Low-order, explicit models of lithium ion cells are critical for real-time battery management system (BMS) applications. This paper presents a seventh-order, electrolyte enhanced single particle model (ESPM) with electrolyte diffusion and temperature dependent parameters (ESPM-T). The impedance transfer function coefficients are explicit in terms of the model parameters, simplifying the implementation of temperature dependence. The ESPM-T model is compared with a commercially available finite volume based model and results show accurate matching of pulse responses over a wide range of temperature (T) and C-rates (I). The voltage response to 30 s pulse charge–discharge current inputs is within 5% of the commercial code for at and at for a graphite/nickel cobalt manganese (NCM) lithium ion cell.
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January 2015
Research-Article
A Temperature Dependent, Single Particle, Lithium Ion Cell Model Including Electrolyte Diffusion
Tanvir R. Tanim,
Tanvir R. Tanim
Department of Mechanical and
Nuclear Engineering,
e-mail: trt140@psu.edu
Nuclear Engineering,
The Pennsylvania State University
,University Park, PA 16802
e-mail: trt140@psu.edu
Search for other works by this author on:
Christopher D. Rahn,
Christopher D. Rahn
Professor
Department of Mechanical and
Nuclear Engineering,
e-mail: cdrahn@psu.edu
Department of Mechanical and
Nuclear Engineering,
The Pennsylvania State University
,University Park, PA 16802
e-mail: cdrahn@psu.edu
Search for other works by this author on:
Chao-Yang Wang
Chao-Yang Wang
Professor
William E. Diefenderfer Chair
of Mechanical Engineering,
and Director of the Electrochemical
Engine Center,
Department of Mechanical
and Nuclear Engineering,
e-mail: cxw31@psu.edu
William E. Diefenderfer Chair
of Mechanical Engineering,
and Director of the Electrochemical
Engine Center,
Department of Mechanical
and Nuclear Engineering,
The Pennsylvania State University
,University Park, PA 16802
e-mail: cxw31@psu.edu
Search for other works by this author on:
Tanvir R. Tanim
Department of Mechanical and
Nuclear Engineering,
e-mail: trt140@psu.edu
Nuclear Engineering,
The Pennsylvania State University
,University Park, PA 16802
e-mail: trt140@psu.edu
Christopher D. Rahn
Professor
Department of Mechanical and
Nuclear Engineering,
e-mail: cdrahn@psu.edu
Department of Mechanical and
Nuclear Engineering,
The Pennsylvania State University
,University Park, PA 16802
e-mail: cdrahn@psu.edu
Chao-Yang Wang
Professor
William E. Diefenderfer Chair
of Mechanical Engineering,
and Director of the Electrochemical
Engine Center,
Department of Mechanical
and Nuclear Engineering,
e-mail: cxw31@psu.edu
William E. Diefenderfer Chair
of Mechanical Engineering,
and Director of the Electrochemical
Engine Center,
Department of Mechanical
and Nuclear Engineering,
The Pennsylvania State University
,University Park, PA 16802
e-mail: cxw31@psu.edu
Contributed by the Dynamic Systems Division of ASME for publication in the JOURNAL OF DYNAMIC SYSTEMS, MEASUREMENT, AND CONTROL. Manuscript received July 21, 2013; final manuscript received July 30, 2014; published online August 28, 2014. Assoc. Editor: Jwu-Sheng Hu.
J. Dyn. Sys., Meas., Control. Jan 2015, 137(1): 011005 (11 pages)
Published Online: August 28, 2014
Article history
Received:
July 21, 2013
Revision Received:
July 30, 2014
Citation
Tanim, T. R., Rahn, C. D., and Wang, C. (August 28, 2014). "A Temperature Dependent, Single Particle, Lithium Ion Cell Model Including Electrolyte Diffusion." ASME. J. Dyn. Sys., Meas., Control. January 2015; 137(1): 011005. https://doi.org/10.1115/1.4028154
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