基于移动互联技术的光缆快速寻障系统设计与应用
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摘要
为了精确定位和判定光缆故障、缩短查障时间、降低作业成本、提升智能运检水平,实现对光缆线路的智能检测和精益管理,文章设计了一种基于移动互联技术的光缆快速寻障系统,系统包括基于光的Sagnac效应的现场测试终端、配套手机APP、云管理平台,该系统集成了光缆断点测距、识别、移动管控等功能,引进了"互联网+"检修理念,改进了传统OTDR检测方法,从而有效节约了人力、时间、费用,提升了光缆故障检测的高效性、便捷性、智慧性。
In order to accurately locate and determine the break of optical fiber, shorten the time of fault checking, reduce the cost of operating, and improve the level of intelligent maintenance, thus the intelligent detection and lean management of optical cable can be achieved, a fast optical fiber fault dectetion system based on mobile interconnection technology is designed and applied in this paper. The system includes a field test terminal based on Sagnac effect of light, a matching mobile phone APP and a cloud service platform.The system integrates several functions such as optical cable break point location, fault identification, mobile management and control etc. It also introduces the concept of "Internet Plus" to maintenance, and improves the traditional detection method with OTDR. As a result, the manpower, time and cost can be saved, while the efficiency, convenience and intelligence of fiber optic fault detection can be promoted.
In order to accurately locate and determine the break of optical fiber, shorten the time of fault checking, reduce the cost of operating, and improve the level of intelligent maintenance, thus the intelligent detection and lean management of optical cable can be achieved, a fast optical fiber fault dectetion system based on mobile interconnection technology is designed and applied in this paper. The system includes a field test terminal based on Sagnac effect of light, a matching mobile phone APP and a cloud service platform.The system integrates several functions such as optical cable break point location, fault identification, mobile management and control etc. It also introduces the concept of "Internet Plus" to maintenance, and improves the traditional detection method with OTDR. As a result, the manpower, time and cost can be saved, while the efficiency, convenience and intelligence of fiber optic fault detection can be promoted.
引文
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[9]杨华.光缆线路故障查找与定位方法[J].铁道通信信号,2013,49(1):88-89.YANG Hua.Fault finding and locating method of optical cable line[J].Railway Signalling&Communication,2013,49(1):88-89.
[10]卞庞,吴媛,贾波,等.基于改进型sagnac干涉仪的扰动定位系统[J].仪器仪表学报,2012,33(12):2870-2874.BIAN Pang,WU Yuan,JIA Bo,et al.Position determination of disturbance along a modified sagnac interferometer[J].Chinese Journal of Scientific Instrument,2012,33(12):2870-2874.
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[13]王巨锋,庄琳玲,刘士伟,等.基于光纤Sagnac环滤波器的高稳定光纤布拉格光栅传感解调技术[J].中国激光,2014,41(9):140-146.WANG Jufeng,ZHUANG Linling,LIU Shiwei,et al.Fiber Bragg grating sensor demodulation technology with high stability by using sagnac loop filter[J].Chinese Journal of Lasers,2014,41(9):140-146.
[14]胡光雄,彭志荣,李瑞德,等.基于Android移动终端的光缆故障监测研究[J].自动化与仪器仪表,2017,24(2):92-94.HU Guangxiong,PENG Zhirong,LI Ruide,et al.Research on fiber optic cable fault monitoring based on Android mobile terminal[J].Automation&Instrumentation,2017,24(2):92-94.
[15]蔡娅楠.HTTP协议优化方法的研究与实现[D].北京:北京邮电大学,2016.
[16]陈宽飞,沈华英.支持移动终端的响应式Web设计与研究[J].无线互联科技,2013(3):115-116.
[17]焦玉姝.浅析通信光缆线路故障原因及测试[J].信息通信,2013(1):167.
[18]孙强,秦威,孙睿頔.基于Sagnac干涉的新型光缆径路探测方法研究[J].铁道学报,2014,36(4):60-64.SUN Qiang,QIN Wei,SUN Ruidi.Research on new-type fiber-optic cable path detection system based on sagnac interferometer[J].Journal of the China Railway Society,2014,36(4):60-64.
[2]卢贺,郑福生,李伟华,等.变电站OPGW光缆引下及接地一体式新型工艺的研究[J].电力信息与通信技术,2017,15(10):98-102.LU He,ZHENG Fusheng,LI Weihua,et al.Research on a new integrated technique of OPGW leading down and grounding in substation[J].Electric Power Information and Communication Technology,2017,15(10):98-102.
[3]中国信息通信研究院.移动互联网白皮书(2015年)[R].2015.
[4]薛文婷,马良,耿海洋.电网企业移动终端的应用及安全分析[J].电力信息与通信技术,2017,15(10):132-136.XUE Wenting,MA Liang,GENG Haiyang.Application and security analysis of mobile terminal in power grid enterprise[J].Electric Power Information and Communication Technology,2017,15(10):132-136.
[5]赵晓燕,王鑫,尹华山,等.基于移动终端现场作业的电力营销稽查系统的开发与设计[J].电子设计工程,2016,24(23):62-64.ZHAO Xiaoyan,WANG Xin,YIN Huashan,et al.Development and design of power marketing audit system for on-site inspection based on mobile terminals[J].Electronic Design Engineering,2016,24(23):62-64.
[6]李炜,黄倩.基于智能终端的移动医疗信息系统[J].电子设计工程,2018,26(4):52-55.LI Wei,HUANG Qian.Mobile medical information system based on intelligent terminal[J].Electronic Design Engineering,2018,26(4):52-55.
[7]郑樟新.电力通信光缆网维护和管理中GIS、RFID、移动互联技术的应用[J].通信电源技术,2018,35(12):166-167.ZHENG Zhangxin.Application of GIS,RFID and mobile Internet technology in maintenance and management of power communication optical cable network[J].Telecom Power Technology,2018,35(12):166-167.
[8]冯曙明,王大淼,潘晨溦,等.基于移动互联的电力物资交付与验收业务应用研究[J].电子世界,2018(1):57-58.
[9]杨华.光缆线路故障查找与定位方法[J].铁道通信信号,2013,49(1):88-89.YANG Hua.Fault finding and locating method of optical cable line[J].Railway Signalling&Communication,2013,49(1):88-89.
[10]卞庞,吴媛,贾波,等.基于改进型sagnac干涉仪的扰动定位系统[J].仪器仪表学报,2012,33(12):2870-2874.BIAN Pang,WU Yuan,JIA Bo,et al.Position determination of disturbance along a modified sagnac interferometer[J].Chinese Journal of Scientific Instrument,2012,33(12):2870-2874.
[11]黎华.基于OTDR和光功率测试的光纤故障监测应用方法[J].计算机测量与控制,2014,22(5):1357-1359.LI Hua.Based on OTDR and light power test of fiber optic fault monitoring application[J].Computer Measurement&Control,2014,22(5):1357-1359.
[12]何存富,郑兴强,骆建伟,等.消偏型Sagnac光纤管道泄漏检测系统及其稳定性研究[J].中国激光,2012,39(2):142-146.HE Cunfu,ZHENG Xingqiang,LUO Jianwei,et al.Research on a pipeline leakage detection system and its stability based on depolarized sagnac fiber interferometer[J].Chinese Journal of Lasers,2012,39(2):142-146.
[13]王巨锋,庄琳玲,刘士伟,等.基于光纤Sagnac环滤波器的高稳定光纤布拉格光栅传感解调技术[J].中国激光,2014,41(9):140-146.WANG Jufeng,ZHUANG Linling,LIU Shiwei,et al.Fiber Bragg grating sensor demodulation technology with high stability by using sagnac loop filter[J].Chinese Journal of Lasers,2014,41(9):140-146.
[14]胡光雄,彭志荣,李瑞德,等.基于Android移动终端的光缆故障监测研究[J].自动化与仪器仪表,2017,24(2):92-94.HU Guangxiong,PENG Zhirong,LI Ruide,et al.Research on fiber optic cable fault monitoring based on Android mobile terminal[J].Automation&Instrumentation,2017,24(2):92-94.
[15]蔡娅楠.HTTP协议优化方法的研究与实现[D].北京:北京邮电大学,2016.
[16]陈宽飞,沈华英.支持移动终端的响应式Web设计与研究[J].无线互联科技,2013(3):115-116.
[17]焦玉姝.浅析通信光缆线路故障原因及测试[J].信息通信,2013(1):167.
[18]孙强,秦威,孙睿頔.基于Sagnac干涉的新型光缆径路探测方法研究[J].铁道学报,2014,36(4):60-64.SUN Qiang,QIN Wei,SUN Ruidi.Research on new-type fiber-optic cable path detection system based on sagnac interferometer[J].Journal of the China Railway Society,2014,36(4):60-64.