配电网中新型馈线自动化技术的研究进展与应用趋势

doi:10.16180/j.cnki.issn1007-7820.2025.06.013

Abstract

Abstract:

With the continuous growth of power demand and the escalating reliability requirements for power supply to users, feeder automation technology has emerged as a crucial means to enhance the reliability of power distribution networks, evolving from traditional local and centralized modes to intelligent distributed modes. Intelligent distributed feeder automation technology leverages advanced communication technology to enable information interaction and collaborative work among feeder terminal units, significantly improving the speed and accuracy of fault handling. This study reviews the research progress of intelligent distributed feeder automation technology, including its technical principles, communication technology support, and integrated applications with the internet of things and adaptive technologies. The current technical challenges are analized, such as increased difficulty in fault location and direction judgment due to the integration of distributed energy sources. The development trends of intelligent distributed feeder automation technology are prospected, including deep integration with artificial intelligence, technical optimization for distributed energy source integration, and technological innovations to improve power supply reliability and power quality.

Key words: feeder automation, distribution network, fault handling processing, internet of things, adaptive, distributed energy resources

CLC Number:

TP273TM727.2

SUN Jianquan, JIA Youcheng, BAO Yulin, WANG Zhengsen. Research Progress and Application Trend of New Feeder Automation Technology in Distribution Network[J].Electronic Science and Technology, 2025, 38(6): 89-94.

References 42

[1]	周盛星. 配电网运行管理中电力自动化技术的应用[J]. 光源与照明, 2022(6):181-183.
	Zhou Shengxing. The application of power automation technology in distribution network operation management[J]. Lamps & Lighting, 2022(6):181-183.
[2]	李树桐. 电力工程中配电网自动化技术运用[J]. 机电工程技术, 2020, 49(S1): 36-37.
	Li Shutong. The application of distribution network automation technology in power engineering[J]. Mechanical & Electrical Engineering Technology, 2020, 49(S1): 36-37.
[3]	曹崴铭. 配电网运行管理中对电力自动化系统技术的应用[J]. 通信电源技术, 2020, 37(11):278-280.
	Cao Weiming. The application of power automation system technology in the operation and management of distribution networks[J]. Telecom Power Technology, 2020, 37(11):278-280.
[4]	刘方, 肖智超, 王超. 配电自动化的主动配电网多目标调度模型与方法[J]. 重庆理工大学学报(自然科学), 2021, 35(8):190-198.
	Liu Fang, Xiao Zhichao, Wang Chao. Distribution automation based multi objective optimal dispatching model for active distribution network[J]. Journal of Chongqing University of Technology(Natural Science), 2021, 35(8):190-198.
[5]	伍燕梅. 电力系统配电网中自动化技术的应用研究[J]. 光源与照明, 2024(5):198-200.
	Wu Yanmei. Research on the application of automation technology in power system distribution networks[J]. Lamps & Lighting, 2024(5):198-200.
[6]	王洪源, 冀戈, 宋绪磊. 配电网分布式馈线自动化技术探讨[J]. 电力设备管理, 2024(14):11-13.
	Wang Hongyuan, Ji Ge, Song Xulei. Discussion on distributed feeder automation technology in distribution network[J]. Electric Power Equipment Management, 2024(14):11-13.
[7]	罗丹, 沈祖涛, 杨成. 智能配电网的就地馈线自动化技术应用[J]. 电子技术, 2021, 50(11):92-93.
	Luo Dan, Shen Zutao, Yang Cheng. Application of local feeder automation technology in smart distribution networks[J]. Electronic Technology, 2021, 50(11):92-93.
[8]	丁娟. 配电网馈线自动化技术应用[J]. 科学技术创新, 2024(17):49-52.
	Ding Juan. Application of feeder automation technology in distribution networ[J]. Scientific and Technological Innovation, 2024(17):49-52.
[9]	Lin G. Technique strategy of feeder automation of distribution power network[J]. Automation of Electric Power Systems, 2001(7):1-10.
[10]	王翔, 陶策, 彭茁, 等. 智能配电网分布式馈线自动化技术探讨[J]. 电力设备管理, 2024, 9(12):14-16.
	Wang Xiang, Tao Ce, Peng Zhuo, et al. Discussion on distributed feeder automation technology of intelligent distribution network[J]. Electric Power Equipment Management, 2024, 9(12):14-16.
[11]	章沈泉. 智能配电网分布式馈线自动化技术的运用[J]. 大众科学, 2024, 45(23):55-57.
	Zhang Shenquan. Application of distributed feedline automation technology in intelligent distribution network[J]. Popular Science, 2024, 45(23):55-57.
[12]	刘玉林. 浅谈几种馈线自动化技术的应用[J]. 电力设备管理, 2021(3):190-192.
	Liu Yulin. Talking about the application of several feeder automation technologies[J]. Electric Power Equipment Management, 2021(3):190-192.
[13]	Zhang Yu. Automatic feeder planning method of distribution network in mountainous areas considering access to distributed energy[J]. Journal of IOP, 2024, 3(1):1-19.
[14]	王喜柱. 基于电力线载波通信的分布式馈线自动化故障定位方法[J]. 通信电源技术, 2024, 41(7): 58-60.
	Wang Xizhu. Automatic fault location of distributed feeder method based on power line carrier communication[J]. Telecom Power Technology, 2024, 41(7): 58-60.
[15]	马啸宇. 基于RTLAB的馈线自动化建模与检测技术研究[D]. 贵阳: 贵州大学,2023:19-23.
	Ma Xiaoyu. Research on feeder automation modeling and detection technology based on RTLAB[D]. Guiyang: Guizhou University,2023:19-23.
[16]	Qin H, Liu D. Risk assessment in distribution networks considering cyber coupling[J]. International Journal of Electrical Power and Energy Systems, 2023(1):1-16.
[17]	何志毅, 莫禄根, 陈观寿, 等. 基于差分进化的配电网自动化终端布局规划方法[J]. 电气技术与经济, 2024(7):147-149.
	He Zhiyi, Mo Lugen, Chen Guanshou, et al. A distribution network automation terminal layout planning method based on differential evolution[J]. Electrical Equipment and Economy, 2024(7):147-149.
[18]	陈利忠. 配电网馈线自动化终端系统的设计[J]. 自动化应用, 2024, 65(5):218-220.
	Chen Lizhong. Design of distribution network feeder automation terminal system[J]. Automation Application, 2024, 65(5):218-220.
[19]	卢加宏. 配电网层次化保护的优化配置及整定方案研究[J]. 通信电源技术, 2024, 41(6):207-209.
	Lu Jiahong. Research on optimal configuration and setting scheme of hierarchical protection of distribution network[J]. Telecom Power Technology, 2024, 41(6):207-209.
[20]	Lan Y, Yu K, Zeng X, et al. High-impedance faulty feeder detection for cross-country faults in distribution networks based on zero-sequence active power regulation[J]. International Journal of Electrical Power and Energy Systems, 2024(7):162-169.
[21]	Kim K H, Kim J M, Choi S M, et al. Design of intelligent fault isolation device to prevent wide-area power outage in radial-type ±35 kV MVDC distribution system[J]. Journal of Electrical Engineering & Technology, 2025, 20(1):185-198.
[22]	Ying S S, Yu H S. Research on distribution network feeder automation technology[J]. Journal of Physics Conference Series, 2020, 15(7):12-25.
[23]	Zavala-Tubay A, Pico-Mera H, Pico-Mera G. Electric vehicles and their impact on the electric distribution system:A case study of the urban feeder in portoviejo[J]. Ingenius, 2024, 52(6):27-40.
[24]	李宏川, 赵宇, 李彬, 等. 配电物联网边缘计算场景下基于改进ANFIS的电缆通道综合评估及智能预警方法研究[J]. 电力系统保护与控制, 2024, 52(12):94-103.
	Li Hongchuan, Zhao Yu, Li Bin, et al. Comprehensive assessment and intelligent early warning of cable passages based on improved ANFIS in the edge computing scenario of PDIoT[J]. Power System Protection and Control, 2024, 52(12):94-103.
[25]	张开迪, 罗嘉玮, 王毅. 馈线自动化正确率影响因素及改进措施[J]. 电气技术与经济, 2024(2):387-389.
	Zhang Kaidi, Luo Jiawei, Wang Yi. Factors affecting the accuracy of feeder automation and improvement measures[J]. Electrical Equipment and Economy, 2024(2):387-389.
[26]	白佳阳. 配网自动化对供电可靠性的影响及对策分析[J]. 中国设备工程, 2021(14):150-151.
	Bai Jiayang. Analysis of the impact of distribution network automation on power supply reliability and countermeasures[J]. China Plant Engineering, 2021(14):150-151.
[27]	李娜, 杨振亿, 曾杰, 等. 基于5G的智能配电网业务场景应用分析[J]. 湖南电力, 2022, 42(2):98-104.
	Li Na, Yang Zhenyi, Zeng Jie, et al. Analysis of smart distribution network business scenario application based on 5G[J]. Hunan Electric Power, 2022, 42(2):98-104.
[28]	李海培. 电力系统及其自动化施工技术存在的问题与对策[J]. 光源与照明, 2021(7):119-120.
	Li Haipei. Problems and countermeasures in power system and its automation construction technology[J]. Lamps & Lighting, 2021(7):119-120.
[29]	郝文斌, 孟志高, 张勇, 等. 新型电力系统下多分布式电源接入配电网承载力评估方法研究[J]. 电力系统保护与控制, 2023, 51(14):23-33.
	Hao Wenbin, Meng Zhigao, Zhang Yong, et al. Carrying capacity evaluation of multiple distributed power supply access to the distribution network with the background of a new power system[J]. Power System Protection and Control, 2023, 51(14):23-33.
[30]	Ameling J, Gust G. Automated feeder routing for underground electricity distribution networks based on aerial images[J]. European Journal of Operational Research, 2024, 318(2):629-641.
[31]	陆静文, 张云飞. 基于配电网开关死区故障的改进馈线自动化处理方法[J]. 电工技术, 2024(15):98-101.
	Lu Jingwen, Zhang Yunfei. Improved distribution network feeder automation by effective handling of switch dead zone faults[J]. Electric Engineering, 2024(15):98-101.
[32]	李卫彬, 童欣, 黄超, 等. 基于分层定位模型的含DG配电网故障定位方法研究[J]. 电力系统保护与控制, 2022, 50(24):160-166.
	Li Weibin, Tong Xin, Huang Chao, et al. Research on fault localization method for DG distribution network based on hierarchical localization model[J]. Power System Protection and Control, 2022, 50(24):160-166.
[33]	朱占春, 潘宗俊, 唐金锐, 等. 基于单端暂态能量谱相似性的配电网故障区段定位新方法[J]. 电力科学与技术学报, 2021, 36(2):180-191.
	Zhu Zhanchun, Pan Zongjun, Tang Jinrui, et al. A novel fault location method for power distribution systems using energy spectrum similarity analysis of single-terminal transient waveform[J]. Journal of Electric Power Science and Technology, 2021, 36(2):180-191.
[34]	Wu Z, Li Y, Zhang X, et al. Distributed voltage control for multi-feeder distribution networks considering transmission network voltage fluctuation based on robust deep reinforcement learning[J]. Applied Energy, 2025, 37(9):193-202.
[35]	于礼瑞. 有源配网中就地型馈线自动化故障处理策略改进研究[D]. 保定: 华北电力大学,2023:52-55.
	Yu Lirui. Research on improving the fault handling strategy of in-situ feeder automation in active distribution networks[D]. Baoding: North China Electric Power University,2023:52-55.
[36]	梅飞, 陈子平, 裴鑫, 等. 基于矩阵算法的有源配电网故障定位容错方法[J]. 电力工程技术, 2022, 41(6):109-115.
	Mei Fei, Chen Ziping, Pei Xin, et al. Fault-tolerant method for fault location of active distributionnetwork based on matrix algorithm[J]. Electric Power Engineering Technology, 2022, 41(6):109-115.
[37]	Mumtahina U, Alahakoon S, Wolfs P. Optimal allocation and sizing of battery energy storage system in distribution network using mountain gazelle optimization algorithm[J]. Energies, 2025, 18(2):379-388.
[38]	赵高帅. 10 kV配电网馈线自动化系统主站的研究与设计[D]. 保定: 华北电力大学,2025:37-40.
	Zhao Gaoshuai. Research and design of the main station for 10 kV distribution network feeder automation system[D]. Baoding: North China Electric Power University,2025:37-40.
[39]	陈麒宇, 陈朝阳. 电力系统中继电保护自动化技术的应用[J]. 现代工业经济和信息化, 2023, 13(9):161-163.
	Chen Qiyu, Chen Chaoyang. Application of relay protection automation technology in power system[J]. Modern Industrial Economy and Informationization, 2023, 13(9):161-163.
[40]	薛永端, 金鑫, 刘晓, 等. 灵活接地系统中配电网接地保护的适应性分析[J]. 电力系统自动化, 2022, 46(5):112-121.
	Xue Yongrui, Jin Xin, Liu Xiao, et al. Analysis on adaptability of grounding protection for distribution network in flexible grounded system[J]. Automation of Electric Power Systems, 2022, 46(5):112-121.
[41]	王颖. 基于组合赋权法-云模型的5G+智能配电网综合评价研究[D]. 保定: 华北电力大学,2023:35-38.
	Wang Ying. Research on comprehensive evaluation of 5G+ smart distribution network based on combined weighting method-cloud model[D]. Baoding: North China Electric Power University,2023:35-38.
[42]	李艳, 许方杰. 基于配电网自动化技术的电力系统运行优化策略[J]. 光源与照明, 2024(2):234-236.
	Li Yan, Xu Fangjie. Power system operation optimization strategy based on distribution network automation technology[J]. Lamps & Lighting, 2024(2):234-236.

Research Progress and Application Trend of New Feeder Automation Technology in Distribution Network

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