Field testing of repurposed electric vehicle batteries for price-driven grid balancing

•Field testing of a repurposed electric vehicle battery for grid balancing.•Battery and converter modeling.•Autonomous battery operation based on spot-market prices for electricity.•Battery performance analysis regarding efficiencies battery and utilization.•Discussions of model inaccuracies and res...

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Bibliographic Details
Published in:Journal of energy storage 2019-02, Vol.21, p.40-47
Main Authors: Faessler, B., Kepplinger, P., Petrasch, J.
Format: Article
Language:English
Subjects:
Autonomous optimization
Distributed storage
Grid balancing
Modeling
Repurposed vehicle ZEBRA battery
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Summary:•Field testing of a repurposed electric vehicle battery for grid balancing.•Battery and converter modeling.•Autonomous battery operation based on spot-market prices for electricity.•Battery performance analysis regarding efficiencies battery and utilization.•Discussions of model inaccuracies and resulting performance issues. As electric cars become more widespread, the disposal and recycling of used batteries will become an important challenge. Typically, vehicle batteries are replaced if their capacity drops to 70–80% of initial capacity. However, they may still be useful for stationary applications. In this paper, results from a field test of a molten salt high-temperature electric vehicle battery repurposed as stationary storage for grid balancing are presented. In a previous study, we have shown that a mixed integer linear programming control strategy driven by a spot-market price for electricity is best suited for an implementation on hardware with limited computational resources. A 14-day experiment resulted in a round-trip energy efficiency (converter-battery-converter) of about 74.4%. The earnings per battery capacity per day achieved in this period amounted to 7.38 €/MWh. An error analysis of the model underlying the optimization showed a root mean square error of 7.6% between the estimated and measured state of charge. The field test implementation shows a substantial economic deviation of 37.3% between theoretical and physical potential of grid-balancing measures due to model inaccuracies and technical characteristics, thereby demonstrating the urgent need for field tests of repurposed electric vehicle batteries for stationary applications.
ISSN:2352-152X
2352-1538
DOI:10.1016/j.est.2018.10.010