Power flow control of a triple active bridge DC-DC converter using GaN power devices for a low-voltage DC power distribution system

Yu, Yue; Masumoto, Keisuke; Wãda, Keiji; Kado, Yuichi

doi:10.1109/ifeec.2017.7992137

Cited by 16 publications

(1 citation statement)

References 13 publications

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“…A triple-active bridge-based DC energy router (TAB-DCER) can interconnect three adjacent DC microgrids and achieve a reasonable distribution of energy among multiple DC microgrids. A TAB-DCER can also be used to realize a flexible coordination of renewable energy and storage across regions and further realize complementary energy support [3][4][5]. Figure 1 presents a schematic diagram of the structure of an interconnected multiple DC microgrid system based on a TAB-DCER.…”

Section: Introductionmentioning

confidence: 99%

An Efficiency Improvement Strategy for Triple-Active-Bridge-Based DC Energy Routers in DC Microgrids

Meng,

Duan,

Sha

et al. 2024

Electronics

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A triple-active bridge (TAB) can be used as a power conversion unit in a three-port DC energy router (DCER) such as a triple-active bridge-based DC energy router (TAB-DCER). The operational loss of a TAB can be seen as a key factor affecting the efficiency of a TAB-DCER. However, the RMS value of the inductor current of the TAB-DCER increases under single-phase shift (SPS) control, and this greatly increases the system operating losses. The use of phase-shifted plus PWM (PS-PWM) control can reduce the RMS value of the inductor current, but its mathematical model is complex, and involves difficult calculations. To address this problem, in the study reported here, we developed an optimal control strategy for the RMS value of the inductor current based on TAB-DCER. First, the working principle of a TAB-DCER under PS-PWM control was analyzed, and a circuit decomposition model was established. Second, the operating modes under PS-PWM control were analyzed, and corresponding expressions of port power and the RMS value of the inductor current were obtained. Third, an optimized mathematical model of the sum of squares of the RMS value of the inductor current of the TAB-DCER was constructed. Finally, a genetic algorithm was used to solve the mathematical model and derive the optimal phase shift angle; this resulted in a lower RMS value of the inductor current in the TAB-DCER and reduced the system operating losses. The simulation and experimental results show that the TAB-DCER used in the present study can reduce operating losses, improve system efficiency, and deliver coordinated power control.

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Section: Introductionmentioning

confidence: 99%