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Battery State Control Techniques for Charge Sustaining Applications
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Abstract
A foundation of battery normalizations, modeling and control techniques is presented for charge sustaining HEV applications. Charge and voltage based battery state observers and controllers are compared. The voltage based technique is shown to provide robust state control, as it directly constrains terminal voltage. Additionally, it provides good power cycle efficiency, and is insensitive to the initialization and drift problems characteristic of charge based controllers. Special attention is given to VRLA batteries, and dynamic loads from typical driving cycles. Future work is introduced which identifies battery power capability and efficiency as possible state control variables.
This work was supported by a Netherland-America Foundation Fellowship, and by the staff at the Technical University of Eindhoven, the Netherlands.
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Wiegman, H. and Vandenput, A., "Battery State Control Techniques for Charge Sustaining Applications," SAE Technical Paper 981129, 1998, https://doi.org/10.4271/981129.Data Sets - Support Documents
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References
- Peukert, W. “Uber die Abhangigkeit der Kapazitat von der Entladestromstarke bei Bleiakkumulatorn.” Electrotech. Z. 18 1897 287 288
- Shepherd, C.M. “Design of Primary and Secondary Cells, II. An Equation Describing Battery Discharge,” J. Electro-chemical Soc. 112 7 1965 657 664
- Bode, H. Lead-Acid Batteries Wiley Int. Princeton, NJ 1977 0-471-08455-7
- Schleuter, W. Skudelny, H.C. “The Electrical Behavior of Lead-Acid and Nickel Iron Batteries,” IEEE Ind. Appl. Soc. (IAS) 1983 363 369
- Burke, A. “An Adaptive Battery State of Charge Indicator (ASCI) for Urban Driving,” 8th Int. Elect. Veh. Sym. (EVS-8) 1986 350
- Kaushik, R. Mawston, I. “Discharge Characterization of Lead/Acid Batteries,” J. of Pow. Sources 28 1989 161 169
- Schöner, H.P. “Electrical Behaviour of Lead/Acid Batteries During Charge, Overcharge, and Open Circuit,” 9th Elect. Veh. Sym. (EVS-9) 1988
- Brandt, D. “Driving cycle testing of electric vehicle batteries and systems,” J. of Pow. Sources 40 1992 73 79
- Noviello, E.I. Plaitano, Tortora “Battery Diagnostics and Performance Prediction: Computational vs. Expert System Based Approach,” IEEE-INTELEC 1 1993 460 468
- Kopf, C. “Adaptive Control of an EV Drive System to Account for Time-Varying Battery Parameters,” EVS-12, EVAA 2 1994 1 10
- Song, S. Kim, K. Oh, S. “A Dynamic State-of-Charge Model for Electric Vehcle Batteries,” EVS-12, EVAA 1994 519 527
- Mauracher, P. Karden, E. “Dynamic Modelling of Lead-Acid Batteries Using Impedance Spectroscopy for Parameter Identification,” 5th ELBC Barcelona J. of Pow. Sources 67 69 84 1996
- Hochgraf, C. Ryan, M. Wiegman, H. “Engine Control Strategy for a Series Hybrid Electric Vehicle Incorporating Load-Leveling and Computer Controlled Energy Managment,” SAE Publ. 960230, or SP-1156 1996 1-56091-786-5 11 24
- An, F. Frank, A. Ross, M. “Meeting Both ZEV and PNGV Goals with a Hybrid Electric Vehicle - An Exploration,” SAE Publ. 961718, or SP-1189 1996 1-56091-840-3 17 32