Multistage converter with reduced switch voltage stress and diode current stress

The utilization of switched inductors, involving parallel charging and series discharging of inductors, is extensively embraced in diverse DC-DC converters for attaining high voltage gain; nevertheless, the stress on switch voltage and diode current escalates considerably with an increased count of inductors integrated into the switched inductors network. In the classical multistage switched inductor converter, the switch voltage aligns with the output voltage, and the diode experiences a high current as the number of stages increases. This research recommends a DC-DC multistage converter for energy conversion and high voltage gain with low stress. In this paper, a novel multistage switched inductor converter is introduced and designed to attain higher voltage gain while mitigating the stresses on switch voltage and diode current. The proposed circuit is created by replacing the standard multistage switched inductor converter's possible diodes with power switches. All of the switching devices are connected in such a way that the output voltage and input current are shared by all of the switches and diodes, respectively. As a consequence, the voltage stress on switches and the current stress on diodes are comparatively low, resulting in a high efficiency compared to a typical multistage switched inductor converter. It's interesting to note that the proposed converter and a typical multistage switched inductor converter both require the same amount of components. Different operation modes, analysis, a non-ideal model, and a comparison of the suggested and recently constructed converters are discussed. The effectiveness and performance of the circuit are validated experimentally. In this research work, a new power circuit is proposed by modifying the circuitry of C-MSI converter. The proposed power circuit is developed to achieve low switch voltage stress, low diode current stress, low cost, and high efficiency compared to C-MSI converter. The proposed power circuit inherently follows the principle of the switched inductor to obtain a large voltage gain. image