A Novel Non-Isolated High-Gain Non-Inverting Interleaved DC-DC Converter

• Published in: Micromachines (Basel) Vol. 14; no. 3; p. 585
• Main Authors: Mumtaz, Farhan, Yahaya, Nor Zaihar, Meraj, Sheikh Tanzim, Singh, Narinderjit Singh Sawaran, Abro, Ghulam E Mustafa
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 28.02.2023; MDPI
• Subjects: Alternative energy sources; Analysis; Circuits; Diodes; Efficiency; Electric current converters; Electric vehicles; Energy resources; Fuel cell industry; Fuel cells; High gain; High voltages; Inductors; non-inverting; non-isolated DC–DC converter; Photovoltaic cells; Prototypes; Ratios; renewable energy; Renewable energy sources; Renewable resources; Switches; switching stress; Topology; Voltage converters (DC to DC); Voltage gain; high gain; renewable energy; non-isolated DC–DC converter; switching stress; non-inverting
• ISSN: 2072-666X; 2072-666X
• DOI: 10.3390/mi14030585

High-gain DC-DC converters are being drastically utilized in renewable energy generation systems, such as photovoltaic (PV) and fuel cells (FC). Renewable energy sources (RES) persist with low-level output voltage; therefore, high-gain DC-DC converters are essentially integrated with RES for satisfactory performance. This paper proposes a non-isolated high-gain non-inverting interleaved DC-DC boost converter. The proposed DC-DC converter topology is comprised of two inductors and these are charging and discharging in series and parallel circuit configurations. The voltage multiplier technique is being utilized to produce high gain. The proposed topology is designed to operate in three modes of operation. Three switches are operated utilizing two distinct duty ratios to avoid the extreme duty ratio while having high voltage gain. Owing to its intelligent design, the voltage stress on the switches is also significantly reduced where the maximum stress is only 50% of the output voltage. The proposed converter's steady-state analysis with two distinct duty ratios is thoroughly explored. Furthermore, a 160 W 20/400 V prototype is developed for performance analysis and validation. The converter topology can generate output voltage with a very high voltage gain of 20, which is verified by the prototype. Moreover, a high efficiency of 93.2% is attained by the proposed converter's hardware prototype.