A Novel Dead Time Design Method for Full-Bridge LLC Resonant Converters with SiC Semiconductors

Wang, Longxiang; Luo, Wenguang; Wang, Yuewu; Li, Hongli

doi:10.3390/pr11030973

Cited by 2 publications

(1 citation statement)

References 20 publications

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“…This is because a short-through phenomenon can occur if the dead time is reduced. Dynamic dead-time control has been proposed to increase the power conversion efficiency and expand the ZVS area compared with fixed dead-time control [19][20][21][22]. In general, a dynamic dead time means that under light load conditions the dead time would be extended to meet the ZVS conditions, for example (7).…”

Section: Proposed Practical Dead-time Control Methodologymentioning

confidence: 99%

Practical Dead-Time Control Methodology of a Three-Phase Dual Active Bridge Converter for a DC Grid System

Choi,

Ahn,

Jung

et al. 2023

Energies

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An effective dead-time control strategy for the three-phase dual active bridge (3P-DAB) converter of a distribution system is studied to reduce the switching losses of power switches and improve the under-light-load power conversion efficiency. Because of the advantages of a dual-active bridge converter, such as an inherent zero-voltage switching (ZVS) capability without any additional resonant tank and a seamless bi-directional power transition, this is an attractive topology for bi-directional application. The 3P-DAB converter is apt for high-power applications such as aircraft due to an interleaved structure, which can reduce conduction losses. However, the design of the dead time depends on engineering experience and empirical methods. In order to overcome the conventional practicality of the dead-time design method, the effective control of dead time is proposed based on the theoretical analysis. In this paper, the overall explanation of the 3P-DAB converter is shown with operation principles. In addition, the dead-time effect of the 3P-DAB converter is examined and the practical variable dead-time control strategy is studied. Finally, experimental results validate the proposed variable dead-time control strategy using a 25 kW prototype 3P-DAB converter.

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Section: Proposed Practical Dead-time Control Methodologymentioning

confidence: 99%

Practical Dead-Time Control Methodology of a Three-Phase Dual Active Bridge Converter for a DC Grid System

Choi,

Ahn,

Jung

et al. 2023

Energies

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Research on parallel control strategy of power converters based on fuzzy neural network

Sun,

Chen,

Zhou

et al. 2024

Proceedings of the Institution of Mechanical Engineers, Part D:

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As pure electric vehicles shift toward intelligent technology, the energy demand for onboard equipment is on the rise. In this study, a parallel control strategy for two 3-kW DC–DC power converters was proposed to meet the power requirements of pure electric vehicle loads in this paper. First, the operation mode of the resonant power converter was analyzed. The operation mode of the power converter adopted the advantageous frequency conversion–phase shift control mode. Second, a parallel control method for Takagi–Sugeno-type fuzzy neural network converters with four inputs and a single output first-order was designed to meet the power demand based on the advantages of fuzzy control and neural networks. The neural networks can be trained automatically based on the established requirements, and the fuzzy rules formulated through fuzzy neural networks were more detailed and accurate. Finally, the proposed control strategy was validated by experiments. The experimental results showed that the proposed control strategy can ensure the stable operation of the power converter during switching under the set load. The output power of the primary and sub converters varies linearly, which can meet the load’s demand for high power. There is no need to develop higher-power power converters. These results can provide a new idea for the research of high-power power converters and reduce development costs.

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A Novel Dead Time Design Method for Full-Bridge LLC Resonant Converters with SiC Semiconductors

Cited by 2 publications

References 20 publications

Practical Dead-Time Control Methodology of a Three-Phase Dual Active Bridge Converter for a DC Grid System

Practical Dead-Time Control Methodology of a Three-Phase Dual Active Bridge Converter for a DC Grid System

Research on parallel control strategy of power converters based on fuzzy neural network

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