基于容性分压的特高压GIL暂态电压超宽带在线监测系统的构建

Jiao Chunlei, Ding Deng-wei, L. Weidong, He Liang, Zhang Ziwei, Yu Minghu
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引用次数: 1

摘要

特高压输电系统中的暂态电压过程对Gil设备的绝缘状态有很大的影响。因此,为了实时监测特高压隧道运行过程中瞬时电压过程,本文构建了基于电容分压的瞬态电压超宽带在线监测系统,并在1100kV苏通隧道工程中实际应用。该系统包括电压传感器、监控终端和存储控制单元。在GIL的盖板上进行电容传感变换。信号的转换和采集在监控终端本地完成,并通过光纤上传到上层存储控制单元。监控系统的有效测量带宽范围为2.1Hz ~ 230MHz,采样速率为250ms /s,模拟带宽为100MHz。通过定制的陡触发方式,可以准确捕获电压突变波形,记录时间不小于100ms。在GIL耐压试验中,成功准确地记录了内部绝缘击穿引起的瞬态电压过程。瞬态电压持续时间约为400us,电压第一次突变约为120ns,突变激发的瞬时频率接近35MHz。通过对暂态电压波形的深入分析,有助于研究故障发生过程,识别故障类型,快速准确地定位击穿位置,为特高压GIL维护提供有力支持。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Construction of transient voltage UWB on-line monitoring system in UHV GIL based on capacitive voltage division
The transient voltage process in UHV transmission system has a great influence on the insulation state of Gil equipment. Therefore, in order to monitor the transient voltage process suffered by the UHV GIL during its operation in real time, this paper constructs a transient voltage ultrawideband (UWB) online monitoring system based on capacitive voltage division, which is actual applied in 1100kV Sutong GIL utility tunnel project. The system included voltage sensor, monitoring terminal and storage and control unit. Capacitance sensing transformation is carried out on the cover plate of the GIL. Signal conversion and acquisition are implemented locally at the monitoring terminal, and uploaded to the upper storage control unit through optical fiber. The effective measurement bandwidth of the monitoring system ranges from 2.1Hz to 230MHz, the sampling rate is 250 MS/s, and the analog bandwidth is 100MHz. The abrupt voltage waveform can be accurately captured by customized steep trigger mode, and the recording time is not less than 100 ms. During withstand voltage test of the GIL, the transient voltage process caused by internal insulation breakdown is recorded successfully and accurately. The transient voltage duration is about 400us, the first abrupt change of voltage is about 120ns, and the instantaneous frequency excited by the abrupt change is close to 35MHz. Through in-depth analysis of transient voltage waveform, it is helpful to research the process of fault occurrence, identify the type of fault, and locate the breakdown location quickly and accurately, which provides strong support for the maintenance of UHV GIL.
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