Comprehensive performance evaluation and optimization of a liquid carbon dioxide energy storage system with heat source

•Two liquid compressed carbon dioxide energy storage systems are proposed.•The modified cycle enhances the recovery of the turbine exhaust energy.•The relative cost difference of the modified cycle has decreased by 6.86%.•Insights are obtained by parametric analysis and multi-objective optimization....

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Bibliographic Details
Published in:Applied thermal engineering 2022-10, Vol.215, p.118957, Article 118957
Main Authors: Tang, Bo, Sun, Lei, Xie, Yonghui
Format: Article
Language:English
Subjects:
Liquid carbon dioxide energy storage systems
Multi-objective optimization
Parametric analysis
Thermodynamic and exergoeconomic analyses
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Summary:•Two liquid compressed carbon dioxide energy storage systems are proposed.•The modified cycle enhances the recovery of the turbine exhaust energy.•The relative cost difference of the modified cycle has decreased by 6.86%.•Insights are obtained by parametric analysis and multi-objective optimization. The investigation of advanced large-scale energy storage systems is needed due to the installation and grid-connected generation of instability renewable energy. As the compression heat tends to low temperature, in this paper, a liquid carbon dioxide energy storage system with heat source and its modification are proposed, in which an ice storage carbon dioxide liquefaction scheme and a modified recuperator layout are specially designed. Firstly, thermodynamic and exergoeconomic models are developed to evaluate the proposed systems; Then, a comprehensive understanding of the proposed system is obtained by parametric analysis and multi-objective optimization; Finally, a comparative analysis shows the attractiveness of the proposed system. The results show that the modified recuperator configuration improves the system performance by recovering more turbine exhaust energy, and the relative cost difference is reduced by 6.86%. The efficiency and economy of the system are greatly influenced by the compressor and turbine performance. Multi-objective optimization obtained compromise results of total exergy efficiency and unit output cost of 68.79% and 34.04 $/GJ. The comparative analysis reflects that the proposed system has certain superiorities.
ISSN:1359-4311
DOI:10.1016/j.applthermaleng.2022.118957