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引用次数: 13
摘要
本文介绍了在电力系统正常运行以及故障等干扰情况下对相量测量单元(pmu)和同步相量系统进行综合测试和评估的框架。建议使用三种不同的测试方法来完成评估,即类型测试、应用测试和端到端测试,并详细介绍了每种测试方法的硬件和软件模块的系统特征。通过提出的在受控环境中进行PMU测试的方法,以及对PMU算法中使用的不同估计技术的详细分析,人们可以深入了解哪种估计技术对于某个最终用途应用是最准确的。这一假设已经通过在Opal Real Time模拟器上运行的23总线系统上使用硬件在环接口的一系列实际测试场景得到验证。此外,对于仅使用PMU测量值的故障定位算法,同步量估计误差的影响及其从PMU到最终应用程序的传播已经被量化。
PMU Multilevel End-to-End Testing to Assess Synchrophasor Measurements During Faults
This paper introduces a framework for comprehensive testing and evaluation of the phasor measurement units (PMUs) and synchrophasor systems under normal power system operating conditions, as well as during disturbances such as faults. The evaluation is suggested to be accomplished using three different testing approaches, namely, type testing, application testing, and end-to-end testing, for each of which, systematic characterization of the hardware and software modules is presented in detail. Through the proposed approach of PMU testing in a controlled environment and detailed analysis of different estimation techniques used in PMU algorithms, one can gain insights on which estimation technique is most accurate for a certain end-use application. This hypothesis has been validated through series of realistic test scenarios on a 23-bus system running on an Opal Real Time simulator using the hardware-in-the-loop interface. In addition, the impact of synchrophasor estimation errors and their propagation from the PMU toward the end-use applications has been quantified for a fault location algorithm that uses only PMU measurements.
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