Design of Fast Intelligence Hybrid Fuzzy Logic and Improved Incremental Conductance Based MPPT Technique

IF 0.6 Q3 ENGINEERING, MULTIDISCIPLINARY

Jurnal Kejuruteraan Pub Date : 2023-09-30 DOI:10.17576/jkukm-2023-35(5)-08

Khaleel Abed Abutaima, Ramizi Mohamed, Mahidur R. Sarker, Radin Za’im Radin Umar

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Abstract

Presently, there has been a significant growth in the solar PV technology due to various factors such as clean technology, zero carbon emission and low maintenance. However, it becomes significant to extract the power in abundance from solar PV system due to its intermittent nature. To extract the significant power, a suitable maximum power point tracking (MPPT) technique has been presented. The MPPT technique is developed based on the hybrid fuzzy logic (FL) and improved incremental and conductance (IInC) method. The aim of developing hybrid FL-IInC technique for MPPT is to regulate duty cycle so that maximum power point (MPP) is achieved with stable and accurate outcomes during dynamic and steady state conditions. The IInC method was developed by regulating the duty cycle and step-size. of It was observed that proposed hybrid FL-IInC delivers accurate and stable results as compared with IInC method. During the model testing at the irradiance with 1000w/m2, the achieved MPPT efficiency was 99.96% as compared with the IInC with an outcome of 98.47% for the improved technique. Additionally, the settling time for the proposed hybrid FL-IInC was less compared with the IInC method. All the simulations were conducted with the MATLAB Simulink Platform. In future, the hybrid FL-IInC method can be employed with other conditions such as partial shading for better applicability

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设计基于快速智能混合模糊逻辑和改进增量电导的 MPPT 技术

目前，由于清洁技术、零碳排放和低维护等各种因素，太阳能光伏技术有了显著增长。然而，由于太阳能光伏系统的间歇性，如何从该系统中提取大量电能变得尤为重要。为了提取大量电力，提出了一种合适的最大功率点跟踪（MPPT）技术。MPPT 技术是基于混合模糊逻辑（FL）和改进的增量与电导（IInC）方法开发的。为 MPPT 开发混合 FL-IInC 技术的目的是调节占空比，从而在动态和稳态条件下以稳定和准确的结果实现最大功率点 (MPP)。与 IInC 方法相比，所提出的混合 FL-IInC 方法能提供准确、稳定的结果。在辐照度为 1000w/m2 的模型测试中，MPPT 的效率为 99.96%，而 IInC 的效率为 98.47%。此外，与 IInC 方法相比，拟议的混合 FL-IInC 的沉淀时间更短。所有模拟都是在 MATLAB Simulink 平台上进行的。未来，混合 FL-IInC 方法还可用于部分遮光等其他条件，以获得更好的适用性。

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

Jurnal Kejuruteraan ENGINEERING, MULTIDISCIPLINARY-

自引率

16.70%

发文量

审稿时长

24 weeks