一种2 M连接器成套工具的研制
|
摘要
随着智能电网的快速发展和建设,通信的可靠性、准确性和传输的快速性越来越重要。2 M业务作为电力通信网中传输业务的重要组成部分,2 M连接器工艺质量和制作效率将极大影响2 M业务的安全性和可靠性。目前2 M连接器的制作存在效率较低、易虚焊,测试和松紧操作较为繁琐、易伤同轴电缆等问题。针对上述问题,文章研制了一种2 M连接器成套工具,可以用于2 M连接器的焊接、测试以及在数字配线架上的松紧操作,提高了运维人员的工作效率,有效保障了电网通信的可靠性和快速性。
With the rapid development and construction of smart grid, the reliability, accuracy and rapid transmission of communications are becoming more and more important. As an important part of the transmission service in the power communication network, the process quality and production efficiency of the 2 M connector will greatly affect the security reliability of the 2 M service. At present, the 2 M connector has low efficiency and easy solder joint problem. The test and elastic operation is cumbersome and easy to damage the coaxial cable. To solve the above problems, this paper developed a 2 M connector kit, which is mainly used for the welding and testing of 2 M head and the elastic operation of 2 M head on the digital distribution frame, which improves the operation efficiency for the operation and maintenance personnel and effectively guarantees the reliability and rapidity of the power grid communication.
With the rapid development and construction of smart grid, the reliability, accuracy and rapid transmission of communications are becoming more and more important. As an important part of the transmission service in the power communication network, the process quality and production efficiency of the 2 M connector will greatly affect the security reliability of the 2 M service. At present, the 2 M connector has low efficiency and easy solder joint problem. The test and elastic operation is cumbersome and easy to damage the coaxial cable. To solve the above problems, this paper developed a 2 M connector kit, which is mainly used for the welding and testing of 2 M head and the elastic operation of 2 M head on the digital distribution frame, which improves the operation efficiency for the operation and maintenance personnel and effectively guarantees the reliability and rapidity of the power grid communication.
引文
[1]王勇,利韶聪,陈宝仁.电力通信业务应用及发展分析[J].电力系统通信,2010,31(11):44-47.WANG Yong,LI Shaocong,CHEN Baoren.Analysis on the application and development of power communication services[J].Telecommunications for Electric Power System,2010,31(11):44-47.
[2]熊小萍.电力系统广域通信网络可靠性分析及优化设计[D].南宁:广西大学,2014.
[3]赵建利.智能变电站通信系统的实时性和可靠性研究[D].天津:河北工业大学,2012.
[4]高会生.电力通信网可靠性研究[D].保定:华北电力大学,2009.
[5]林宇锋,钟金,吴复立.智能电网技术体系探讨[J].电网技术,2009,33(12):8-14.LIN Yufeng,ZHONG Jin,WU Fuli.Discussion on smart grid supporting technologies[J].Power System Technology,2009,33(12):8-14.
[6]彭林,马骞宙,黄文思,等.信息化支撑智能电网建设[J].电力信息化,2011,9(2):148-151.PENG Lin,MA Qianzhou,HUANG Wensi,et al.Informatization supports the construction of smart power grid[J].Electric Power Information Technology,2011,9(2):148-151.
[7]姜绍艳.2 M光接口及其在电力通信线路保护业务中的应用研究[J].自动化与信息工程,2011,32(6):45-48.JIANG Shaoyan.The 2 M optic-interfaces and the application for line protection business in power communication[J].Automation and Information Engineering,2011,32(6):45-48.
[8]张毅,陈军,余锐,等.2 M传输通道可靠性分析[J].电力系统通信,2010,31(10):30-33.ZHANG Yi,CHEN Jun,YU Rui,et al.Reliability analysis on2 M transmission channel[J].Telecommunications for Electric Power System,2010,31(10):30-33.
[9]林传佳,刘捷.电力通信网2 M传输通道异常分析与处理[J].电力学报,2013,28(6):500-502.LIN Chuanjia,LIU Jie.Analysis and processing of abnormal situation in 2 M transmission channel in electric power communication network[J].Journal of Electric Power,2013,28(6):500-502.
[10]龙康.电力通信2 M通道的业务故障诊断系统分析[J].通信电源技术,2018,35(4):208-210.LONG Kang.Business fault diagnosis system analysis of power communication 2 M channel[J].Telecom Power Technologies,2018,35(4):208-210.
[11]张旭,魏娟,赵冬梅,等.电网故障诊断的研究历程及展望[J].电网技术,2013,37(10):2745-2753.ZHANG Xu,WEI Juan,ZHAO Dongmei,et al.Research course and prospects of power grid fault diagnosis[J].Power System Technology,2013,37(10):2745-2753.
[12]王晔,施科峰,李勃,等.宁夏电力继电保护信号2 M通道传输适应性分析[J].光通信技术,2015,39(10):44-46.WANG Ye,SHI Kefeng,LI Bo,et al.Transmission adaptability analysis of 2 M channel for relay protection signal in Ningxia power grid[J].Optical Communication Technology,2015,39(10):44-46.
[13]孙百生,章继高.光通信系统中数字配线架电接触不良的影响[J].北京邮电大学学报,1999,22(3):73-81.SUN Baisheng,ZHANG Jigao.Effects of the electric contact failure of DDF in optical communication system[J].Journal of Beijing University of Posts and Telecommunications,1999,22(3):73-81.
[14]张春平,唐云善,施健.电力通信设备检修影响业务分析的研究及应用[J].电力系统通信,2012,33(6):23-26.ZHANG Chunping,TANG Yunshan,SHI Jian.Study and application of power communication equipment maintenance effection business analysis[J].Telecommunications for Electric Power System,2012,33(6):23-26.
[15]李建明,刘媛,沈晗阳,等.基于2 M业务的电网保护恢复机制研究[J].电力系统保护与控制,2016,44(16):106-111.LI Jianming,LIU Yuan,SHEN Hanyang,et al.Research on the protection mechanism of electric power grid based on 2 Mbusiness[J].Power System Protection and Control,2016,44(16):106-111.
[16]廖超.一种便携式多功能2 M线缆检测工具[J].集成电路应用,2018,35(12):95-96.LIAO Chao.A portable multi-function 2 M cable detection tool[J].Applications of IC,2018,35(12):95-96.
[17]刘娟.2 M误码测试分析仪的研究与设计[D].武汉:武汉邮电科学研究院,2009.
[18]郭思嘉.电力通信传输网业务通道可靠性评估方法的研究[D].北京:华北电力大学,2017.
[19]曾庆涛.电力通信网风险管理关键技术的研究[D].北京:北京邮电大学,2015.
[2]熊小萍.电力系统广域通信网络可靠性分析及优化设计[D].南宁:广西大学,2014.
[3]赵建利.智能变电站通信系统的实时性和可靠性研究[D].天津:河北工业大学,2012.
[4]高会生.电力通信网可靠性研究[D].保定:华北电力大学,2009.
[5]林宇锋,钟金,吴复立.智能电网技术体系探讨[J].电网技术,2009,33(12):8-14.LIN Yufeng,ZHONG Jin,WU Fuli.Discussion on smart grid supporting technologies[J].Power System Technology,2009,33(12):8-14.
[6]彭林,马骞宙,黄文思,等.信息化支撑智能电网建设[J].电力信息化,2011,9(2):148-151.PENG Lin,MA Qianzhou,HUANG Wensi,et al.Informatization supports the construction of smart power grid[J].Electric Power Information Technology,2011,9(2):148-151.
[7]姜绍艳.2 M光接口及其在电力通信线路保护业务中的应用研究[J].自动化与信息工程,2011,32(6):45-48.JIANG Shaoyan.The 2 M optic-interfaces and the application for line protection business in power communication[J].Automation and Information Engineering,2011,32(6):45-48.
[8]张毅,陈军,余锐,等.2 M传输通道可靠性分析[J].电力系统通信,2010,31(10):30-33.ZHANG Yi,CHEN Jun,YU Rui,et al.Reliability analysis on2 M transmission channel[J].Telecommunications for Electric Power System,2010,31(10):30-33.
[9]林传佳,刘捷.电力通信网2 M传输通道异常分析与处理[J].电力学报,2013,28(6):500-502.LIN Chuanjia,LIU Jie.Analysis and processing of abnormal situation in 2 M transmission channel in electric power communication network[J].Journal of Electric Power,2013,28(6):500-502.
[10]龙康.电力通信2 M通道的业务故障诊断系统分析[J].通信电源技术,2018,35(4):208-210.LONG Kang.Business fault diagnosis system analysis of power communication 2 M channel[J].Telecom Power Technologies,2018,35(4):208-210.
[11]张旭,魏娟,赵冬梅,等.电网故障诊断的研究历程及展望[J].电网技术,2013,37(10):2745-2753.ZHANG Xu,WEI Juan,ZHAO Dongmei,et al.Research course and prospects of power grid fault diagnosis[J].Power System Technology,2013,37(10):2745-2753.
[12]王晔,施科峰,李勃,等.宁夏电力继电保护信号2 M通道传输适应性分析[J].光通信技术,2015,39(10):44-46.WANG Ye,SHI Kefeng,LI Bo,et al.Transmission adaptability analysis of 2 M channel for relay protection signal in Ningxia power grid[J].Optical Communication Technology,2015,39(10):44-46.
[13]孙百生,章继高.光通信系统中数字配线架电接触不良的影响[J].北京邮电大学学报,1999,22(3):73-81.SUN Baisheng,ZHANG Jigao.Effects of the electric contact failure of DDF in optical communication system[J].Journal of Beijing University of Posts and Telecommunications,1999,22(3):73-81.
[14]张春平,唐云善,施健.电力通信设备检修影响业务分析的研究及应用[J].电力系统通信,2012,33(6):23-26.ZHANG Chunping,TANG Yunshan,SHI Jian.Study and application of power communication equipment maintenance effection business analysis[J].Telecommunications for Electric Power System,2012,33(6):23-26.
[15]李建明,刘媛,沈晗阳,等.基于2 M业务的电网保护恢复机制研究[J].电力系统保护与控制,2016,44(16):106-111.LI Jianming,LIU Yuan,SHEN Hanyang,et al.Research on the protection mechanism of electric power grid based on 2 Mbusiness[J].Power System Protection and Control,2016,44(16):106-111.
[16]廖超.一种便携式多功能2 M线缆检测工具[J].集成电路应用,2018,35(12):95-96.LIAO Chao.A portable multi-function 2 M cable detection tool[J].Applications of IC,2018,35(12):95-96.
[17]刘娟.2 M误码测试分析仪的研究与设计[D].武汉:武汉邮电科学研究院,2009.
[18]郭思嘉.电力通信传输网业务通道可靠性评估方法的研究[D].北京:华北电力大学,2017.
[19]曾庆涛.电力通信网风险管理关键技术的研究[D].北京:北京邮电大学,2015.