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摘要:利用ZnS:Cu电致发光粉末与环氧树脂胶混合,设计制作了一种梯形电极结构的电压传感单元,实现了电致发光电压传感器输出信号的温度漂移补偿。电致发光电压传感信号通过2根塑料光纤传输到2个硅光电探测器,并选择其开路电压作为传感器的输出信号。在同一外加电压条件下,梯形电极区域内的电场分布是不均匀的,因而不同场点的发光亮度不同。通过测量梯形电极区域内2个不同发光点的发光强度随外加电压的变化,并对两路输出电压传感信号进行数据拟合与计算,可获知被测电压的有效值,并可实现对输出信号温度漂移的补偿。在-40~60℃范围内,采用上述温度漂移补偿方法测量了有效值在0.7~1.5 kV范围内的工频电压,传感器输出信号的非线性误差低于1.6%,验证了该温度漂移补偿方法的有效性。Abstract:A ladder-shaped voltage sensing unit is designed and fabricated using ZnS:Cu powder and epoxy adhesive, and the temperature drift compensation of an electroluminescent voltage sensing signal is implemented. Two channels of electroluminescent voltage sensing signals are transmitted to two photo-detectors using two pieces of plastic optical fibers. Open circuit voltages of the two photo-detectors are used as output voltage sensing signals. The electric field distribution is non-uniform within the ladder-shaped electroluminescent voltage sensing unit, and thus the electroluminescent brightness is also non-uniform under a same applied voltage. AC voltage sensing signals can be obtained by measuring the electroluminescent brightness at two different positions on the ladder-shaped voltage sensing unit. The temperature drift compensation existing in output voltage sensing signal can be achieved by an optimal calculation and fitting of experimental data. 50 Hz AC voltage in the range of 0.7-1.5 kV is measured, and the nonlinear error is less than 1.6% in the range of -40-60℃. This result demonstrates the effectiveness of the proposed temperature drift compensation method.
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图 1基于ZnS\:Cu粉末的电致发光电压传感单元结构示意图
Figure 1.Structure diagram of electroluminescent voltage sensing unit based on ZnS\:Cu powder
图 2电致发光电压传感特性的实验装置
Figure 2.Experimental setup of electroluminescent voltage sensing performances
图 3在不同外加电压下,梯形电压传感单元样品2的电致发光照片
Figure 3.Photographs of electroluminescence from the second ladder-shaped voltage sensing unit under different applied voltages
图 4当Ui=1 200 V时,对应于梯形电压传感单元样品2的开路电压Uoc随不同发光场点位置x变化的曲线
Figure 4.Curves of open-circuit voltageUocversus different electroluminescent positions on the second ladder-shaped voltage sensing unit whenUi=1 200 V
图 5工频电压传感信号波形
Figure 5.Waveforms of electroluminescent voltage sensing signals of 50 Hz AC voltage
图 6开路电压Uoc1和Uoc2随外加电压有效值Ui变化的曲线
Figure 6.Curves of open circuit voltageUoc1andUoc2versus applied voltageUi
图 7梯形电压传感单元的输入阻抗随外加电压变化的曲线
Figure 7.Curves of input impedanceZiof ladder-shaped voltage sensing unit versus applied voltage
图 8开路电压与被测电压及温度的关系
Figure 8.Open circuit voltage versus applied voltage and temperature
图 9当Ui=1 200 V时开路电压随温度变化的曲线
Figure 9.Curves of open circuit voltage versus temperature under the condition ofUi=1 200 V
图 10Ui=1 200 V时,输出电压在补偿前(Uoc1和Uoc2)和补偿后(Uom)随温度变化的曲线
Figure 10.Curves of output voltages versus temperature without compensation (Uoc1andUoc2) and with compensation (Uom) under the condition ofUi=1 200 V
图 11温度漂移补偿后传感器输出电压Uom随外加电压Ui的实验数据及线性拟合直线
Figure 11.Experimental data of output voltageUomwith temperature compensation and applied voltagesUi, and their linear fitting line
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