Details

Autor(en) / Beteiligte

• López del Moral, D.
• Barrado, A.
• Sanz, M.
• Lázaro, A.
• Zumel, P.

Titel

Analysis and implementation of the Buck-Boost Modified Series Forward converter applied to photovoltaic systems

Ist Teil von

• Solar energy, 2018-12, Vol.176, p.771-787

Ort / Verlag

New York: Elsevier Ltd

Erscheinungsjahr

2018

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• •The BBMSF converter presents a step-up and step-down voltage transfer function.•The dynamic performances of the BBMSF converter are similar to Forward converter.•ZVS, ZCS and soft switching characteristics in the diodes and MOSFET.•Use of a single controlled switch and only a driver.•The theoretical analysis is verified through a 225 W prototype. The mismatching phenomenon is one of the main issues in photovoltaic (PV) applications. It could reduce the generated power of a string when a PV panel has different performances from the other PV panels connected to the same string. Distributed Maximum Power Point Tracking (DMPPT) architectures are one of the most promising solutions to overcome the drawbacks associated with mismatching phenomena in PV applications. In this kind of architectures, a DC-DC module integrated converter (MIC) manages each PV panel, isolating it from the rest of the PV panels, for harvesting the maximum available power from the Sun. Due to the high number of DC-DC converters used in a grid-tied PV installation, the most desired MIC requirements are high efficiency, low cost and the capability of voltage step-up and step-down. This paper proposes the Buck-Boost Modified Forward (BBMSF) converter as a good candidate to be applied in DMPPT architectures. A complete analysis of the BBMSF converter is carried out, including the steady-state analysis as well as the small signal analysis in continuous conduction mode. The main advantages of the BBMSF converter are its step-up and step-down voltage transfer function; a higher simplicity, since it only includes a single controlled switch; the soft switching characteristics in all the diodes and MOSFET, reaching in some cases ZVS and ZCS, and yielding high efficiencies; the use of an autotransformer, with better performances than a typical Forward transformer; and the good dynamic performance, like the Forward converter ones. The theoretical analyses are validated through the experimental results in a 225 W BBMSF prototype designed and built under the requirements of a 100 kW grid-tied PV installation, achieving an efficiency up to 93.6%.