Investigation of 3-Z-network boost converter for photovoltaic power generation system using MPPT control strategies

2016 International Conference on Circuit, Power and Computing Technologies (ICCPCT) Pub Date : 2016-03-18 DOI:10.1109/ICCPCT.2016.7530144

S. Kayatri, R. Vengatesh, S. Rajan

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引用次数: 1

Abstract

This paper investigates the performance of 3-Z-Network boost converter for a standalone Photovoltaic (PV) power generation system. This proposed converter integrates a single-switch with 3-Z-active Network by diodes, capacitors & inductors. The 3-Z structure of the converter improves the energy conversion efficiency with low switching losses and also reduces the shoot through problem. The different operating modes of this converter and the input-output responses have been analyzed. The Voltage gain (Gv) characteristic curve of this converter circuit has been studied for various duty cycle (D) and it is compared with conventional and Quadratic boost converters. The comparative result illustrates that the Voltage gain of the converter is more than the other boost converters. Further, this proposed converter is integrated with the Photovoltaic panel for promoting the green energy. The sun radiates more photons which are used to generate the electrical power. The solar energy has certain intermittency issues, not available at night and also during daytime there may be cloudy or rainy weather and partial shadow effects which affect the performance of the system. During, the Partial Shading Conditions (PSC) multiple peaks and multiple steps are accomplished in the photovoltaic characteristics curve. One way to improve the systems performance is by operating the PV system at its Maximum Power Point (MPP). Here, the Perturb and Observe (P&O), Incremental Conductance (IC) and Improved Incremental Conductance (IIC) algorithms have been incorporated and the simulations are carrying out under Psim-circuit environment to track the MPP. The simulation results show that the Improved Incremental Conductance algorithm overcomes the drawbacks of conventional algorithms where it fails to track the MPP effectively under PSC. The parameters of the PV module have been referred from the manufacturer datasheet (MS24250) for these analyzes.

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基于MPPT控制策略的光伏发电系统3- z网络升压变换器研究

本文研究了用于独立光伏发电系统的3- z网络升压变换器的性能。该转换器集成了一个带有3- z有源网络的单开关，由二极管、电容器和电感组成。变换器的3-Z结构提高了能量转换效率，降低了开关损耗，也减少了射穿问题。分析了该变换器的不同工作模式和输入输出响应。研究了该变换器在不同占空比下的电压增益(Gv)特性曲线，并与常规变换器和二次型变换器进行了比较。对比结果表明，该变换器的电压增益大于其他升压变换器。此外，该转换器与光伏板集成，以促进绿色能源。太阳辐射出更多的光子，这些光子被用来发电。太阳能有一定的间歇性问题，晚上不可用，白天也可能有多云或下雨的天气和部分阴影影响系统的性能。在部分遮阳条件下，光伏特性曲线实现了多峰、多阶变化。提高系统性能的一种方法是在其最大功率点(MPP)运行光伏系统。本文采用了扰动和观察(P&O)、增量电导(IC)和改进增量电导(IIC)算法，并在psim电路环境下进行了模拟，以跟踪MPP。仿真结果表明，改进的增量电导算法克服了传统算法在PSC下无法有效跟踪MPP的缺点。PV组件的参数已从制造商数据表(MS24250)中引用，用于这些分析。

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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2016 International Conference on Circuit, Power and Computing Technologies (ICCPCT)

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