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Assessing battery degradation as a key performance indicator for multi-objective optimization of multi-carrier energy systems

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  • Jin, Lingkang
  • Kazemi, Milad
  • Comodi, Gabriele
  • Papadimitriou, Christina

Abstract

The Pareto frontier is extensively adopted in multi-objective optimization, especially in multi-carrier energy system modeling. Despite the various methodologies available to derive the frontier, it represents different optimal solutions, making the final selection non-trivial. The modeler’s expertise is crucial in determining the weight factors assigned to each objective for selecting the final solution from the Pareto frontier. This study proposes a novel approach to support such decision-making, introducing an additional key performance indicator, the state of health of the battery, evaluated through physical battery modeling. By comparing different scheduling schemes in multi-objective multi-carrier energy systems, each with its distinct battery operational strategy, this newly introduced indicator has deployed to automatically identify the ultimate solution from the Pareto frontier, without additional weighting coefficients. Such an approach, therefore, automates the decision process, which supports easy engineering, especially for the small scale multi-energy systems such as smart homes, like the case study presented in this work that has four distinct energy carriers, adopting the 12 V 128 Ah LFP chemistry Li-ion battery modules, demonstrates the effectiveness of this automated selection process. Furthermore, when compared to the maximum values across the entire frontier, the automatically chosen solution exhibits reductions of 27.96% in CO2 emissions and 3.67% reduction in overall costs. Over long-term operation, this approach has the potential to extend battery lifespan by up to 26.67%, directly impacting the economics of multi-carrier energy systems.

Suggested Citation

  • Jin, Lingkang & Kazemi, Milad & Comodi, Gabriele & Papadimitriou, Christina, 2024. "Assessing battery degradation as a key performance indicator for multi-objective optimization of multi-carrier energy systems," Applied Energy, Elsevier, vol. 361(C).
    • Handle: RePEc:eee:appene:v:361:y:2024:i:c:s0306261924003088
    DOI: 10.1016/j.apenergy.2024.122925
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    References listed on IDEAS

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    1. Chang, Miguel & Thellufsen, Jakob Zink & Zakeri, Behnam & Pickering, Bryn & Pfenninger, Stefan & Lund, Henrik & Østergaard, Poul Alberg, 2021. "Trends in tools and approaches for modelling the energy transition," Applied Energy, Elsevier, vol. 290(C).
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    Cited by:

    1. Chao Xing & Jiajie Xiao & Xinze Xi & Jingtao Li & Peiqiang Li & Shipeng Zhang, 2024. "Two-Layer Optimal Scheduling and Economic Analysis of Composite Energy Storage with Thermal Power Deep Regulation Considering Uncertainty of Source and Load," Energies, MDPI, vol. 17(19), pages 1-20, September.
    2. Jin, Lingkang & Rossi, Mosè & Monforti Ferrario, Andrea & Mennilli, Francesca & Comodi, Gabriele, 2025. "Designing hybrid energy storage systems for steady green hydrogen production in residential areas: A GIS-based framework," Applied Energy, Elsevier, vol. 389(C).
    3. Li Peng & Longfu Luo & Jingyu Yang & Wanting Li, 2024. "A Wind Power Fluctuation Smoothing Control Strategy for Energy Storage Systems Considering the State of Charge," Energies, MDPI, vol. 17(13), pages 1-20, June.
    4. Kai Zhang & Siyuan Zhao & Hui Zeng & Junming Chen, 2025. "Two-Stage Archive Evolutionary Algorithm for Constrained Multi-Objective Optimization," Mathematics, MDPI, vol. 13(3), pages 1-25, January.

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