Adedasola A. Ademola;Roland B. Brandis;Andreas F. Schuetzinger;Bart Simons;Luc Dorpmanns;Andrea Pinceti;Katelynn D. Vance;Ibukunoluwa O. Korede;Robert M. Orndorff;Micah J. Till;Kyle D. Hannah;Mike Lamb;R. Matthew Gardner;Yilu Liu
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引用次数: 0
摘要
地磁感应电流(GIC)在电网中的流动会引起变压器过热、谐波、无功功率需求增加等不良影响。已经开发了许多仿真模型来研究这些影响,但对现代变压器设计的实际验证很少。本文介绍了在美国进行的第一次长时间GIC现场测试,该测试在高压并网变压器上进行,该变压器采用绕组夹和拉杆代替传统的拉杆。采用现场测量来评价GIC的效果。这些测量还有助于开发和验证变压器的热和电磁瞬变(EMT)模型。在测试期间,观察到明显的电流和电压畸变以及相当大的变压器无功功率损耗。现场测量分析表明,变压器的热点在内绕组,其k因子接近出厂测试值和软件默认值。热模拟表明,即使对于峰值约为200 a /相的GIC波形,变压器也不会违反其热极限。EMT模拟显示,在某些情况下,增加变压器负荷可能会减少gic诱导的无功功率需求和谐波。该研究还强调了使用k因子法计算变压器无功损耗的潜在不准确性。
Geomagnetically Induced Current Field Test on Large Grid-Connected Power Transformers: Analysis, Model Development, and Simulations
Geomagnetic-induced current (GIC) flow in power grids can cause undesirable effects such as transformer overheating, harmonics, higher reactive power demand, etc. Many simulation models have been developed to study these effects, but real-world verification on modern transformer designs is rare. This paper presents the first long-duration GIC field test in the U.S. performed on high-voltage, grid-connected transformers featuring winding clamps and tie rods instead of conventional tie bars. Field measurements were taken to evaluate GIC effects. These measurements also aided in developing and validating thermal and electromagnetic transient (EMT) models of the transformers. During the test, significant current and voltage distortions were observed along with considerable transformer reactive power losses. Analysis of the field measurements showed that the transformers’ hottest spot was at the inner windings, and their k-factors were close to factory test and software default values. Thermal simulations indicated that the transformers would not violate their thermal limits even for a GIC waveform that peaks at about 200 A/phase. EMT simulations revealed that increased transformer loading may reduce GIC-induced reactive power demand and harmonics in certain scenarios. The study also highlighted potential inaccuracies in using the k-factor method to calculate transformer reactive power losses.
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