An asymmetrical multilevel inverter with minimum voltage stress and fewer components for photovoltaic renewable-energy system

IF 2.9 4区 环境科学与生态学 Q3 ENERGY & FUELS
Clean Energy Pub Date : 2024-01-02 DOI:10.1093/ce/zkad073
Rabail Memon, M. A. Mahar, A. S. Larik, Syed Asif Ali shah
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Abstract

The enhanced power quality provided by multilevel inverters (MLIs) has made them more appropriate for medium- and high-power applications, including photovoltaic systems. Nevertheless, a prevalent limitation involves the necessity for numerous switches and increased voltage stress across these switches, consequently increasing the overall system cost. To address these challenges, a new 17-level asymmetrical MLI with fewer components and low voltage stress is proposed for the photovoltaic system. This innovative MLI configuration has four direct current (DC) sources and 10 switches. Based on the trinary sequence, the proposed topology uses photovoltaics with boost converters and fuzzy logic controllers as its DC sources. Mathematical equations are used to calculate crucial parameters for this proposed design, including total standing voltage per unit (TSVPU), cost function per level (CF/L), component count per level (CC/L) and voltage stress across the switches. The comparison is conducted by considering switches, DC sources, TSVPU, CF/L, gate driver circuits and CC/L with other existing MLI topologies. The analysis is carried out under various conditions, encompassing different levels of irradiance, variable loads and modulation indices. To reduce the total harmonic distortion of the suggested topology, the phase opposition disposition approach has been incorporated. The suggested framework is simulated in MATLAB®/Simulink®. The results indicate that the proposed topology achieves a well-distributed stress profile across the switches and has CC/L of 1.23, TSVPU of 5 and CF/L of 4.58 and 5.76 with weight coefficients of 0.5 and 1.5, respectively. These values are notably superior to those of existing MLI topologies. Simulation results demonstrate that the proposed topology maintains a consistent output at varying irradiance levels with FLCs and exhibits robust performance under variable loads and diverse modulation indices. Furthermore, the total harmonic distortion achieved with phase opposition disposition is 7.78%, outperforming alternative pulse width modulation techniques. In summary, it provides enhanced performance. Considering this, it is suitable for the photovoltaic system.
用于光伏可再生能源系统的电压应力最小、元件数量更少的非对称多电平逆变器
多电平逆变器(MLI)可提供更高的电能质量,因此更适用于中高功率应用,包括光伏系统。然而,多电平逆变器普遍存在的一个局限性是需要大量开关,并增加了这些开关上的电压应力,从而增加了整个系统的成本。为了应对这些挑战,我们为光伏系统提出了一种组件更少、电压应力更低的新型 17 级非对称 MLI。这种创新型 MLI 配置有四个直流电源和 10 个开关。基于三进制序列,所提出的拓扑结构使用光伏与升压转换器和模糊逻辑控制器作为直流源。数学公式用于计算拟议设计的关键参数,包括单位总静态电压 (TSVPU)、每级成本函数 (CF/L)、每级元件数 (CC/L) 和开关两端的电压应力。通过考虑开关、直流源、TSVPU、CF/L、栅极驱动器电路和 CC/L 与其他现有 MLI 拓扑进行了比较。分析是在各种条件下进行的,包括不同水平的辐照度、可变负载和调制指数。为减少建议拓扑结构的总谐波失真,采用了相位对置方法。建议的框架在 MATLAB®/Simulink® 中进行了仿真。结果表明,建议的拓扑结构在开关上实现了良好的应力分布,CC/L 为 1.23,TSVPU 为 5,CF/L 为 4.58 和 5.76,权重系数分别为 0.5 和 1.5。这些值明显优于现有的 MLI 拓扑。仿真结果表明,所提出的拓扑结构能在不同辐照度水平下通过 FLC 保持稳定的输出,并在可变负载和不同调制指数下表现出稳健的性能。此外,利用相位反置实现的总谐波失真为 7.78%,优于其他脉宽调制技术。总之,它提供了更高的性能。因此,它适用于光伏系统。
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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来源期刊
Clean Energy
Clean Energy Environmental Science-Management, Monitoring, Policy and Law
CiteScore
4.00
自引率
13.00%
发文量
55
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