A temperature dependent, single particle, lithium ion cell model including electrolyte diffusion

Tanvir R. Tanim; Christopher D. Rahn; Chao Yang Wang

doi:10.1115/1.4028154

A temperature dependent, single particle, lithium ion cell model including electrolyte diffusion

Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

136 Scopus citations

Abstract

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 25°C < T < 50°C at 1 ≤ 12.5C and -10°C < T < 50°C at 1 ≤ 1C for a graphite/nickel cobalt manganese (NCM) lithium ion cell.

Original language	English (US)
Article number	011005
Journal	Journal of Dynamic Systems, Measurement and Control, Transactions of the ASME
Volume	137
Issue number	1
DOIs	https://doi.org/10.1115/1.4028154
State	Published - Jan 2015

All Science Journal Classification (ASJC) codes

Control and Systems Engineering
Information Systems
Instrumentation
Mechanical Engineering
Computer Science Applications

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abstract = "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 25°C < T < 50°C at 1 ≤ 12.5C and -10°C < T < 50°C at 1 ≤ 1C for a graphite/nickel cobalt manganese (NCM) lithium ion cell.",

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T1 - A temperature dependent, single particle, lithium ion cell model including electrolyte diffusion

AU - Tanim, Tanvir R.

AU - Rahn, Christopher D.

AU - Wang, Chao Yang

PY - 2015/1

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N2 - 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 25°C < T < 50°C at 1 ≤ 12.5C and -10°C < T < 50°C at 1 ≤ 1C for a graphite/nickel cobalt manganese (NCM) lithium ion cell.

AB - 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 25°C < T < 50°C at 1 ≤ 12.5C and -10°C < T < 50°C at 1 ≤ 1C for a graphite/nickel cobalt manganese (NCM) lithium ion cell.

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A temperature dependent, single particle, lithium ion cell model including electrolyte diffusion

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