A Single-Stage Bimodal Transformerless Inverter with Common-Ground and Buck-Boost Features

Vo, Dai-Van; Nguyen, Minh-Khai; Lim, Young‐Cheol; Choi, Joon-Ho

doi:10.3390/electronics12010221

Cited by 3 publications

(2 citation statements)

References 33 publications

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“…Electronics 2024, 13, x FOR PEER REVIEW (a) (b) Based on ( 6) and (10), the comparison diagram between λ and λb is indica Figure 5b. It can be concluded from Figure 5b that the voltage transfer ratio λb conventional boost converter is larger than λ of the proposed rectifier.…”

Section: Mathematical Modelingmentioning

confidence: 99%

“…To overcome these limitations and achieve higher voltage gain, several enhanced boosting solutions have been proposed, including isolation transformers, switched capacitors, coupled inductors, and cascaded converters. However, isolation transformers, while capable of achieving step-up and step-down functions, have drawbacks such as significant weight, volume, and cost, making their design complex and expensive [10]. Switched capacitors offer advantages in terms of high-power density and the use of only power switches and clamped capacitors.…”

Section: Introductionmentioning

confidence: 99%

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SEPIC-Boost-Based Unidirectional PFC Rectifier with Wide Output Voltage Range

Cheng,

Li,

Wang

et al. 2024

Electronics

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A novel unidirectional hybrid PFC rectifier topology based on SEPIC and boost converters is proposed, which is applicable to various industrial applications such as electric vehicle charging stations, variable speed AC drives, and energy storage systems. Compared to other rectifiers, the proposed SEPIC-boost-based rectifier exhibits continuous current on the AC side, lower voltage stress on the active switches, a wider range of DC output voltage, no auxiliary DC-DC converters, and a high step-up static voltage gain operating with low input voltage and a low step-up static gain for the high-input-voltage operation. These traits allow the SEPIC-boost-based rectifier to utilize smaller input-side harmonic filtering inductors and adopt active switches with lower voltage ratings, resulting in reduced conduction losses. Additionally, the proposed rectifier features power factor correction and high boost/buck voltage-gain capabilities, simplifying control for electric vehicle charging and expanding its range of applications. In this paper, the operating principle of the novel topology is presented first, and then the mathematical model of the proposed rectifier is built. Based on this, the comparison between the proposed topology and conventional boost and SEPIC converters is given. Furthermore, the control strategy, including the high-power-factor control and the balancing control to the DC capacitor voltages, is discussed. Finally, to validate the accuracy of the proposed rectifier’s theoretical research, a 500-W SEPIC-boost rectifier system has been constructed in the laboratory, generating a 200/120 Vdc output voltage from a 155 Vpk/50 Hz power source.

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Section: Mathematical Modelingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

SEPIC-Boost-Based Unidirectional PFC Rectifier with Wide Output Voltage Range

Cheng,

Li,

Wang

et al. 2024

Electronics

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A Single-Phase Seven-Level Inverter With Triple Boosting Ability

Vo,

Nguyen,

Duong

et al. 2023

2023 11th International Conference on Power Electronics and ECCE Asia (ICPE 2023 - ECCE Asia)

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Small-Signal Model of the NPC + GCC Multilevel Transformerless Inverter in Single-Phase Photovoltaic Power Systems

Patrao,

Liberos,

González-Medina

et al. 2023

Electronics

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Photovoltaic transformerless inverters are very efficient and economical options for solar-power generation. The absence of the isolation transformer improves the converters’ efficiency, but high-frequency voltage to ground can appear in the photovoltaic string poles. The high capacitance to ground of the photovoltaic generator leads to undesirable high-leakage currents. Using half-bridge topologies dramatically reduces the leakage to ground, and using a multilevel half-bridge inverters improves the output quality compared with classical inverters. The neutral point clamped + generation control circuit (NPC + GCC) topology is a multilevel single-phase transformerless inverter capable of tracking the maximum power point of two photovoltaic sources at the same time. This paper presents the control structure and the dynamic modeling of the NPC + GCC inverter. The pulse-width modulated (PWM) switch model in continuous conduction mode (CCM) was used to obtain the small-signal model of the two switching converters that make up the inverter. The resulting dynamic model was used to quantify the stability margins of both converters’ current and voltage loops.

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A Single-Stage Bimodal Transformerless Inverter with Common-Ground and Buck-Boost Features

Cited by 3 publications

References 33 publications

SEPIC-Boost-Based Unidirectional PFC Rectifier with Wide Output Voltage Range

SEPIC-Boost-Based Unidirectional PFC Rectifier with Wide Output Voltage Range

A Single-Phase Seven-Level Inverter With Triple Boosting Ability

Small-Signal Model of the NPC + GCC Multilevel Transformerless Inverter in Single-Phase Photovoltaic Power Systems

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