Design of bidirectional power converters coupled with coils for wireless charging of AUV docking systems

The docking station is usually deployed at seafloor as a charging node to enhance the endurance of autonomous underwater vehicles (AUVs). However, for deep-sea observation requirements, it is nearly unaffordable to deploy extremely long cables to provide power for docking stations. Therefore, this p...

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Veröffentlicht in:	Journal of marine science and technology 2022-06, Vol.27 (2), p.873-886
Hauptverfasser:	Lin, Mingwei, Zhang, Feng, Yang, Canjun, Li, Dejun, Lin, Ri
Format:	Artikel
Sprache:	eng
Schlagworte:	Automotive Engineering Autonomous underwater vehicles Cables Coils Current loss Deep sea Deep water Docking Eddy current testing Eddy currents Engineering Engineering Design Engineering Fluid Dynamics Flow control Mechanical Engineering Ocean floor Offshore Engineering Original Article Power converters Power flow Prototypes Remote submersibles Sea-water Seawater Underwater vehicles Wireless power transmission
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container_title	Journal of marine science and technology
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creator	Lin, Mingwei Zhang, Feng Yang, Canjun Li, Dejun Lin, Ri
description	The docking station is usually deployed at seafloor as a charging node to enhance the endurance of autonomous underwater vehicles (AUVs). However, for deep-sea observation requirements, it is nearly unaffordable to deploy extremely long cables to provide power for docking stations. Therefore, this paper proposes a possible power-supply solution by developing an underwater bidirectional wireless power transmission (UBWPT) system. To improve the efficiency of the UBWPT system in underwater scenarios, the power converters coupled with coils is designed by analyzing the eddy current loss and parasitic jumper capacitor in seawater. Additionally, two independent controllers are developed for the transmitting and receiving converters to achieve power flow control underwater. The effectiveness of the bidirectional power converters is verified by developing a 51-W charging prototype system, which improves the system efficiency by 3% in simulated seawater.
doi_str_mv	10.1007/s00773-022-00877-7
format	Article
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subjects	Automotive Engineering Autonomous underwater vehicles Cables Coils Current loss Deep sea Deep water Docking Eddy current testing Eddy currents Engineering Engineering Design Engineering Fluid Dynamics Flow control Mechanical Engineering Ocean floor Offshore Engineering Original Article Power converters Power flow Prototypes Remote submersibles Sea-water Seawater Underwater vehicles Wireless power transmission
title	Design of bidirectional power converters coupled with coils for wireless charging of AUV docking systems
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