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Design and Performance of High-Capacity Magnesium–Air Battery for Power Generator System

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  • Kwang-Yeop Jang

    (Reliability & Semiconductor Convergence Center, Korean Testing Certification Institute, Gunpo 15809, Republic of Korea
    Electrical Engineering, Graduate School, Tech University of Korea, Siheung 15073, Republic of Korea)

  • Sang-Won Seo

    (Research & Development, SUNKWANG LTI., Seoul 06230, Republic of Korea)

  • Dong-Jin Kim

    (Research & Development, SUNKWANG LTI., Seoul 06230, Republic of Korea)

  • Dong-Gun Lee

    (Electrical Engineering, Graduate School, Tech University of Korea, Siheung 15073, Republic of Korea
    Department of Energy & Electrical Engineering, Tech University of Korea, Siheung 15073, Republic of Korea)

Abstract

Efforts to achieve carbon neutrality, which aims to reduce the net carbon emissions to zero by decreasing carbon emissions from human activities and increasing carbon absorption, are actively underway. Additionally, the search for clean energy alternatives to fossil fuels has become a global research trend. This paper presents research on metal–air batteries, focusing on the development of energy supply technologies that do not generate carbon emissions during power generation and require less space for power generation compared to existing renewable energy sources. The proposed Mg–air battery (MAB) in this study uses magnesium as the metal anode and theoretically offers a maximum open-circuit voltage of 3.1 V and a high energy density of 6.8 kWh/kg. While previous research has primarily focused on designing small-capacity cells and maximizing the performance of metal anodes, this study differentiates itself by designing a large-capacity MAB cell and optimizing its electrical performance. For the large-capacity cell design, the weight, shape, and size of the anode were designed based on MAB performance factors, and research was conducted on manufacturing methods to optimize the performance of the air cathode. Furthermore, to enhance usability and extend the lifespan of the MAB cell, it was designed to allow electrolyte circulation, and the electrolyte circulation performance was verified through simulations of fluid flow within the cell. Based on the study of the power performance of the newly designed large-capacity MAB cell, the feasibility of constructing a kW-class system using multiple Mg–air battery cell stacks was confirmed.

Suggested Citation

  • Kwang-Yeop Jang & Sang-Won Seo & Dong-Jin Kim & Dong-Gun Lee, 2024. "Design and Performance of High-Capacity Magnesium–Air Battery for Power Generator System," Energies, MDPI, vol. 17(22), pages 1-20, November.
    • Handle: RePEc:gam:jeners:v:17:y:2024:i:22:p:5643-:d:1518810
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    References listed on IDEAS

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    1. Camilo Mora & Daniele Spirandelli & Erik C. Franklin & John Lynham & Michael B. Kantar & Wendy Miles & Charlotte Z. Smith & Kelle Freel & Jade Moy & Leo V. Louis & Evan W. Barba & Keith Bettinger & Ab, 2018. "Broad threat to humanity from cumulative climate hazards intensified by greenhouse gas emissions," Nature Climate Change, Nature, vol. 8(12), pages 1062-1071, December.
    2. Andrey Zhuk & Grigory Belyaev & Tatiana Borodina & Elena Kiseleva & Eugeny Shkolnikov & Viktor Tuganov & Georgy Valiano & Viktor Zakharov, 2024. "Magnesium–Air Battery with Increased Power Using Commercial Alloy Anodes," Energies, MDPI, vol. 17(2), pages 1-19, January.
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