Engineering design of lossless passive soft switching methods for PWM converters - Part II. With non-minimum voltage stress circuit cells
This paper proposes the analysis and design methodology of lossless, passive soft switching methods for PWM converters. The emphasis of the design and analysis is for PWM converters that use nonminimum voltage stress (non-MVS) circuit cells to provide soft switching. PWM converters with non-MVS circuit cells have several distinct advantages over converters that use minimum voltage stress (MVS) cells. With the same relative size of the inductor and capacitor added for soft switching, the non-MVS cells have a substantially larger duty ratio range where soft switching is guaranteed. In addition, the over-current stress of the main switch, under most conditions, will be lower and an optimum value of inductor and capacitor added for soft switching can be used. Therefore, with proper design, the non-MVS cells provide higher efficiency. These advantages are obtained with the price of higher switching voltage stress and one additional inductor. The loss model for a MOSFET and optimum capacitor and inductor values are utilized in the design procedure. Examples of the design procedure are given for PFC and dc-dc applications. Experimental results backup the claim of higher efficiency.
Publication Source (Journal or Book title)
IEEE Transactions on Power Electronics
Smith, K., & Smedley, K. (2002). Engineering design of lossless passive soft switching methods for PWM converters - Part II. With non-minimum voltage stress circuit cells. IEEE Transactions on Power Electronics, 17 (6), 864-873. https://doi.org/10.1109/TPEL.2002.805601