13-Level Single-Source Switched-Capacitor Boost Multilevel Inverter

13-Level Single-Source Switched-Capacitor Boost Multilevel Inverter

Transformerless inverters (TIs) are becoming increasingly popular in solar photovoltaic (PV) applications due to their enhanced efficiency and cost-effectiveness. Unlike transformer-based inverters, TIs, which lack transformers and additional components, offer significant advantages in terms of redu...

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Bibliographic Details
Main Authors: Kah Haw Law, Yew Wei Sia, Raymond Choo Wee Chiong, Swee Peng Ang, Kenneth Siok Kiam Yeo, Sy Yi Sim
Format: Article
Language:English
Published: MDPI AG 2025-03-01
Series:Energies
Subjects:
multilevel inverter (MLI)
photovoltaic (PV)
self-balanced
switched-capacitor (SC)
transformerless inverter (TI)
voltage boost
Online Access:https://www.mdpi.com/1996-1073/18/7/1664
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Summary:Transformerless inverters (TIs) are becoming increasingly popular in solar photovoltaic (PV) applications due to their enhanced efficiency and cost-effectiveness. Unlike transformer-based inverters, TIs, which lack transformers and additional components, offer significant advantages in terms of reduced weight, compactness, and lower costs. Research studies have demonstrated that multilevel TIs can achieve lower total harmonic distortion (THD), reduced switching stresses, and higher AC output voltage levels suitable for high voltage applications. However, achieving these outcomes simultaneously with maximum power ratings and the lowest switching frequencies poses a challenge for TI topologies. In light of these challenges, this research proposes the implementation of a 13-level single-source switched-capacitor boost multilevel inverter (SSCBMLI) designed for solar PV systems. The SSCBMLI consists of a single DC power source, switched-capacitor (SC) units, and a full H-bridge. Compared to other existing 13-level multilevel inverter (MLI) configurations, the proposed SSCBMLI utilizes the fewest components to minimize development costs. Moreover, the SSCBMLI offers voltage boosting and can drive high inductive loads, self-voltage-balanced capacitors, an adaptable topology structure, and reliable system performance. Simulations and experimental tests are conducted using PLECS 4.5 and SIMULINK to assess the performance of the proposed SSCBMLI under varying modulation indices, source powers, and loads. A comparative analysis is then conducted to evaluate the SSCBMLI against existing inverter topologies.
ISSN:1996-1073

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