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Erschienen in:
Design and Modeling of Fuel Cell Hybrid Electric Vehicle for Urban Transportation Kapitel lesen Erstes Kapitel lesen

2021 | OriginalPaper | Buchkapitel

Power Electronics—EV Battery Charging

verfasst von : Biswamoy Pal, Shib Sankar Saha, Papun Biswas

Erschienen in: Electric Vehicles

Verlag: Springer Singapore

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Abstract

Growing worldwide demand of electric vehicles (EV) to curtail air pollution and steep fuel price rise is drawing prime attention of EV manufacturers towards improving the performance of EV battery chargers. Modern EV chargers are intended to be small sized, lightweight, efficient and cost effective. Bidirectional chargers have the additional provisions of feeding the battery stored energy back to the grid to meet the power demand in peak hours. All EV battery chargers essentially use power electronic converters as the main power processing unit. Power electronic researchers are therefore trying to develop new topologies of power electronic converters to meet the demands of modern EV battery chargers. This chapter elaborates power system layouts of EV battery charging systems, different categories of power electronic converters for such applications and working principles of basic power electronic converters. At last, several new topologies of recently developed power converters with many of the features mentioned above have been presented and explained briefly.

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Vorheriges Kapitel Plug-In Hybrid Electric Vehicles (PHEVs)
Nächstes Kapitel An Overview of Solar-Powered Electric Vehicle Charging in Vehicular Adhoc Network
Literatur
1.
G.J. Henry, G.W. Heinke, Environmental Science and Engineering London (Prentice-Hall International 1996)
2.
P.D. Bailey, modelling future vehicle exhaust emissions in Europe, Water, Air and Soil Pollution, vol. 85 (Kluwer Academic Publishers, printed in the Netherlands, 1995), pp. 1879–1884
3.
Lilley, A New Approach to Emissions Inventory Modelling; Assessing Fuel And Vehicle Impacts on Air Quality, Air Pollution, vol. 3, pp. 389–398 (2000)
4.
U.M. Netravati, V.C. Patil, T.M. Veeragangadhar Swamy, S. Goud, vehicular pollution in india and solution. Int. J. Disaster Recovery Bus. Continuity 11(1), 1010–1014 (2020)
5.
J.Y. Yong, V.K. Ramachandaramurthy, K.M. Tan, N. Mithulananthan, A review on the state-of-the-art Technologies of electric vehicle, its impacts and prospects. Renew. Sustain. Energy Rev. 49, 365–385 (2015)CrossRef
6.
C.C. Chan, The state of the art of electric and hybrid vehicles. Proc. IEEE 90, 247–275 (2002)CrossRef
7.
O.M.F. Camacho, P.B. Nørgård, N. Rao, L. Mihet-Popa, Electrical vehicle batteries testing in a distribution network using sustainable energy. IEEE Trans. Smart Grid. 5, 1033–1042 (2014)CrossRef
8.
A. Khaligh, Z. Li, Battery, ultracapacitor, fuel cell, and hybrid energy storage systems for electric, hybrid electric, fuel cell, and plug-in hybrid electric vehicles: State of the art. IEEE Trans. Veh. Technol. 59, 2806–2814 (2010)CrossRef
9.
H.J. Chiu, L.W. Lin, A bidirectional DC–DC converter for fuel cell electric vehicle driving system. IEEE Trans. Power Electron. 21, 950–958 (2006)CrossRef
10.
Y. Gao, M. Ehsani, J.M. Mille, Hybrid electric vehicle: overview and state of the art, in Proceedings of the IEEE International Symposium on Industrial Electronics, Dubrovnik, Croatia, 20‒23 June 2005, pp. 307–316
11.
S.S. Williamson, A.K. Rathore, F. Musavi, Industrial electronics for electric transportation: Current state of- The-art and future challenges. IEEE Trans. Ind. Electron. 62, 3021–3032 (2015)CrossRef
12.
P.A. Cassani, S.S. Williamson, Feasibility analysis of a novel cell equalizer topology for plug-in hybrid electric vehicle energy-storage systems. IEEE Trans. Veh. Technol. 58, 3938–3946 (2009)CrossRef
13.
A.C. Baughman, M. Ferdowsi, Double-tiered switched-capacitor battery charge equalization technique. IEEE Trans. Ind. Electron. 55, 2277–2285 (2008)CrossRef
14.
K. Nishijima, H. Sakamoto, K. Harada, A PWM controlled simple and high performance battery balancing System, in Proceedings of the IEEE Power Electronics Specialists Conference, Galway, Ireland, vol. 1 (2000), pp. 517–520
15.
P.A. Cassani, S.S. Williamson, Design, testing, and validation of a simplified control scheme for a novel plug-in hybrid electric vehicle battery cell equalizer. IEEE Trans. Ind. Electron. 57, 3956–3962 (2010)CrossRef
16.
Y.S. Lee, M.W. Cheng, Intelligent control battery equalization for series connected lithium-ion battery Strings. IEEE Trans. Ind. Electron. 52, 1297–1307 (2005)CrossRef
17.
Y.S. Lee, M.W. Cheng, S.C. Yang, C.L. Hsu, Individual cell equalization for series connected lithium-ion batteries. IEICE Trans. Commun. E89-B, 2596–2607 (2006)CrossRef
18.
E.A. Grunditz, T. Thiringer, Performance analysis of current BEVs based on a comprehensive review of specifications. IEEE Trans. Transp. Electr. 2, 270–289 (2016)CrossRef
19.
H. Shareef, M.M. Islam, A. Mohamed, A review of the stage-of-the-art charging technologies, placement methodologies, and impacts of electric vehicles. Renew. Sustain. Energy Rev. 64, 403–420 (2016)CrossRef
20.
K. Itani, A.D. Bernardinis, Z. Khatir, A. Jammal, M. Oueidat, Regenerative braking modeling, control, and simulation of a hybrid energy storage system for an electric vehicle in extreme conditions. IEEE Trans. Trans. Electrification. 2 (2016)
21.
C. Li, Y. Zhang, Z. Cao, D. XU, Single-phase single-stage isolated ZCS current-fed full-bridge converter for high power AC/DC applications. IEEE Trans. Power Electron. (2016)
22.
C.H. Chang, C.A. Cheng, E.C. Chang, H.L. Cheng, B.E Yang, An integrated high-power-factor converter with ZVS transition. IEEE Trans. Power Electron. (2015)
23.
H.N. Kutkut, D.M. Divan, D.W. Novotny, R.H. Marion, Design Considerations and Topology Selection for a 120-kW IGBT Converter for EV Fast Charging. IEEE Trans. on power Electron. 13 (1998)
24.
S. Ratanapanachote, H.J. Cha, P.N. Enjeti, A Digitally Controlled Switch Mode Power Supply Based on Matrix Converter. IEEE Trans. on power Electron. 21 (2006)
25.
T. Mishima, K. Akamatsu, M. Nakaoka, A high frequency-link secondary-side phase-shifted full-range soft-switching PWM DC–DC converter with ZCS active rectifier for EV battery chargers. IEEE Trans. on power Electron. 28 (2013)
26.
J, Deng, S. Li, S. Hu, C.C. Mi, R.Ma, Design methodology of LLC resonant converters for electric vehicle battery chargers. IEEE Trans. vehicular Technol. 63 (2014)
27.
C. Wang, M. Xu, F.C. Lee, B. Lu, EMI Study for the Interleaved Multi-Channel PFC, in Proceedings of the IEEE Power Electronics Specialists Conference (PESC), (Orlando, FL, USA, 2007), pp. 1336–1342
28.
D.S. Gautam, F. Musavi, W. Eberle, W.G. Dunford, A zero voltage switching full-bridge dc-dc converter with capacitive output filter for a plug-in-hybrid electric vehicle battery charger, in Proceedings of the IEEE Applied Power Electronics Conference and Exposition (Orlando, FL, USA, 2012), pp. 1381–1386
29.
F. Musavi, M. Craciun, D.S. Gautam, W. Eberle, W.G. Dunford, An LLC resonant DC-DC Converter for wide output voltage range battery charging applications. IEEE Trans. Power Electron. 28, 5437–5445 (2013)CrossRef
30.
Y. Gurkaynak, Z.M. Li, A. Khaligh, A novel grid-tied, solar powered residential home with plug-in hybrid electric vehicle (PHEV) loads, in Proceedings of the 5th Annual IEEE Vehicle Power and Propulsion Conference, (Dearborn, MI, USA, 2009), pp. 813–816
31.
O. Onar, Bi-Directional Rectifier/Inverter and Bi-Directional DC/DC Converters Integration for Plug-in Hybrid Electric Vehicles with Hybrid Battery/Ultra-capacitors Energy Storage Systems (Illinois Institute of Technology, Chicago, IL, USA, 2009)
32.
M.H. Rashid, Power Electronics Handbook: Devices, Circuits and Applications (Elsevier, Amsterdam, The Netherlands, 2010)
33.
B. Koushki, A. Safaee, P. Jain, A. Bakhshai, Review and comparison of bi-directional AC-DC converters with V2G capability for on-board EV and HEV, in Proceedings of the 2014 IEEE Transportation Electrification Conference and Expo (ITEC) (Dearborn, MI, USA, 2014)
34.
J. G. Pinto, Vítor Monteiro, H. Gonçalves, J.L. Afonso, Onboard Reconfigurable Battery Charger for Electric Vehicles With Traction-to-Auxiliary Mode, IEEE trans. Vehicular Technol. 63 (2014)
35.
H.S. Krishnamoorthy, P. Garg, P.N. Enjeti, A matrix converter-based topology for high power electric vehicle battery charging and V2G application
36.
L. Yao, W.H. Lim, T.S. Tsai, A real-time charging scheme for demand response in electric vehicle parking station. IEEE Trans. Smart Grid 8, 52–62 (2017)CrossRef
37.
L. Kütt, E. Saarijärvi, M. Lehtonen, H. Mõlder, J. Niitsoo, A review of the harmonic and unbalance effects in electrical distribution networks due to EV charging, in Proceedings of the 2013 12th International Conference on Environment and Electrical Engineering (EEEIC) (Wroclaw, Poland, 2013)
38.
P. Richardson, D. Flynn, A. Keane, Optimal charging of electric vehicles in low-voltage distribution systems. IEEE Trans. Power Syst. 27, 268–279 (2012)CrossRef
39.
F. Mwasilu, J.J. Justo, E.K. Kim, T.D. Do, J.W. Jung, Electric vehicles and smart grid interaction: a review on vehicle to grid and renewable energy sources integration. Renew. Sustain. Energy Rev. 34, 501–516 (2014)CrossRef
40.
B. Geng, J.K. Mills, D. Sun, Two-stage charging strategy for plug-in electric vehicles at the residential transformer level. IEEE Trans. Smart Grid 4, 1442–1452 (2013)CrossRef
41.
U.R. Prasanna, A.K. Singh, K. Rajashekara, Novel bidirectional single-phase single-stageisolated AC-DC converter with PFC forcharging of electric vehicles. IEEE Trans. Transp. Electrification (2017)
42.
L. Yang, B. Lu, W. Dong, Z. Lu, M. Xu, F.C. Lee, W.G. Odendaal, Modeling and characterization of a 1KW CCM PFC converter for conducted EMI Prediction, in IEEE Applied Power Electronics Conference and Exposition, APEC, vol. 2, (2004), pp. 763–69
43.
C. L. Sirio, Analysis of line current harmonics for single-phase PFC converters, in IEEE Power Electronics Specialists Conference, (2007), pp. 1291–1297
44.
D. Xu, J. Zhang, W. Chen, J. Lin, F.C. Lee, Evaluation of output filter capacitor current ripples in single phase PFC converters, in Proceedings of the Power Conversion Conference, PCC. vol. 3 (Osaka, Japan, 2002), pp. 1226–1231
45.
D. Mitchell, AC–DC converter having an improved power factor, United States Patent # 4,412,277 (1983)
46.
U. Moriconi, A bridgeless PFC configuration based on L4981 PFC Controller, STMicroelectronics Application Note AN1606, (2002)
47.
W.Y. Choi, J.M. Kwon, E.H. Kim, J.J. Lee, B.H. Kwon, Bridgeless boost rectifier with low conduction losses and reduced diode reverse-recovery problems. IEEE Trans. Ind. Electron. 54, 769–780 (2007)
48.
J. M. Hancock, Bridgeless PFC boosts low-line efficiency, infineon technologies (2008)
49.
L. Huber, Y. Jang, M.M. Jovanovic, Performance evaluation of bridgeless PFC boost rectifiers. IEEE Trans. Power Electron. 23, 1381–1390 (2008)CrossRef
50.
F. Musavi, W. Eberle, W.G. Dunford, A high-performance singlephase ac-dc power factor corrected boost converter for plug in hybrid electric vehicle battery chargers, in IEEE Energy Conversion Congress and Exposition, (ECCE, Atlanta, Georgia, 2010)
51.
P. Nayak, S.K. Pramanick, K. Rajashekara, Isolated single stage AC-DC converter topologies with regenerative snubber circuit for EV application, in IECON 2018 - 44th Annual Conference of the IEEE Industrial Electronics Society (2018)
52.
C.M. Wang, A Novel ZCS-PWM flyback converter with a simple ZCS-PWM commutation cell. IEEE Trans. Ind. Electron. 55 (2008)
53.
K.S. Muhammad, D.D.C Lu, Single-phase single-stage ZCS boost PFC rectifier with reduced switch count, in Australasian Universities Power Engineering Conference, AUPEC 2014, (Curtin University, Perth, Australia, 2014)
Metadaten
Titel
Power Electronics—EV Battery Charging
verfasst von
Biswamoy Pal
Shib Sankar Saha
Papun Biswas
Copyright-Jahr
2021
Verlag
Springer Singapore
Buch
Electric Vehicles

Print ISBN: 978-981-15-9250-8

Electronic ISBN: 978-981-15-9251-5

Copyright-Jahr: 2021

DOI
https://doi.org/10.1007/978-981-15-9251-5_4