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单极电容式电压传感器的研究与实验

Research and Experiments on a Unipolar Capacitive Voltage Sensor.

作者信息

Zhou Qiang, He Wei, Li Songnong, Hou Xingzhe

机构信息

State Key Laboratory of Power Transmission Equipment & System Security and New Technology, Chongqing University, Chongqing 400044, China.

State Grid Chongqing Electric Power Co. Electric Power Research Institute, Chongqing 400015, China.

出版信息

Sensors (Basel). 2015 Aug 21;15(8):20678-97. doi: 10.3390/s150820678.

DOI:10.3390/s150820678
PMID:26307992
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4570442/
Abstract

Voltage sensors are an important part of the electric system. In service, traditional voltage sensors need to directly contact a high-voltage charged body. Sensors involve a large volume, complex insulation structures, and high design costs. Typically an iron core structure is adopted. As a result, ferromagnetic resonance can occur easily during practical application. Moreover, owing to the multilevel capacitor divider, the sensor cannot reflect the changes of measured voltage in time. Based on the electric field coupling principle, this paper designs a new voltage sensor; the unipolar structure design solves many problems of traditional voltage sensors like the great insulation design difficulty and high costs caused by grounding electrodes. A differential signal input structure is adopted for the detection circuit, which effectively restrains the influence of the common-mode interference signal. Through sensor modeling, simulation and calculations, the structural design of the sensor electrode was optimized, miniaturization of the sensor was realized, the voltage division ratio of the sensor was enhanced, and the phase difference of sensor measurement was weakened. The voltage sensor is applied to a single-phase voltage class line of 10 kV for testing. According to the test results, the designed sensor is able to meet the requirements of accurate and real-time measurement for voltage of the charged conductor as well as to provide a new method for electricity larceny prevention and on-line monitoring of the power grid in an electric system. Therefore, it can satisfy the development demands of the smart power grid.

摘要

电压传感器是电气系统的重要组成部分。在运行过程中,传统电压传感器需要直接接触高压带电体。传感器体积大、绝缘结构复杂、设计成本高。通常采用铁芯结构。因此,在实际应用中容易发生铁磁谐振。此外,由于采用多级电容分压器,传感器不能及时反映被测电压的变化。基于电场耦合原理,本文设计了一种新型电压传感器;单极结构设计解决了传统电压传感器的许多问题,如接地电极导致的绝缘设计难度大、成本高等问题。检测电路采用差分信号输入结构,有效抑制了共模干扰信号的影响。通过传感器建模、仿真和计算,对传感器电极的结构设计进行了优化,实现了传感器的小型化,提高了传感器的分压比,减小了传感器测量的相位差。该电压传感器应用于10kV单相电压等级线路进行测试。根据测试结果,所设计的传感器能够满足带电导体电压精确实时测量的要求,为电力系统中的防窃电和电网在线监测提供了一种新方法。因此,它能够满足智能电网的发展需求。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b3d0/4570442/e279b0c591c8/sensors-15-20678-g016.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b3d0/4570442/a587c13a132a/sensors-15-20678-g017.jpg
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Study and Experiment on Non-Contact Voltage Sensor Suitable for Three-Phase Transmission Line.适用于三相输电线路的非接触式电压传感器的研究与实验
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