第41卷 第22期 电力系统保护与控制 Vol.41 No.22 2013年11月16日 Power System Protection and Control Nov.16, 2013
一种提高分布式馈线自动化故障判定可靠性方法
张 伟,徐士华
(积成电子股份有限公司,山东 济南 250100)
摘要:为解决分布式馈线自动化故障判定过程中的可靠性问题,提出了配电网开关分组模型,依靠开关分组模型研究了开关拒分情况下的故障处理过程,并给出了一种基于逻辑运算的故障处理原则。对开关一次重合闸原则进行了补充,有效避免了开关拒分情况下的故障隔离范围扩大。对开关拒合情况进行了分析,增加了一种开关拒合情况下的二次重合功能,有效避免了开关拒合情况下的故障隔离范围扩大。分三种情况研究了相邻开关通信故障下的故障处理过程,并给出了一种统一的故障判定方法。对开关保护信号失灵分为互感器偶然性干扰及永久性故障分别进行了分析,研究表明偶然性故障对故障隔离无影响,永久性故障将导致故障隔离范围扩大。给出了实例分析,表明所提方法可行。 关键词:配电自动化;分布式馈线自动化;故障判定;故障隔离;故障恢复;可靠性
A method for improving the reliability of distributed 中图分类号: TM76 文献标识码:A 文章编号: 1674-3415(2013)22-0122-06
0 引言
馈线自动化系统具有隔离故障区域并使健全区域快速恢复供电功能feeder automation fault location
ZHANG Wei, XU Shi-hua
(Jicheng Electronics Corporation, Jinan 250100, China)
Abstract: To improve the reliability of distributed feeder automation fault location, a distribution network switch group model is established. Based on switch group model, the failure process due to switch rejecting is researched. The fault handing principles are proposed based on logic operations. By supplementing the principle of single-shot reclosing, the extension of fault isolation scope is avoided effectively when the switch rejects to break. Through analyzing the switch rejecting to close, a secondary reclosing processing method is proposed to avoid fault isolation extending. The fault handling process is researched in three cases of communication failure of the adjacent switch. A uniform failure determination method is given. Incidental interference and permanent failure are discussed in switch protection signal failure. The research shows that incidental interference has no effect on fault isolation, while permanent failure will expand the scope of fault isolation. The results of many cases study show the feasibility and effectiveness of the proposed approaches.
Key words: distribution automation; distributed feeder automation; fault location; fault isolation; fault recovery; reliability [1-15]。对减小停电面积、缩短停电时间、提高供电可靠性具有重要意义。
分布式馈线自动化系统是一种依靠设备间的相互配合隔离故障及恢复健全区域供电的方法[7-10]。主要包括:重合器与电压-时间型分段器配合馈线自动化,重合器与重合器配合馈线自动化,重合器与过流脉冲计数型分段器配合馈线自动化,开关相互通信型馈线自动化[7-14]笔者在文献[15]中提出了一种基于逻辑运算的分布式馈线自动化故障判定方法,该方法将一系列开关模拟量转换为逻辑值,通过一系列逻辑运算得
到开关的控制状态。并对暂时性故障给出了处理方案。但却未对开关拒动、通信故障、保护信号失真等设备可靠性故障发生时的处理方法进行论述。
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为解决实际应用中的诸多可靠性问题,本文提出了一种基于逻辑运算的分布式馈线自动化故障判定可靠性提高方法,该方法根据自动化开关之间的连接关系,提出了一种开关分组模型。依靠开关分组模型对开关拒动分为开关拒分和开关拒合两种情况分别进行了论述,并给出了相应故障处理方案。并将处理方法转换为简单逻辑运算,给出了相应公式。针对通信故障,分分支开关通信故障、主干开关通信故障、分支主干开关通信故障三种情况分别进行了详细论述,并给出了一种基于故障开关延时分闸的统一故障处理原则。对保护信号失真分