Grid Forming Inverter With Increased Short-Circuit Contribution to Address Inverter-Based Microgrid Protection Challenges

IF 5.2 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Maximiliano Ferrari;Leon M. Tolbert;Emilio C. Piesciorovsky
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引用次数: 0

Abstract

Substantial differences in fault levels between grid-tied and islanded modes is one of the primary challenges of microgrid protection. During grid-tied mode, the bulk grid provides significant short-circuit, while during islanded operation the short-circuit magnitude is small due to inverter-based resources limiting their current output close to nominal ratings. Consequently, conventional distribution protection strategies based on overcurrent cannot reliably protect microgrids when operating in islanded mode. Fuses and circuit breakers are particularly affected because of their inverse characteristics. Presently, the absence of affordable solutions for protecting microgrids in islanded mode leads to microgrids shutting down during electrical faults. The contribution of this article is two-fold. The first innovation proposes specific hardware modifications to grid-forming inverters to increase their short-circuit current during electrical faults. The second innovation introduces a novel control strategy designed to preserve control stability margins even when the grid-filter saturates, ensuring sinusoidal output currents under normal and fault conditions. Through experimental results, the inverter with the proposed modifications can provide more than three-times its nominal current during electrical faults. For the prototype testbed, this was sufficient to enable the use of traditional legacy overcurrent protection, achieving the fuse-to-relay and relay-to-relay minimum coordination time for the line-to-ground, line-to-line to ground, and three-phase electrical faults.
成网逆变器具有更强的短路贡献能力,可应对基于逆变器的微电网保护挑战
并网模式和孤岛模式之间故障水平的巨大差异是微电网保护面临的主要挑战之一。在并网模式下,大容量电网提供大量短路,而在孤岛运行模式下,由于基于逆变器的资源将其电流输出限制在接近额定值的范围内,短路幅度很小。因此,当微电网在孤岛模式下运行时,基于过流的传统配电保护策略无法可靠地保护微电网。熔断器和断路器因其反向特性而尤其受到影响。目前,由于缺乏经济实惠的解决方案来保护孤岛模式下的微电网,导致微电网在发生电力故障时关闭。本文有两方面的贡献。第一项创新是对电网形成逆变器进行特定的硬件修改,以增加其在电气故障期间的短路电流。第二项创新引入了一种新型控制策略,旨在即使在电网滤波器饱和时也能保持控制稳定裕度,确保正常和故障条件下的正弦输出电流。实验结果表明,经过改进的逆变器能在电气故障时提供超过额定电流三倍的电流。在原型测试平台上,这足以使传统的过流保护得以使用,实现了线对地、线对地和三相电气故障的熔断器对继电器和继电器对继电器最小协调时间。
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来源期刊
IEEE Open Journal of the Industrial Electronics Society
IEEE Open Journal of the Industrial Electronics Society ENGINEERING, ELECTRICAL & ELECTRONIC-
CiteScore
10.80
自引率
2.40%
发文量
33
审稿时长
12 weeks
期刊介绍: The IEEE Open Journal of the Industrial Electronics Society is dedicated to advancing information-intensive, knowledge-based automation, and digitalization, aiming to enhance various industrial and infrastructural ecosystems including energy, mobility, health, and home/building infrastructure. Encompassing a range of techniques leveraging data and information acquisition, analysis, manipulation, and distribution, the journal strives to achieve greater flexibility, efficiency, effectiveness, reliability, and security within digitalized and networked environments. Our scope provides a platform for discourse and dissemination of the latest developments in numerous research and innovation areas. These include electrical components and systems, smart grids, industrial cyber-physical systems, motion control, robotics and mechatronics, sensors and actuators, factory and building communication and automation, industrial digitalization, flexible and reconfigurable manufacturing, assistant systems, industrial applications of artificial intelligence and data science, as well as the implementation of machine learning, artificial neural networks, and fuzzy logic. Additionally, we explore human factors in digitalized and networked ecosystems. Join us in exploring and shaping the future of industrial electronics and digitalization.
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