Abstract
A new non-isolated modified SEPIC front-end dc-dc converter for the low power system is proposed in this paper, and this converter is the next level of the traditional SEPIC converter with additional devices, such as two diodes and splitting of the output capacitor into two equal parts. The circuit topology proposed in this paper is formulated by combining the boost structure with the traditional SEPIC converter. Therefore, the proposed converter has the benefit of the SEPIC converter, such as continuous input current. The proposed circuit structure also improves the features, such as high voltage gain and high conversion efficiency. The converter comprises one MOSFET switch, one coupled inductor, three diodes, and two capacitors, including the output capacitor. The converter effectively recovers the leakage energy of the coupled inductor through the passive clamp circuit. The operation of the proposed converter is explained in continuous conduction mode (CCM) and discontinuous conduction mode (DCM). The required voltage gain of the converter can be acquired by adjusting the coupled inductor turn’s ratio along with the additional devices at less duty cycle of the switch. The simulation of the proposed converter under CCM is carried out, and an experimental prototype of 100 W, 25 V/200 V is made, and the experimental outcomes are presented to validate the theoretical discussions of the proposed converter. The operating performance of the proposed converter is compared with the converters discussed in the literature. The proposed converter can be extended by connecting voltage multiplier (VM) cell circuits to get the ultra-high voltage gain.
Highlights
The demand for high voltage gain dc-dc converters is increased in many real-time power electronics applications in renewable energy systems
High voltage gain dc-dc converters play a significant role in renewable energy-based systems, and this is due to the sources like individual solar photovoltaic (PV) panels, fuel cells, etc. that produce a low output voltage in the range of 20–40 V, and it has to be stepped up to 200–400 V for standalone systems or grid-tied systems with high efficiency, power quality, and the reliability
The gate-source voltage and the voltage stress of the MOSFET switch are shown in Figure 12a, and from Figure 12a, it is noticed that during Mode-2, the maximum voltage stress is about 60 V, and during Mode-3, the maximum voltage stress about 50 V, as discussed earlier
Summary
The demand for high voltage gain dc-dc converters is increased in many real-time power electronics applications in renewable energy systems. High voltage gain dc-dc converters play a significant role in renewable energy-based systems, and this is due to the sources like individual solar photovoltaic (PV) panels, fuel cells, etc. Various advanced converter topologies were introduced by researchers incorporating boosting methods such as voltage-doubler, voltage lift, voltage multiplier (VM) cells, coupled inductors, cascaded circuits, etc. These converters have their own demerits, which has motivated researchers to propose a new converter topology. The authors of [4,5] proposed a modified SEPIC converter topology to improve the voltage gain of a converter for renewable energy applications. The conversion efficiency of the modified SEPIC converter is less than 90%
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