可再生能源供电主动配电系统不平衡补偿方法中的电力电子变流器:AOA-RERNN 方法

IF 3.1 3区 计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
R. Banupriya, R. Nagarajan, S. Muthubalaji
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引用次数: 0

摘要

低压电网经常使用三相四线制系统,没有较大的导体,因此必须解决低压电网中不平衡负载和中性线电流大的问题。为了克服低压网络中的负载和电流问题,本手稿提出了一种混合方法,用于改善使用三相四线制系统的低压网络。AOA-RERNN 技术融合了阿基米德优化算法 (AOA) 和回忆-增强-再流-神经网络 (RERNN) 技术,以缓解中性点电压偏移、谐波和中性点对地电压升高等问题。在共用耦合点(PCC)上,阿基米德优化算法和回忆增强型回流神经网络方法相结合,可解决上述问题。该策略包括利用 AOA 优化变流器参数,并利用 RERNN 解决系统失衡问题,包括中高线电流、相位差和中性线补偿。此外,实施基于控制的补偿可降低中性线电流,而无需大型中性线导体。建议的模型在 MATLAB 中完成。因此,所提出的方法达到了令人印象深刻的 97.54% 的效率。但是,现有的方法,如人工变性长粟米算法(ATLA)、自适应蚱蜢优化算法和人工神经网络组合(AGONN)以及比例积分法(PI)的效率分别为 80.23%、77.26% 和 82.13%。模拟结果表明,建议的技术比现有方法提供了更好的结果。最后,本研究证明了所提方法在提高可再生能源发电中电子功率转换器的效率和性能方面的可能性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Power electronic converters in the unbalance compensation method for renewable energy-powered active distribution systems: AOA-RERNN approach

Power electronic converters in the unbalance compensation method for renewable energy-powered active distribution systems: AOA-RERNN approach

Unbalanced loads and high neutral currents on low voltage networks which frequently use three-phase, four wire systems with no larger conductors must need to be addressed. To overcome the loads and currents in low-voltage networks, an hybrid method is proposed in this manuscript for improving the networks of low-voltage using three-phase four-wire systems. The AOA-RERNN technique is the integration of the Archimedean-Optimization-Algorithm (AOA) and Recalling-Enhanced-Recurrent-Neural-Network (RERNN) technique to mitigate the issues, like neutral voltage offset, and harmonics, and neutral-to-ground voltage raise. At the point-of-common-coupling (PCC), the integration of Archimedean-optimization-algorithm and Recalling-enhanced-recurrent-neural-network approach is used to overcome the above mentioned issues. This strategy involves optimizing converter parameters with AOA and addressing system imbalances with RERNN, including mid-high line current, phase disparities, and neutral line compensation. Also, implementing control-based compensation reduces neutral current without requiring large neutral conductors. The proposed model is done in MATLAB. By this, the proposed approach achieves an impressive efficiency of 97.54%. But, the existing methods, like Artificial Transgender Long corn Algorithm (ATLA), Combined Adaptive Grasshopper Optimization Algorithm and Artificial Neural Network (AGONN), And Proportional Integral (PI) attain the efficiency of 80.23%, 77.26%, and 82.13%, respectively. The outcome of the simulation indicates that the proposed technique provides better findings than the present methods. Finally, this study demonstrates the possibility of the proposed approach for increasing the efficiency and the performance of electronic power converters in renewable generation.

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来源期刊
Soft Computing
Soft Computing 工程技术-计算机:跨学科应用
CiteScore
8.10
自引率
9.80%
发文量
927
审稿时长
7.3 months
期刊介绍: Soft Computing is dedicated to system solutions based on soft computing techniques. It provides rapid dissemination of important results in soft computing technologies, a fusion of research in evolutionary algorithms and genetic programming, neural science and neural net systems, fuzzy set theory and fuzzy systems, and chaos theory and chaotic systems. Soft Computing encourages the integration of soft computing techniques and tools into both everyday and advanced applications. By linking the ideas and techniques of soft computing with other disciplines, the journal serves as a unifying platform that fosters comparisons, extensions, and new applications. As a result, the journal is an international forum for all scientists and engineers engaged in research and development in this fast growing field.
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