铁道建筑技术,2010(7):15-16.Sun Chuanfu,Zhang Feng. New Anti-corrosion Technology of Catenary Steel Column of High-speed Railway[J]. Railway Construction Technology,2010(7):15-16.
|
[8] |
樊伟平. 高速铁路接触网零部件服役性能提升技术研究[J].电气化铁道,2019(1):43-47.Fan Weiping. Technology for Service Performance of OCS Fittings for High Speed Railway[J]. Electric Railway,2019(1):43-47.
|
|
|
|