首页|期刊导航|电力工程技术|基于差动电流相关性的直流配电网极间短路故障保护方法

基于差动电流相关性的直流配电网极间短路故障保护方法OA

Protection method for pole-to-pole short-circuit faults in DC distribution networks based on differential current correlation

中文摘要英文摘要

直流配电网发生极间短路故障时,故障电流数毫秒内迅速上升至额定电流的数倍甚至数十倍,导致变流器瞬时闭锁,严重时甚至导致系统停运.为保障直流配电网的持续运行,文中提出基于差动电流相关性的直流配电网极间短路故障保护方法.该方法揭示了极间短路故障的暂态电流持性,区内故障时,差动电流主要由模块化多电平换流器(modular multilevel converter,MMC)与直流变压器电容放电电流组成;区外故障时,差动电流仅包含线路分布电容的放电电流.基于此,文中引入 Pearson 相关性系数,利用线路差动电流与其差分电流积聚量的相关性识别故障线路,进而构成保护判据.仿真结果表明,所提保护方法可以快速、可靠识别故障线路,在发生区外故障时分布电容暂态电流不会造成保护误动.此外,该方法具有一定的抗噪声(30 dB)和同步误差(0.3 ms)的能力,且在高阻(100 Ω)故障下仍能准确识别故障线路.

When a pole-to-pole short-circuit fault occurs in DC distribution networks,the fault current rises to several times or even tens of times the rated current within milliseconds.This rapid increase results in instantaneous converter lockouts and may lead to system shutdowns.To ensure the continuous operation of DC distribution networks,a fault protection method based on differential current correlation is proposed.The transient characteristics of fault currents are investigated.For internal faults,the differential current is mainly formed by capacitor discharge currents from modular multilevel converters and DC transformers.For external faults,the differential current is primarily composed of discharge currents from line-distributed capacitors.Based on these characteristics,the Pearson correlation coefficient is applied to identify faulted lines by analyzing the correlation between line differential currents and their accumulated difference currents.Simulation results demonstrate that the proposed method can quickly and reliably identify faulted lines.Transient currents from line-distributed capacitors during external faults do not cause misoperation.The method is resistant to noise(30 dB)and synchronization errors(0.3 ms).It also accurately identifies high-resistance faults(100 Ω).

贾思强;崔双喜

新疆大学电气工程学院,新疆 乌鲁木齐 830017新疆大学电气工程学院,新疆 乌鲁木齐 830017

信息技术与安全科学

直流配电网电流积聚量极间短路故障差动电流Pearson相关性分布电容

DC distribution networkcurrent accumulationpole-to-pole short-circuit faultdifferential currentPearson correlationdistributed capacitance

《电力工程技术》 2026 (4)

75-83,93,10

国家自然科学基金资助项目(52266018)

10.12158/j.2096-3203.2026.04.008

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