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2024 | OriginalPaper | Buchkapitel

Modified Multi-inductor-Based Cell Balancing in Electric Vehicles

verfasst von : Utsab Bhattacharya, Pradeep Kumar

Erschienen in: Recent Advances in Power Electronics and Drives

Verlag: Springer Nature Singapore

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Abstract

Cell balancing is an essential feature of battery management systems as the battery packs are affected by various factors, and imbalance is one of the major ones. Without balance, the cell's performance will drift apart, and much energy will be wasted in the battery pack when they are frequently operated in recycling conditions. Different methodologies for cell balancing have been proposed so far, which must be adequately applied considering the application of the battery pack. This paper presents a modified simple inductor-based active cell balancing technique in Electric Vehicles. The cell equalization topology has been simulated in MATLAB/Simulink. The performance is evaluated using the quantification of energy exchange. The results show that the proposed approach transfers energy in less time, with lower losses. Also, the design complexity is less.

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Vorheriges Kapitel Grid-Integrated EV Charging Infrastructure

Nächstes Kapitel Design and Hardware Implementation of Fuzzy Logic Controller for Boost Converter for Battery Charging Using dSPACE

Zhang JB, Lu LG, Li Z (2012) Key technologies and fundamental academic issues for traction battery system. J Autom Saf Energy 3(2):87–104

Wu J, Emadi A, Duoba MJ, Bohn TP (2007) Plug-in hybrid electric vehicles: testing, simulations, and analysis, pp 469–476

Bruno Scrosati JG (2010) Lithium batteries: status, prospects and future. J Power Sources 195(9):2419–2430

Aizpuru I, Iraola U, Canales JM, Unamuno E, Gil I (2013) Battery pack tests to detect unbalancing effects in series connected Li-ion cells. In: 2013 International Conference on Clean Electrical Power (ICCEP), pp 99–106

Dubarry M, Devie A, Liaw BY (2016) Cell-balancing currents in parallel strings of a battery system. J Power Sources 321:36–46CrossRef

Qi G, Li X, Yang D (2014) A control strategy for dynamic balancing of lithium iron phosphate battery based on the performance of cell voltage. In: IEEE transportation electrification conference and expo, ITEC Asia-Pacific 2014 - conference proceedings, vol 1, pp 1–5

Cao J, Schofield N, Emadi A (2008) Battery balancing methods: a comprehensive review. In: Vehicle Power and Propulsion Conference. VPPC’08. IEEE, pp 1–6

Bowkett M, Thanapalan K, Stockley T, Hathway M, Williams J (2013) Design and implementation of an optimal battery management system for hybrid electric vehicles. In: Proceedings of the 19th international conference on automation & computing

Xu J, Li S, Mi C, Chen Z, Cao B (2013) SOC based battery cell balancing with a novel topology and reduced component count. Energies 6:2726–2740CrossRef

10.

Carpinelli G, Mottola F, Proto D, Varilone P (2017) Minimizing unbalances in low-voltage microgrids: optimal scheduling of distributed resources. Appl Energy 191:170–182CrossRef

11.

Han W, Zhang L (2018) Battery cell reconfiguration to expedite charge equalization in series-connected battery systems. IEEE Robot Autom Lett 3(1):22–28CrossRef

12.

Orcioni S, Ricci A, Buccolini L, Scavongelli C, Conti M (2017) Effects of the variability of the characteristics of a single cell on the performance of a lithium-ion battery pack. In: 2017 13th workshop on intelligent solutions in embedded systems WISES 2017, pp 15–21

13.

Samadi MF, Saif M (2014) Nonlinear model predictive control for cell balancing in li-ion battery packs. In: 2014 American Control Conference (ACC), pp 2924–2929

14.

Cui X, Shen W, Zhang Y, Hu C, Zheng J (2017) Novel active LiFePO4 battery balancing method based on chargeable and dischargeable capacity. Comput Chem Eng 97:27–35CrossRef

15.

Campbell ID, Gopalakrishnan K, Marinescu M, Torchio M, Offer GJ, Raimondo D (2019) Optimising lithium-ion cell design for plug-in hybrid and battery electric vehicles. J Energy Storage 22:228–238CrossRef

16.

Ur Rehman MM et al (2014) Modular approach for continuous cell level balancing to improve performance of large battery packs. In: 2014 IEEE Energy Conversion Congress and Exposition, ECCE 2014, pp 4327–4334

17.

Anderson RD, Zane R, Plett G, Maksimovic D, Smith K, Trimboli MS (2017) Life balancing – a better way to balance large batteries. SAE Tech Pap Ser 1:4–6

18.

Oeser D, Ziegler A, Ackva A (2018) Single-cell analysis of lithium-ion e-bike batteries aged under various conditions. J Power Sources 397:25–31CrossRef

19.

Schneider PJ, Moore SW (2001) A review of cell equalization methods for lithium ion and lithium polymer battery systems. In: SAE 2001 world congress

20.

Lindemark B (1991) Individual Cell voltage Equalizers (ICE) For reliable battery performance. In: IEEE 13th International Telecommunications Energy Conference, INTELEC’91, pp 196–201

21.

Moore S, Schneider P (2001) A review of cell equalization methods for lithium ion and lithium polymer battery systems. In: Proceedings of the SAE 2001 world congress

22.

Stuart AT, Zhu W (2009) Fast equalization for large lithium ion batteries. IEEE Aerosp Electron Syst Mag 24:27–31CrossRef

23.

Cadar DV, Petreus DM, Patarau TM (2010) An energy converter method for battery cell balancing.In: IEEE 33rd International Spring Seminar on Electronics technology (ISSE), pp 290–293

24.

Daowd M, Omar N, Van Den Bossche P, Van Mierlo J (2011) Passive and active battery balancing comparison based on MATLAB simulation, pp 1–7

25.

Lin JCM (2017) Development of a new battery management system with an independent balance module for electrical motorcycles. Energies 10(1289)

26.

Wen S (2009) Cell balancing buys extra run time and battery life. Analog Appl 14–18

27.

Imtiaz AM, Khan FH, Kamath H (2011) A low-cost time shared cell balancing technique for future lithium-ion battery storage system featuring regenerative energy distribution. In: IEEE 26th annual Applied Power Electronics Conference and exposition (APEC), pp 792–799

28.

Kutkut NH, Divan DM (1996) Dynamic equalization techniques for series battery stacks, pp 514–521

29.

Jonathan Carter JC, Fan Z (2020) Cell equalisation circuits: a review. J Power Sources 448

30.

Sang-Hyun P, Tae-Sung K, Jin-Sik P, Gun-Woo M, Myung-Joong Y (2007) A new battery equalizer based on buck-boost topology. In: IEEE 7th international conference on power electronics, pp 962–965

31.

Park S, Kim T-S, Park J-S, Moon G-W, Yoon M-J (2007) A new battery equalizer based on buck-boost topology, pp 962–965

32.

Phung TH, Crebier J, Chureau A, Collet A, Nguyen V (2011) Optimized structure for next-to-next balancing of series-connected lithium-ion cells, pp 1374–1381

33.

West S, Krein PT (2000) Switched-capacitor systems for battery equalization. In: IEEE Modern Techniques and Technology (MTT 2000). Proceedings of the VI International scientific and practical conference of students, post-graduates and young scientists, pp 57–59

34.

Pascual C, Krein PT (1997) Switched capacitor system for automatic series battery equalization, vol 2, pp 848–854

35.

Baughman AC, Ferdowsi M (2008) Double-tiered switched-capacitor battery charge equalization technique. IEEE Trans Ind Electron 55:2277–2285CrossRef

36.

Baughman A, Ferdowsi M (2005) Double-tiered capacitive shuttling method for balancing series connected batteries, pp 109–113

37.

Siqi L, Mi CC, Mengyang Z (2013) A high-efficiency active battery-balancing circuit using multiwinding transformer. IEEE Trans Ind Appl 49:198–207CrossRef

38.

Cadar D et al (2010) An energy converter method for battery cell balancing. In: 33rd International Spring Seminar on Electronics technology, ISSE 2010, pp 290–293

39.

Einhorn M, Roessler W, Fleig J (2011) Improved performance of serially connected li-ion batteries with active cell balancing in electric vehicles. IEEE Trans Veh Technol xx(99):1–10

40.

Parky K-H, Kim C-H, Cho H-K, Seo J-K (2010) Design considerations of a lithium ion Battery Management System (BMS) for the STSAT-3 satellite. J Power Electron 10(2):210–217CrossRef

41.

Chakraborty S, Jain AK, Mohan N (2004) Novel converter topology and algorithm for simultaneous charging and individual cell balancing of multiple li-ion batteries. In: 26th annual international telecommunications energy conference, pp 248–253

42.

Chol-Ho K, Moon-young K, Hong-sun P, Gun-Woo M (2012) A modularized two-stage charge equalizer with cell selection switches for series-connected lithium-ion battery string in an HEV. IEEE Trans Power Electron 27:3764–3774CrossRef

43.

Einhorn M, Guertlschmid W, Blochberger T, Kumpusch R, Permann R, Conte FV et al (2011) A current equalization method for serially connected battery cells using a single power converter for each cell. IEEE Trans Veh Technol 60:4227–4237CrossRef

44.

Caspar M, Eiler T, Hohmann S (2018) Systematic comparison of active balancing: a model-based quantitative analysis. IEEE Trans Veh Technol 67(2):920–934CrossRef

45.

Narayanaswamy S et al (2017) Modular active charge balancing for scalable battery packs. IEEE Trans Very Large-Scale Integr (VLSI) Syst 25(3):974–987

46.

Moghaddam AF, Van den Bossche A (2019) An efficient equalizing method for lithium-ion batteries based on coupled inductor balancing. Electronics 8(2):136. https://doi.org/10.3390/electronics8020136

47.

Liu X, Wan Z, He Y, Zheng X, Zeng G, Zhang J (2018) A unified control strategy for inductor-based active battery equalisation schemes. Energies 11(2):405. https://doi.org/10.3390/en11020405

Titel: Modified Multi-inductor-Based Cell Balancing in Electric Vehicles
verfasst von: Utsab Bhattacharya
Pradeep Kumar
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_22