青藏联网中高性能OPGW的研制与应用

doi:10.11930/j.issn.1004-9649.2013.6.57.5

中国电力 ›› 2013, Vol. 46 ›› Issue (6): 57-62.DOI: 10.11930/j.issn.1004-9649.2013.6.57.5

青藏联网中高性能OPGW的研制与应用

李伟华¹，贾小铁¹，朱京¹，于晶²

1. 国网信息通信有限公司,北京 100761;
2. 上海电缆研究所,上海 200093

收稿日期:2013-02-11 出版日期:2013-06-05 发布日期:2015-12-15
作者简介:李伟华（1982—）,男,湖北潜江人,工程师,从事跨区电网配套通信工程项目的建设管理工作。E-mail: weihuali@sgcc.com.cn

Development and Application of High-Performance OPGW in the Qinghai-Tibet DC Power Transmission Interconnection Project

LI Wei-hua¹, JIA Xiao-tie¹, ZHU Jing¹, YU Jin²

1. State Grid Information & Telecommunication Co., Ltd., Beijing 100761, China;
2. Shanghai Electric Cable Research Institute, Shanghai 200093, China

Received:2013-02-11 Online:2013-06-05 Published:2015-12-15

摘要/Abstract

摘要： 青藏地区高海拔、极端低温、巨大温差的恶劣自然环境严重影响光纤复合架空地线（optical fiber composite overhead ground wire,OPGW）的损耗特性,并且威胁其长期安全稳定运行。为此,介绍在青藏直流联网工程中应用的高性能OPGW。该OPGW采用SMF-28 ULL超低损耗光纤及耐超低温纤膏研发定制而成,在-55 ℃低温环境下仍有良好的损耗特性,成功应用于翻越唐古拉山脉、距离长达295 km的世界最高海拔超长站距光纤通信系统。高性能OPGW的成功研制与应用,为青藏直流联网通信系统长期安全稳定运行奠定了坚实的基础,为后续工程建设积累了宝贵经验。

关键词: 光纤复合架空地线（OPGW）, 超低损耗, 光纤通信, 直流联网

Abstract: The Qinghai-Tibet plateau’s odious natural environment of high altitude, extreme low temperature and great temperature difference has severe impact on the loss characteristics of OPGW, and threatens its long term safe and stable operation. This paper introduces the ultra high-performance OPGW used in the Qinghai-Tibet DC transmission interconnection project. Customized by the use of SMF-28 ULL fiber and low temperature resistant optical fiber ointment, the OPGW has low loss characteristics in the ultra low temperature of -55 ℃ and has been successfully used in the world’s highest ultra long-span optical fiber communication system which crosses over the Tang-ku-la Mountains with a distance up to 295 km. Application shows that the OPGW can operate stably in the poor natural environment of plateau area. The development and application of ultra high performance OPGW provides a good foundation for the long term safe and stable operation of the communication system of the Qinghai-Tibet DC transmission interconnection project and valuable experiences for similar projects in the future.

Key words: OPGW, ultra low loss, optical fiber communication, DC transmission interconnection

中图分类号:

TM73

李伟华，贾小铁，朱京，于晶. 青藏联网中高性能OPGW的研制与应用[J]. 中国电力, 2013, 46(6): 57-62.

LI Wei-hua, JIA Xiao-tie, ZHU Jing, YU Jin. Development and Application of High-Performance OPGW in the Qinghai-Tibet DC Power Transmission Interconnection Project[J]. Electric Power, 2013, 46(6): 57-62.

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参考文献

[1] 黄俊华,林光,周峰,等.首条采用超低损耗光纤的超低衰减OPGW[J]. 电力系统通信,2010,31（10）：6-11.
HUANG Jun-hua, LIN Guang, ZHOU Feng, et al . First ultra low attenuation OPGW cable using ULL fiber[J]. Telecommunications for Electric Power System, 2010,31(10): 6-11.
[2] 刘源,黄丽艳,雷学义. 超低损耗光纤是超长站距光通信的新选择[J]. 电力系统通信,2011,32（6）：35-38.
LIU Yuan, HUANG Li-yan, LEI Xue-yi. ULL optical fiber-the new choice of ultra-long span optical communication[J].Telecommunications for Electric Power System, 2011, 32(6): 35-38.
[3] 董振华,印新达,黄丽艳,等. 521 km超长站距无中继光传输系统研究[J]. 光通信研究,2011（1）：5-8.
DONG Zhen-hua, YIN Xin-da, HUANG Li-yan, et al . Research on a 521 km ultra-long span repeaterless optical transmission system[J]. Study on Optical Transmission System, 2011(1): 5-8.
[4] 国网信息通信有限公司. 超低损耗光纤在智能电网中的应用考察报告[R]. 2010.
[5] 夏江珍,谢同林,贾小铁,等. 507 km超长站距无中继光传输系统[J]. 电力系统通信,2009,30（3）：10-12.
XIA Jiang-zhen, XIE Tong-lin, JIA Xiao-tie, et al . Unrepeated optical fiber transmission over 507 km long haul[J]. Telecommunications for Electric Power System, 2009, 30(3): 10-12.
[6] 郑晓东,何昕. 超长站距光通信工程建设问题初探[J]. 电力系统通信,2008,29（3）：1-6.
ZHENG Xiao-dong, HE Xin. Discussion on ultra-long span optical communication engineering construction[J]. Telecommunications for Electric Power System, 2008, 29(3): 1-6.
[7] 熊煌,李树辰,宋璇坤. 超长站距光传输技术及其在电力系统的应用[J]. 电力系统通信,2008,29（3）：9-10.
XIONG Huang, LI Shu-chen, SONG Xuan-kun. Ultra long span optical fiber transmission technology and its application in electric power system[J]. Telecommunications for Electric Power System, 2008, 29(3): 9-10.
[8] LUCERO A, FOURSA D G, CAI J X. Long-haul raman ROPA-assisted EDFA systems[C]// 2009 IEEE Optical Fiber Conference, San Diego, USA, 2009.
[9] DOWNIE J D, HURLEY J, KHRAPKO R, et al . Performance comparison of a new low-attenuation fibrewith G.652 fiberin unrepeatered single-span systems[C]// 2006 32th European Conference on Optical Communications, Cannes, France, 2006.
[10] 李祥珍,何清素,孙寄生. 智能配电网通信组网技术研究及应用[J]. 中国电力,2011,44（12）：78-81.
LI Xiang-zhen, HE Qing-su, SUN Ji-sheng. Research and application on communication technology in smart distribution and utilization grid[J]. Electric Power, 2011, 44(12): 78-81.
[11] 彭珍.基于GIS的光缆资源管理系统在电力通信网的应用[J].中国电力,2011,44（8）：68-70.
PENG Zhen. Applications of GIS-based cable resource management system in power communication network[J]. Electric Power, 2011, 44(8): 68-70.
[12] 李强,庄严.青藏高原地区风电机组的雷电工程防护设计[J].风能,2010（3）：10-18.
LI Qiang, ZHUANG Yan. The design of the thunder and lightning protection for wind power system in Qinghai-Tiber district[J]. Wind Energy, 2010(3): 10-18.

青藏联网中高性能OPGW的研制与应用

Development and Application of High-Performance OPGW in the Qinghai-Tibet DC Power Transmission Interconnection Project

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青藏联网中高性能OPGW的研制与应用

Development and Application of High-Performance OPGW in the Qinghai-Tibet DC Power Transmission Interconnection Project

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