Shilin Guo scite author profile

A novel full-range soft-switching full-bridge (FSFB) cycloconvertertype high-frequency-link inverter (CHFLI) with active snubber network is proposed. By adding an auxiliary inductor in primaryside DC/AC converter and adopting centre-tapped transformer structure, the proposed FSFB-CHFLI achieves zero voltage switching (ZVS) for all switches under different operating conditions from light load to rated load, which benefits with high efficiency and high switching frequency. The secondary-side active snubber network is utilised to recycle leakage inductor energy and suppress voltage spikes caused by the resonance of the leakage inductor and the parasitic capacitance of switch. The commutation overlap strategy is adopted to guarantee complete ZVS turn-on and ZVS turn-off of bidirectional switches. Experimental results of a high efficient and high switching frequency (200 kHZ) prototype are presented to verify the analysis results of the proposed FSFB-CHFLI.

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Decentralised adaptive control design for single‐phase parallel‐inverter systems

Fan

Guo

Yang

et al. 2019

IET Renewable Power Generation

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Single-phase inverters are widely installed to integrate distributed generations into microgrids. To further improve the reliability and flexibility, several inverter modules connected in parallel are usually preferred. Besides achieving bus voltage regulation, another control objective of parallel-inverter systems is to guarantee load current sharing performance among multiple inverter modules. To attain these objectives in the presence of physical differences and uncertain system parameters, advanced control schemes are needed. In this study, a state-feedback decentralised adaptive control algorithm is firstly presented for single-phase parallel-inverter systems with unknown system parameters. Adaptive laws are designed to compensate for the uncertainties. In addition, the proposed control algorithm is decentralised in the sense that only local information is required for each inverter's controller. To overcome the practical problem that not all system states are available due to the presence of the unknown system parameters and load current, an output-feedback version of the decentralised adaptive controller is introduced through observers. The closed-loop system stability is proved via Lyapunov analysis. Finally, extensive simulation studies on parallel-inverter systems of different levels of detail are conducted to illustrate that the proposed control algorithm can provide satisfactory voltage regulation and current sharing performance under various loading conditions.

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Shilin Guo

A Consensus-Based Algorithm for Power Sharing and Voltage Regulation in DC Microgrids

Analytical Optimization of Nonsaturated Thermally Limited High-Frequency Transformer/Inductor Design Considering Discreteness of Design Variables

Properties and Synthesis of Lossless Snubbers and Passive Soft-Switching PWM Converters

High‐efficiency full‐range soft‐switching full‐bridge high‐frequency‐link inverter

Decentralised adaptive control design for single‐phase parallel‐inverter systems

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