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2024 | OriginalPaper | Buchkapitel

Comprehensive Analyses of Control Techniques in Dual Active Bridge DC–DC Converter for G2V Operations

verfasst von : Sudipta Baidya, Akanksha Shukla

Erschienen in: Recent Advances in Power Electronics and Drives

Verlag: Springer Nature Singapore

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Abstract

Power conversion via high-frequency link (HFL) using DC–DC converters is gaining gradual popularity in Electric Vehicles (EVs) and the power sector due to their high power density, lightweight, cost-effectiveness, and reliability without conciliatory efficiency. One such promising DC–DC converter that combines bidirectional ability with energy storage and isolation is the dual active bridge (DAB). This paper presents the outcome of various control methodologies on the peak inductor current, primary and secondary side voltage of the HF transformer, and output power of a DAB converter. This converter regulates power flow in both directions by employing phase shift techniques. The traditional control techniques can be categorized as single-phase shift (SPS), dual-phase shift (DPS), and triple-phase shift (TPS). Closed-loop controlling and simulation results for all three control techniques are presented here along with a comparative analysis. It is observed that with an increase in the degree of freedom of control, both peak inductor current and switching stress reduce. As the degree of control increases, so does the overall performance of the DAB converter.

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Vorheriges Kapitel A Generalized Symmetrical and Asymmetrical Multilevel Inverter Topology with Reduced Number of Components

Nächstes Kapitel DBSCAN-Based Cascaded Inductively Coupled DSTATCOM for PQ Improvement

Corti F et al (2022) Comparison of control strategies for dual active bridge converter. In: 2022 IEEE 21st Mediterranean Electrotechnical Conference (MELECON). IEEE

Chen L et al (2020) Predictive control based DC microgrid stabilization with the dual active bridge converter. IEEE Trans Ind Electron 67(10):8944–8956

Xuan Y et al (2019) A three-level dual-active-bridge converter with blocking capacitors for bidirectional electric vehicle charger. IEEE Access 7:173838–173847

Jiang C, Liu H (2020) A novel interleaved parallel bidirectional dual-active-bridge DC–DC converter with coupled inductor for more-electric aircraft. IEEE Trans Ind Electron 68(2):1759–1768CrossRef

Xiao Q et al (2019) Model predictive control for dual active bridge in naval DC microgrids supplying pulsed power loads featuring fast transition and online transformer current minimization. IEEE Trans Ind Electron 67(6):5197–5203

Emadi, Lee YJ, Rajashekara K (2008) Power electronics and motor drives in electric, hybrid electric, and plug-in hybrid electric vehicles. IEEE Trans Ind Electron 55(6):2237–2245

Doncker RWD, Divan DM, Kheraluwala MH (1988) A three-phase soft-switched high power density dc/dc converter for high power applications. In: Conference record of the 1988 ieee industry applications society annual meeting, October 1988, vol 1, pp 796–805

Mi C, Bai H, Wang C, Gargies S (2008) Operation, design and control of dual h-bridge-based isolated bidirectional dc-dc converter. IET Power Electron 1(4):507–517CrossRef

Shao S et al (2019) Optimal phase-shift control to minimize reactive power for a dual active bridge DC–DC converter. IEEE Trans Power Electron 34(10):10193–10205

10.

Friedemann RA, Krismer F, Kolar JW (2012) Design of a minimum weight dual active bridge converter for an airborne wind turbine system. In: 2012 twenty-seventh annual IEEE Applied Power Electronics Conference and exposition (APEC), pp 509–516. IEEE

11.

Everts J et al (2013) Optimal ZVS modulation of single-phase single-stage bidirectional DAB AC–DC converters. IEEE Trans Power Electron 29(8):3954–3970

12.

Hu J et al (2020) Generic dynamic phase-shift control for bidirectional dual-active bridge converters. IEEE Trans Power Electron 36(6):6197–6202

13.

Bindi M et al (2021) Comparison between pi and neural network controller for dual active bridge converter. In: 2021 IEEE 15th international conference on Compatibility, Power Electronics and Power Engineering (CPE-POWERENG). IEEE

14.

Shi H, Wen H, Chen J, Hu Y, Jiang L, Chen G (2017) Minimum reactive-power scheme of dual-active-bridge dc-dc converter with three level modulated phase-shift control. IEEE Trans Ind Appl 53(6):5573–5586CrossRef

15.

Zhao B, Song Q, Liu W (2012) Power characterization of isolated bidirectional dual-active-bridge dc-dc converter with dual-phase-shift control. IEEE Trans Power Electron 27(9):4172–4176CrossRef

16.

Huang J, Wang Y, Li Z, Lei W (2016) Unified triple-phase-shift control to minimize current stress and achieve full soft-switching of isolated bidirectional dc-dc converter. IEEE Trans Ind Electron 63(7):4169–4179CrossRef

17.

Hou N, Song W, Wu M (2016) Minimum-current-stress scheme of dual active bridge dc-dc converter with unified phase-shift control. IEEE Trans Power Electron 31(12):8552–8561

18.

Tong A, Hang L, Li G, Jiang X, Gao S (2018) Modeling and analysis of a dual-active-bridge-isolated bidirectional dc/dc converter to minimize RMS current with whole operating range. IEEE Trans Power Electron 33(6):5302–5316CrossRef

19.

Qin H, Kimball JW (2012) Generalized average modeling of dual active bridge DC–DC converter. IEEE Trans Power Electron 27(4):2078–2084CrossRef

20.

Zhao B et al (2013) Overview of dual-active-bridge isolated bidirectional DC–DC converter for high-frequency-link power-conversion system. IEEE Trans Power Electron 29(8):4091–4106

21.

Tiwari S, Sarangi S (2019) Implementation of SPS and DPS control techniques on DAB converter with comparative analysis. J Inf Optim Sci 40(8):1623–1638MathSciNet

22.

Ramakrishnan H (2019) Bi-directional, dual active bridge reference design for level 3 electric vehicle charging stations. Design Guide, June 2019

23.

Bai H, Mi C (2008) Eliminate reactive power and increase system efficiency of isolated bidirectional dual-active-bridge DC–DC converters using novel dual-phase-shift control. IEEE Trans Power Electron 23(6):2905–2914CrossRef

24.

Zhao B et al (2015) Universal high-frequency-link characterization and practical fundamental-optimal strategy for dual-active-bridge DC-DC converter under PWM plus phase-shift control. IEEE Trans Power Electron 30(12):6488–6494

Titel: Comprehensive Analyses of Control Techniques in Dual Active Bridge DC–DC Converter for G2V Operations
verfasst von: Sudipta Baidya
Akanksha Shukla
Verlag: Springer Nature Singapore
Buch: Recent Advances in Power Electronics and Drives
Print ISBN: 978-981-9994-38-0

Electronic ISBN: 978-981-9994-39-7

Copyright-Jahr: 2024
DOI: https://doi.org/10.1007/978-981-99-9439-7_11