Development of an Experimental Testbed for Research in Lithium-Ion Battery Management Systems

Lotfi, Nima; Fajri, Poria; Novosad, Samuel; Savage, Jack; Landers, Robert G.; Ferdowsi, Mehdi

doi:10.3390/en6105231

Cited by 46 publications

(23 citation statements)

References 35 publications

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“…Cell balancing based on voltage inconsistency is more easily implemented and more common [13]. In this paper, the cells terminal voltages are employed as the index of inconsistency.…”

Section: Equalization Principlementioning

confidence: 99%

Analysis and Application of a Novel Layered Bidirectional Equalizer for Series Connected Battery Strings

Wang¹,

Kang²,

Li³

et al. 2017

Preprint

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Abstract:To eliminate the influence of the inconsistency on the cycle life and the available capacity of the battery pack, and improve the balancing speed, a novel inductor-based layered bidirectional equalizer (IBLBE) is proposed. The equalizer is composed of the bottom balancing circuits and the upper balancing circuits, and the two layer circuits both consist of a plurality of balancing sub-circuits, which allow the dynamic adjustment of equalization path and equalization threshold. The battery string is modularized by layered balancing circuits to realize fast active equalization, especially for long battery strings. By controlling the bottom balancing circuits, the individual cells can be balanced in each module. At the same time, the equalization between battery modules can be realized by controlling the upper balancing circuits. Simulation and experimental results demonstrate that the proposed equalizer can achieve fast active equalization for a long battery string, and has the characteristics of multi balancing path, large balancing current and high accuracy. The advantages of the proposed equalizer are further verified by a comparison with existing active equalizer.

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“…Cell balancing based on voltage inconsistency is more easily implemented and more common [13]. In this paper, the cells terminal voltages are employed as the index of inconsistency.…”

Section: Equalization Principlementioning

confidence: 99%

Analysis and Application of a Novel Layered Bidirectional Equalizer for Series Connected Battery Strings

Wang¹,

Kang²,

Li³

et al. 2017

Preprint

View full text Add to dashboard Cite

show abstract

“…When compared to electrochemical models (which may have in excess of 88 parameters that must be defined [31]) the attraction of the ECM approach to cell modeling is further reinforced. This is particularly the case when the cell model is embedded within an optimization algorithm, such as within management systems to predict runtimes and dynamic power estimations [32][33][34]. Within the context of EV performance simulation [25], introducing further RC terms within the model will increase the computational effort required without offering a discernable improvement in model accuracy.…”

Section: Cell Electrical Modelmentioning

confidence: 99%

An Acausal Li-Ion Battery Pack Model for Automotive Applications

Uddin

Picarelli²,

Lyness

et al. 2014

Energies

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Abstract:In this work, a novel acausal and reconfigurable battery pack model is presented. The model structure adopted for the battery cell is based on an equivalent circuit representation. The circuit elements are modified to take account of both hysteresis and diffusion limitation. The latter is known to be a nonlinear function of large operating currents or long operating times. It is shown that the integration of a current dependent time constant within the cell model better emulates the solid diffusional dynamics of lithium intercalation into the active material under large electrical loads. The advantages of an acausal modeling approach, when scaling-up individual cell models into a complete battery system are also presented. Particular consideration is given to emulating the impact of cell to cell variations on pack performance. Using statistical analysis of battery tests, cell model parameter variations are characterized and quantified. The cell and scaled-up pack model are parameterized for a number of commercially available cell formats, energy capacities and chemistries. The new models are validated using transient, real-world, electrical data measured from an electric vehicle (EV) operating within an urban environment.

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“…This approach extends established HILS methods for improved system design and verification and is complementary to existing research investigating novel methods of battery system testing for control integration [9]. HILS has become embedded within a number of high-value manufacturing organisations (typically within the automotive and aerospace sectors) as a safe, cost effective and deterministic method of early-stage verification of system performance, reliability and robustness.…”

Section: Introductionmentioning

confidence: 98%

A Cell-in-the-Loop Approach to Systems Modelling and Simulation of Energy Storage Systems

et al. 2015

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This research is aligned with the engineering challenge of scaling-up individual battery cells into a complete energy storage system (ESS). Manufacturing tolerances, coupled with thermal gradients and the differential electrical loading of adjacent cells, can result in significant variations in the rate of cell degradation, energy distribution and ESS performance. The uncertain transition from cell to system often manifests itself in over-engineered, non-optimal ESS designs within both the transport and energy sectors. To alleviate these issues, the authors propose a novel model-based framework for cell-in-the-loop simulation (CILS) in which a physical cell may be integrated within a complete model of an ESS and exercised against realistic electrical and thermal loads in real-time. This paper focuses on the electrical integration of both real and simulated cells within the CILS test environment. Validation of the CILS approach using real-world electric vehicle data is presented for an 18650 cell. The cell is integrated within a real-time simulation model of a series string of similar cells in a 4sp1 configuration. Results are presented that highlight the impact of cell variability (i.e., capacity and impedance) on the energy available from the multi-cell system and the useable capacity of the physical cell.

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Development of an Experimental Testbed for Research in Lithium-Ion Battery Management Systems

Cited by 46 publications

References 35 publications

Analysis and Application of a Novel Layered Bidirectional Equalizer for Series Connected Battery Strings

Analysis and Application of a Novel Layered Bidirectional Equalizer for Series Connected Battery Strings

An Acausal Li-Ion Battery Pack Model for Automotive Applications

A Cell-in-the-Loop Approach to Systems Modelling and Simulation of Energy Storage Systems

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