Top

Hint

Swipe to navigate through the chapters of this book

Published in:

Read chapter Read first chapter

2021 | OriginalPaper | Chapter

Energy Storage: Ultracapacitor

Author : Andrew Burke

Published in: Electric, Hybrid, and Fuel Cell Vehicles

Publisher: Springer New York

Excerpt

Battery

a cell in which electrical energy is stored and discharged via Faradaic electrochemical reactions occurring at a predetermined voltage dependent on the active materials in the two electrodes

Supercapacitor (electrochemical capacitor)

a device in which electrical energy is stored and discharged via the electrostatic separation of charge in the micropores of activated carbon in two electrodes

Hybrid-electric vehicle (HEV)

a vehicle having both an electric motor and internal combustion engine in which the battery is maintained near a fixed state-of-charge via electrical energy generated by the electric motor/generator driven by the engine

Plug-in electric hybrid vehicle (PHEV)

a vehicle having both an electric motor and internal combustion engine in which the battery is depleted by all-electric driving and recharged from the wall-plug

Pulse power efficiency

the fraction of the discharge or charge energy from the battery or supercapacitor during a short, high-power pulse that is available as electrical energy for use by the vehicle

Control (power split) strategy

the strategy used in a hybrid-electric vehicle to determine the fraction of the power demanded that is provided by the electric motor and engine, respectively

Vehicle simulations

computer calculations of the operation of a vehicle based on models of the various components in the driveline of the vehicle and a specified control strategy for its operation

…

To get access to this content you need the following product:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 69.000 Bücher
über 500 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt 90 Tage mit der neuen Mini-Lizenz testen!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 50.000 Bücher
über 380 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt 90 Tage mit der neuen Mini-Lizenz testen!

inform now

previous chapter Lithium-Ion Batteries for Automotive Applications: Life Cycle Analysis

next chapter Regenerative Braking

Burke AF, Miller M (2009) Performance characteristics of Lithium-ion batteries of various chemistries for plug-in hybrid vehicles, EVS-24, Stavanger, May 2009 (paper on the CD of the meeting)

Burke AF, Park J (2018) Battery and supercapacitor energy storage systems for PHEVs. In: Presented at AABC USA, San Diego, June 2018

Burke AF (2018) Electrochemical capacitors. In: Handbook of batteries, 5 th edn. Chap. 20, McGraw-Hill, United States, 2019

Burke AF, Park J (2018) Tests of state-of-the art supercapacitors using aqueous and organic electrolytes. In: Presented at AABC Europe, Mainz, Jan 2018

Burke AF, Miller M (2011) The power capability of supercapacitors and lithium batteries for electric and hybrid vehicle applications. J Power Sources 196(1):514–522 CrossRef

Zhao J, Gao Y, Burke AF (2017) Performance testing of supercapacitors: important issues and uncertainties. J Power Sources 363:1–14 CrossRef

Burke AF, Kumar A (2019) Comparison of the power characteristics of lithium batteries and supercapacitors in vehicle applications, EVS32, Lyon, 19–22 May 2019. Anderman

Corrigan D, Liu X (2013) Pulse power testing of batteries and supercapacitors for hybrid electric vehicle applications: a comparison of constant current, constant power, and ramped power transients. SAE Technical Paper 2013-01-1535

Burke AF, Coogan T (2016) Lithium titanate oxide (LTO) batteries and supercapacitors as options for hybrid vehicles. Presented at AAABC Europe, Mainz, Jan 2016

10.

Burke AF (2018) Considerations in the selection of batteries to be used with supercapacitors in vehicle applications. In: International battery seminar, Fort Lauderdale, Mar 2018

11.

Burke AF, Zhao H (2017) Considerations in the use of supercapacitors in combination with batteries in vehicles, on the CD for EVS 30, Stuttgart, Oct 2017

12.

Bohn T (2007) Plug-in hybrid vehicles: decoupling battery load transients with ultracapcitor storage. Paper presented at the advanced capacitor world summit 2007, San Diego, July 2007

13.

Miller JM, Bohn T, Deshpande U (2008) DC-DC converter buffered supercapacitor in active parallel combination with lithium battery for plug-in hybrid electric vehicle energy storage, SAE paper 2008-01-1003, SAE World Congress, Detroit, Apr 2008

14.

Song Z, Li J et al (2018) The battery-supercapacitor hybrid energy storage system in electric vehicle applications, a case study. Energy 154:433–441 CrossRef

15.

Qiao Z, Li G et al (2020) Experimental study on semi-active battery-supercapacitor hybrid energy storage system for electric vehicle applications. IEEE Trans 35(1)

16.

Bender J (2009) Life cycle testing of a supercapacitor/lithium battery combination, Private communication from AFS Trinity, June 2009

17.

Hochgraf CG, Basco JK, Bohn TP et al (2014) Effect of ultracapacitor-modified PHEV protocol on performance degradation in lithium-ion cells. J Power Sources 246:965–969 CrossRef

18.

Zhao C, Yin H, Ma C (2016) Quantitative evaluation of LiFePO4 battery cycle life improvement using ultracapacitors. IEEE Trans Power Electron 31(6):3989–3993 CrossRef

19.

Burke AF, Zhao JY (2017) Cycle life of lithium-ion batteries in combination with supercapacitors: the effect of load leveling, EVS 30, Stuttgart, 9–11 Oct 2017

20.

Bartley T (2005) Supercapacitor energy storage in heavy-duty hybrid drive update. In: Proceedings of the advanced capacitor world summit 2005, San Diego, July 2005

21.

King RD et al (2003) Supercapacitor enhanced zero emissions zinc air electric transit bus – performance test results. In: 20 ^th international electric vehicle symposium, Long Beach

22.

Burke AF, Armiroli P et al (2008) Valeo Stars+System, supercapacitors: the way for regen for micro-mild hybrids. In: Proceedings of the fourth international symposium on large supercapacitor technology and application, Tampa, May 2008

23.

Burke AF, Zhao JY (2015) Supercapacitors in micro- and mild hybrids with lithium titanate oxide batteries: vehicle simulations and laboratory tests. Presented at the European electric vehicle congress 2015, Brussels, Dec 2015

24.

Okamura SA (2006) EC-funded project “SUPERCAR”: supercapacitor modules for mild hybrid applications. In: Proceedings of the second international symposium on large supercapacitor (EDLC) technology and application, Baltimore, 16–17 May 2006

25.

Knorr R (2006) SUPERCAR – results of a European mild hybrid project. In: Proceedings of the 6th international advanced automotive battery and supercapacitor conference, Baltimore, 17–19 May 2006

26.

Gonder J, Pesaran A, Lustbader J, Tataria H (2009) Fuel economy and performance of mild hybrids with supercapacitor simulations and vehicle test results. Presentation at the 5th international symposium on large EC capacitor technology and applications, Long Beach, June 2009

27.

Peasaran A (2007) Factors and conditions for widespread use of supercapacitors in automotive applications. In: Proceedings of the advanced capacitor world summit 2007, San Diego, July 2007

28.

Knight B (2003) Information on the supercapacitors used in the Honda fuel cell vehicle, Mar 2003

29.

Thounthong P, Rael S, Davat B (2009) Energy management of fuel cell/supercapacitor hybrid power source for vehicle applications. J Power Sources 193:376–385 CrossRef

30.

Burke AF, Miller M (2003) Supercapacitor and fuel cell applications. In: Proceedings of the 20th international electric vehicle symposium, Long Beach, Nov 2003

31.

Burke AF, Zhao H, Van Gelder E (2009) Simulated performance of alternative hybrid-electric powertrains in vehicles on various driving cycles, EVS-24, Stavanger, May 2009 (paper on the CD of the meeting)

32.

Burke AF, Van Gelder E (2008) Plug-in hybrid-electric vehicle powertrain design and control strategy options and simulation results with lithium-ion batteries. Paper presented at EET-2008 European Ele-Drive conference, Geneva, 12 Mar 2008 (paper on CD of proceedings)

33.

Burke AF, Sinha AK (2019) Energy storage considerations for 48V hybrid-electric powertrains, AABC USA, San Diego, June 2019

34.

Burke AF (2007) Batteries and supercapacitors for electric, hybrid, and fuel cell vehicles. IEEE J Spec Issue Vehicles 95(4):806–820

35.

Burke A, Miller M (2010) Lithium batteries and supercapacitors alone and in combination in hybrid vehicles: fuel economy and battery stress reduction advantages, paper presented at the electric vehicle symposium 25, Shenzhen, Nov 2010

36.

Zhao H, Burke AF (2009) Optimum performance of direct hydrogen hybrid fuel cell vehicles, EVS-24, Stavanger, May 2009 (paper on the CD of the meeting)

37.

Zhao H, Burke AF (2009) Optimization of fuel cell system operating conditions for fuel cell vehicles. J Power Sources 186(2):408–416 CrossRef

38.

Zhao H, Burke AF (2010) Effects of powertrain configurations and control on fuel economy of fuel cell vehicles. Paper presented at the electric vehicle symposium 25, Shenzhen, Nov 2010

Title: Energy Storage: Ultracapacitor
Author: Andrew Burke
Publisher: Springer New York
Book: Electric, Hybrid, and Fuel Cell Vehicles
Print ISBN: 978-1-0716-1491-4

Electronic ISBN: 978-1-0716-1492-1

Copyright Year: 2021
DOI: https://doi.org/10.1007/978-1-0716-1492-1_809