A Dual-Active-Bridge-Based Novel Single-Stage Low Device Count DC-AC Converter

This paper presents a novel single-stage, isolated, and single-phase dc-ac converter topology, suitable for low-medium power-scale solar photovoltaic and fuel-cell applications. The circuit employs two full-bridge cells with floating dc bus capacitors placed on either side of a high-frequency transformer and works on the dual-active-bridge principle. It has advantages of a single-stage power processing structure, low device count (uses eight switches), and the possibility of achieving zero-voltage-switching operation over the full ac line cycle. Moreover, by dynamic variation of phase-shift between the high-frequency primary and secondary voltages, twice-line-frequency energy buffering can be affected via the high-voltage side dc bus capacitor, which reduces decoupling capacitance requirement, enabling a film capacitor-based implementation. Basic operating principle, control strategy, and detailed design optimization guidelines of the circuit are described followed by simulation results to validate the approach. Practical evaluation of converter performance is done on a 250 W, 20-35 V input, and 110 V rms output prototype.