The Effect of Non-Ideal Operating Conditions on Reliability of Inverters in Microgrids

2020 IEEE 11th International Symposium on Power Electronics for Distributed Generation Systems (PEDG) Pub Date : 2020-09-28 DOI:10.1109/PEDG48541.2020.9244343

Sondre J. K. Berg, F. Göthner, V. V. Vadlamudi, D. Peftitsis

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Abstract

Microgrids are becoming increasingly popular due to modern trends in power consumption and distribution. Power converters are essential in order to ensure the desired function of a microgrid. As with traditional distribution systems, reliability is a major concern since it is one of the main functions of a microgrid [1]. A lot of literature has been published related to microgrid specific reliability. However, literature on the reliability of converters under non-ideal operating conditions is scarce. In this paper, the reliability in terms of failure rate of a three-phase converter operating under non-ideal conditions is investigated. The studied microgrid is derived from the CIGRE LV benchmark system. The study shows that unbalanced conditions have a particularly detrimental effect on converter reliability expressed as its failure rate. Nonlinear conditions also have a negative impact and even more so than the impact of increased RMS currents due to low power factor (pf) loads. In addition, the ambient temperature has a large impact on the system reliability. Temperature swings in the power electronic devices caused by harmonics and imbalanced currents could also cause large failure rate deviations. The results show that failing to include the effect of expected non-ideal operating conditions could lead to a wrong estimation of the system reliability as an effect of worsened failure rates in the power electronic components.

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非理想工况对微电网逆变器可靠性的影响

由于电力消费和分配的现代趋势，微电网正变得越来越受欢迎。为了确保微电网的预期功能，电源转换器是必不可少的。与传统配电系统一样，可靠性是一个主要问题，因为它是微电网的主要功能之一。关于微电网特定可靠性的研究已经发表了大量文献。然而，关于变流器在非理想运行条件下的可靠性的文献很少。本文从故障率的角度研究了三相变流器在非理想工况下的可靠性问题。所研究的微电网来源于CIGRE低压基准系统。研究表明，不平衡工况对变流器的可靠性影响尤为严重，其可靠性表现为变流器的故障率。非线性条件也有负面影响，甚至比由于低功率因数(pf)负载而增加的RMS电流的影响更大。此外，环境温度对系统的可靠性影响较大。谐波和电流不平衡引起的电力电子器件温度波动也会造成较大的故障率偏差。结果表明，如果不考虑预期非理想运行条件的影响，可能会导致对系统可靠性的错误估计，从而导致电力电子元件故障率的恶化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2020 IEEE 11th International Symposium on Power Electronics for Distributed Generation Systems (PEDG)

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