Analysis, Design, and Implementation of the AFZ Converter Applied to Photovoltaic Systems

Abstract

Grid-tied photovoltaic (PV) installations with distributed maximum power point tracking (DMPPT) architectures include a dc-dc module integrated converter (MIC) for managing each PV panel, isolating it from the others, reducing the mismatching effect and maximizing the harvested power. In this article, the autotransformer forward converter with type-Zeta resonant reset (AFZ) is proposed as a DMPPT architecture's MIC candidate. The main characteristics of the AFZ converter are the high versatility due to its voltage step-up and step-down capability; the use of an optimized autotransformer with only two windings, reducing the complexity and power losses of this component; the good dynamic performances, like the forward converter ones; the low number of components and the simplicity and high feasibility associated to the use of just one active switch. Besides, soft switching transitions are achieved thanks to the autotransformer type-Zeta resonant reset. The steady-state theoretical analysis, considering the effect of the autotransformer leakage inductance, is presented. The converter is also studied in the frequency domain, obtaining the small-signal transfer functions. A design procedure based on the requirements of a 100-kW grid-tied photovoltaic installation is described, yielding in a 225-W prototype with efficiencies up to 95.6%. Experimental results validate the theoretical analysis.