Design and Implementation of Three-Level DC-DC Converter with Golden Section Search Based MPPT for the Photovoltaic Applications

Chouki Balakishan,M V Aware,N Sandeep

doi:10.1155/2015/587197

Chouki Balakishan, M V Aware + Show 1 more

Open Access

https://doi.org/10.1155/2015/587197

Copy DOI

Abstract

In many photovoltaic (PV) energy conversion systems, nonisolated DC-DC converters with high voltage gain are desired. The PV exhibits a nonlinear power characteristic which greatly depends on the environmental conditions. Hence in order to draw maximum available power various algorithms are used with PV voltage/current or both as an input for the maximum power point tracking (MPPT) controller. In this paper, golden section search (GSS) based MPPT control and its application with three-level DC-DC boost converter for MPPT are demonstrated. The three-level boost converter provides the high voltage transfer which enables the high power PV system to work with low size inductors with high efficiency. The balancing of the voltage across the two capacitors of the converter and MPPT is achieved using a simple duty cycle based voltage controller. Detailed simulation of three-level DC-DC converter topology with GSS algorithm is carried out in MATLAB/SIMULINK platform. The validation of the proposed system is done by the experiments carried out on hardware prototype of 100 W converter with low cost AT’mega328 controller as a core controller. From the results, the proposed system suits as one of the solutions for PV based generation system and the experimental results show high performance, such as a conversion efficiency of 94%.

Highlights

The photovoltaic systems are major contributors in the electrical power
The converter operation with the maximum power point tracking (MPPT) control and voltage balancing is presented through simulation
Reference value is set to 2 A; after that it is changed according to golden section search (GSS) MPPT

Summary

Introduction

The photovoltaic systems are major contributors in the electrical power. These are utilized effectively with interface to the existing systems through DC-DC converters. Isolated converter structures with cascaded configuration enables to achieve high voltage gain [3]. These are used up to several kW applications [4, 5]. In the conventional boost converters, high voltage ratio is feasible without multistage cascading [8]. The voltage balancing across the DC bus capacitors is required due to nonidealities in the components This is feasible by sensing the voltages across them with corrective feedback through controllers [11, 12]. The current sensing of inductor by dispensing the voltage measurements is feasible to balance the voltages across the DC bus capacitors [13]

Methods

Results

Conclusion