A single‐source nine‐level solar‐PV inverter with quadruple voltage boosting and high reliability

A single‐source nine‐level solar‐PV inverter with quadruple voltage boosting and high reliability

Summary An increase in generation from distributed energy sources like solar PV has motivated researchers to explore better electrical energy conversion solutions. Multilevel inverters with fewer component count and boosting capabilities contribute to a reliable and efficient single‐stage solution....

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Bibliographic Details
Published in:International journal of circuit theory and applications Vol. 52; no. 8; pp. 3734 - 3755
Main Authors: Zaid, Mohammad, Tayyab, Mohammad, Sarwer, Zeeshan, Ali, Mohammad, Sarwar, Adil, Anwar, Md Nishat, Tariq, Mohd, Khalid, Muhammad
Format: Journal Article
Language:English
Published: Bognor Regis Wiley Subscription Services, Inc 01-08-2024
Subjects:
Alternating current
Capacitors
Component reliability
Distributed generation
Efficiency
Electric potential
Energy conversion
grid‐connected operation
Inverters
Leakage current
Mean time to failure
multilevel inverter (MLI)
reliability
Reliability analysis
single‐phase
solar PV
Topology
Voltage
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Summary:Summary An increase in generation from distributed energy sources like solar PV has motivated researchers to explore better electrical energy conversion solutions. Multilevel inverters with fewer component count and boosting capabilities contribute to a reliable and efficient single‐stage solution. This work proposes a reliable single‐source switched capacitor multilevel inverter capable of producing nine‐level boosted AC voltage with its stand‐alone and grid‐connected operation. It employs 11 switches, three diodes, and three switched capacitors. The main feature of the proposed topology is its ability to produce quadruple boosting with respect to the DC input voltage. Another advantage is the exhibition of low capacitor currents due to frequent charging durations in one operational cycle. The selection criterion for the switched capacitors is also presented. The topology's performance is evaluated in MATLAB/Simulink under various conditions and in PLECS environments for its efficiency. It was then realized on an experimental prototype in stand‐alone mode. The topology is then modified in terms of topology and modulation to mitigate the leakage current, thus making it suitable for grid‐connected operation. This operation is validated on the hardware‐in‐the‐loop platform. Further, the reliability analysis explores a high total mean time to failure (MTTFT) of nearly 253,164 hours/failures compared to recent switched capacitor topologies and an efficiency of above 95%. The low inrush currents, high MTTFT value, and better efficiency make it a suitable topology for renewable microgrids' stand‐alone and grid‐integrated operation. A new nine‐level boost inverter with quadruple boost and self‐balanced capacitors is proposed. The inverter is suitable for renewable energy and industrial applications. In the work shown, a thorough analysis of the converter in both stand‐alone and grid‐connected modes is carried out. Reliability analysis and comparison with other converters is done. The working of the converter is verified through experimental, simulation, and hardware‐in‐loop results.
ISSN:0098-9886
1097-007X
DOI:10.1002/cta.3956