Journal
ENERGY
Volume 260, Issue -, Pages -Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.energy.2022.124932
Keywords
Entropy generation; 3D coupled thermal model; Thermodynamic analysis; Supercapacitor
Categories
Funding
- National Natural Science Foundation of China [51906211, 52076188]
- Royal Society Newton Advanced Fellowship [52061130218]
- State Key Laboratory of Clean Energy Utilization Open Fund [ZJUCEU2019002]
- National Program for Support of Top-notch Young Professionals
- Australian Research Council
- QUT Center for Materials Science
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This work introduces entropy generation analysis to supercapacitors for the first time, accurately quantifying the irreversibilities and inefficiency mechanisms in the system. The effects of electrolyte, porosity, and charge/discharge current on thermodynamic irreversibilities and heat transfer characteristics are investigated, and an optimal design scheme is obtained through optimization approaches. This study provides a fundamental and computational framework for the development and optimization of clean and renewable energy conversion and storage systems with reduced irreversibilities.
Sustainability and efficiency are the key issues concerning performance and lifetime of supercapacitors. In this work, an entropy generation analysis is implemented for the first time in the supercapacitor cell, aiming at facilitating the design and optimization of the supercapacitor systems. Entropy generation analysis accurately quantifies the irreversibilities due to heat transfer, mass transfer and ohmic loss of the supercapacitor cell, satisfying direct identification of the inefficiency mechanisms that cannot be achieved by the conventional energy analysis. The effects of the electrolyte, porosity and charge/discharge current on the thermodynamic irreversibilities and heat transfer characteristics are investigated. The optimal design scheme of the supercapacitor cell is obtained using the optimization approaches based on the combined energy and entropy generation ana-lyses. Results indicate that the main contribution to the irreversibilities is due to ohmic loss, followed by the mass transfer effect. The 1 M TEMABF(4)/ACN electrolyte with the porosity of 0.4 is found to be the optimal choice, corresponding to the entropy generation rate of 2230 W/(m(3).K) and the temperature rise of 0.20974 degrees C. The outcomes of this work provide a fundamental and computational framework for the development and optimi-zation of clean and renewable energy conversion and storage systems with reduced irreversibilities.
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