Survivability of Autonomous Microgrid during Overload Events

2020 IEEE Power & Energy Society General Meeting (PESGM) Pub Date : 2020-08-02 DOI:10.1109/pesgm41954.2020.9281970

W. Du, R. Lasseter, A. Khalsa

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Abstract

Grid-forming sources are voltage sources that draw necessary currents to meet any load changes. A load step can cause part or all of these sources to become overloaded in a microgrid. This paper presents an overload mitigation controller that addresses the two overload issues in a microgrid by actively controlling the sources’ frequency. When part of the sources in a microgrid is overloaded, the controller autonomously transfers the extra load to other sources by rapidly reducing its frequency. The frequency difference between sources during transient results in a change of phase angle, which redistributes the power flow. When all sources in a microgrid are overloaded, each source keeps dropping the frequency. Therefore, under frequency load shedding can be used to trip the non-critical loads resulting in the survival of microgrid. The advantages of these concepts are that communications between sources are not needed during transient, and the robust voltage control is maintained. Simulation and field tests from CERTS/AEP microgrid test site verify that the control strategy is effective in both purely inverter-based microgrids and inverter & generator mixed microgrids.

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过载事件下自治微电网的生存能力

电网形成源是电压源，它产生必要的电流以满足任何负载变化。负载步骤可能导致微电网中部分或全部这些源过载。本文提出了一种过载缓解控制器，通过主动控制源频率来解决微电网中的两个过载问题。当微电网中部分电源过载时，控制器通过快速降低其频率，自动将多余的负荷转移到其他电源。在暂态过程中，电源之间的频率差会导致相角的变化，从而重新分配潮流。当微电网中的所有源都过载时，每个源的频率不断下降。因此，低频减载可以用来跳闸非关键负荷，从而保证微网的生存。这些概念的优点是在瞬态期间不需要源之间的通信，并且保持了鲁棒电压控制。CERTS/AEP微电网试验场的仿真和现场测试验证了该控制策略在纯逆变器微电网和逆变器&发电机混合微电网中都是有效的。

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 Power & Energy Society General Meeting (PESGM)

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