Implementation Of Electric Spring In SEIG Based Autonomous System For Voltage Stabilization

Abstract

In the contemporary paradigm of global energy dynamics, there is a discernible shift towards sustainable and decentralized solutions to meet the growing demand for electricity. Within this transformative landscape, the integration of wind energy assumes a pivotal role, particularly in the context of remote and isolated microgrid configurations. This research aims to comprehensively explore the intricate dynamics associated with voltage stabilization in such remote microgrid settings, placing a special emphasis on the distinctive attributes of a wind-penetrated Self-Excited Induction Generator (SEIG) system. The motivation behind investigating these complex dynamics lies in the unique challenges posed by remote locations, where traditional grid connectivity is often limited or non-existent. In such settings, the intermittency of wind resources adds an additional layer of complexity to the task of maintaining a stable and reliable voltage supply. The SEIG system, with its inherent characteristics, emerges as a promising solution, and this research seeks to unravel the mechanisms through which it contributes to effective voltage stabilization in remote microgrids. By delving into the intricacies of wind energy integration, the study aims to shed light on the challenges and opportunities associated with voltage stabilization. Special attention is given to understanding how the SEIG system, operating in conjunction with wind resources, influences the overall stability of the microgrid. Through a combination of theoretical analysis, simulation studies, and potentially practical implementations, the research strives to provide valuable insights that can inform the development of effective and sustainable energy solutions for remote and isolated regions. newlineThe study investigates the unique challenges posed by remote locations, characterized by intermittent wind resources and limited access to conventional power infrastructure. It explores how the inherent features of SEIG systems contribute to voltage stabilization, consi