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Evaluation of a Hybrid Energy Storage System for EV's
ISSN: 0148-7191, e-ISSN: 2688-3627
Published April 12, 2011 by SAE International in United States
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Electric energy storage is among the most significant hurdles to deployment of electric vehicles (EVs). Present storage methods struggle to provide the capacity and the service life demanded by automotive use. Hybrid energy storage systems (HESS) use a combination of storage types, for example, different types of batteries and ultracapacitors, to tailor the characteristics of the storage system to each application. In addition to sizing the system for the intended application, a suitable strategy for the integration of the energy storage system must be adopted. In the present application, a HESS has been designed for the electrification of a 2004 Chrysler Pacifica, through consideration of a combination of high capacity batteries, high power batteries, and capacitors. Hybrid storage systems using batteries alone, batteries and capacitors, and dual batteries have been considered. Each configuration used high capacity batteries as an energy device and a power device such as capacitors or high power batteries. The high power device was sized to accept and deliver the kinetic energy of the vehicle at highway speed. The energy device was used to provide a suitable range. Whole vehicle simulations were performed over a variety of drive histories using MATLAB® and Simulink® to assess range and power performance of the system. Service life, mass, and range were considered in the selection of the final configuration.
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CitationMikkelsen, K. and Lambert, S., "Evaluation of a Hybrid Energy Storage System for EV's," SAE Technical Paper 2011-01-1376, 2011, https://doi.org/10.4271/2011-01-1376.
- Hodkinson, Ron Fenton, John Lightweight Electric/Hybrid Vehicle Design Woburn Butterworth-Heinemann 2001
- Masrur, A. Mi, C. “Fundamentals of Hybrid Electric Vehicles,” SAE International Seminar 2006
- Kokam Co. Ltd. “Product Catalogue.” Kokam America 2010 http://www.kokam.com/english/product/battery_main.html 05 19 2010
- NESSCAP Co., Ltd. “NESSCAP Ultracapacitor Products.” NESSCAP 2008 http://www.nesscap.com/products_edlc.htm 05 19 2010
- Vetter, J Novak, P. Wagner, M.R. Veit, C. Moller, K.C. Besenhard, J.O. Winter, M. Wohlfahrt-Mehrens, M. Vogler, C. Hammouche, A. Ageing Mechanisms in Lithium Ion Batteries Journal of Power Sources 147 2005
- Lachichi, A. Schofield, N. “Comparison of DC-DC Converter Interfaces for Fuel.” IEEE Vehicle Power and Propulsion Conference 2006
- Hoelscher, David Skorcz, Alex Gao, Yimin Ehsani, Mehrdad “Hybridized Electric Energy Storage Systems for Hybrid Electric Vehicles.” IEEE Power and Propulsion Conference 2006
- Lukic, S Emado, A Modeling of Electric Machines for Automotive Applications Using Efficiency Maps Illinois Illinois Institute of Technology
- United States Environmental Protection Agency Testing and Measuring Emissions March 19 2008
- Powerex CM200DU-12NFH Product Datasheet Youngwood, PA Powerex, Inc. 2009
- McLyman, Colonel Wm Transformer and InductorDesign Handbook 3rd ed. Columbus, OH Marcel Dekker, Inc 2004