PERFORMANCE ANALYSIS OF FUZZY CONTROLLER BASED ZVS DC-DC CONVERTER FOR SOLAR ENERGY CONVERSION SYSTEM

International Journal of Technical Research & Science Pub Date : 2019-08-15 DOI:10.30780/ijtrs.v04.i08.005

Abhishek Deshwal, V. Yadav

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Abstract

AbstractThis present work emphasis on the improvement of resonant converter (DC –DC converter) for solar energy conversion system (SECS). It accentuations on plan and exh ib iting periods of the distinctive constituents of the SECS like the rudimentary model of zero voltage switching (ZVS) converter, inverter, fuzzy logic controller, best maximum power point tracking (MPPT) system utilizing MATLAB/ Simulink. Here, a resonant converter represents the static and dynamic characteristics of an actual solar irradiance have been developed for simulation tests. The irradiance and temperature changes circumstances are performed using the resonant converter, which consist of PV system, whose control is implemented using Fuzzy logic control unit and MATLAB/ Simulink. This PV module can achieve maximum power using Perturb & Obserb algorithm. Under various abnormal conditions like change in irrad iance and temperature, step change in irradiance etc. The control system is executed on a fuzzy logic control unit . Speculative outcomes are exhib ited utilizing a 200W model of SECS to demonstrate the better aftereffects of the propelled framework and their control under steadystate and dynamic conditions.

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太阳能转换系统中基于模糊控制器的ZVS dc-dc变换器性能分析

摘要本文着重对太阳能转换系统(SECS)的谐振变换器(DC -DC变换器)进行了改进。重点介绍了零电压开关(ZVS)变换器、逆变器、模糊逻辑控制器、最佳最大功率点跟踪(MPPT)系统的基本模型等SECS各组成部分的规划和运行周期。在这里，谐振变换器代表了一个实际太阳辐照度的静态和动态特性，已开发用于模拟测试。利用由光伏系统组成的谐振变换器来实现辐照度和温度的变化情况，其控制采用模糊逻辑控制单元和MATLAB/ Simulink实现。该光伏模块可以通过Perturb & ob塞族算法实现最大功率。在各种异常条件下，如辐照度和温度的变化、辐照度的阶跃变化等。控制系统在模糊逻辑控制单元上执行。利用200W的SECS模型展示了推测结果，以证明在稳态和动态条件下推进框架及其控制的更好的后效应。

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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International Journal of Technical Research & Science

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