Designing moving magnet pumps for high-temperature, liquid-metal systems

Moving magnet pumps (MMP's) operate on the same principles as other induction-style electromagnetic pumps. However, MMP's generate a travelling magnetic field with a spinning array of permanent magnets instead of polyphase field coils. This difference allows MMP's to be made much more...

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Veröffentlicht in:	Nuclear engineering and design 2018-02, Vol.327 (C), p.228-237
Hauptverfasser:	Hvasta, M.G., Nollet, W.K., Anderson, M.H.
Format:	Artikel
Sprache:	eng
Schlagworte:	Coils Electromagnetic induction Electromagnetic pumps Energy storage Field coils Magnetic fields Metals Nuclear Science & Technology Permanent magnets Pumps Solar energy Solar power Spinning
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container_title	Nuclear engineering and design
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creator	Hvasta, M.G. Nollet, W.K. Anderson, M.H.
description	Moving magnet pumps (MMP's) operate on the same principles as other induction-style electromagnetic pumps. However, MMP's generate a travelling magnetic field with a spinning array of permanent magnets instead of polyphase field coils. This difference allows MMP's to be made much more quickly, reliably, and inexpensively than other types of electromagnetic pumps, For these reasons, MMP's are a promising technology that can be used to enhance liquid-metal systems in the nuclear, concentrated solar power, and energy storage industries. This paper will provide a background on MMP design and present an updated theory that can accurately predict MMP performance - even if the magnetic field produced by the MMP is non-sinusoidal. The new theory will be tested for a range of operating conditions (magnet configurations, magnet spacing, magnet type, etc.) and compared to experimental results.
doi_str_mv	10.1016/j.nucengdes.2017.11.004
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subjects	Coils Electromagnetic induction Electromagnetic pumps Energy storage Field coils Magnetic fields Metals Nuclear Science & Technology Permanent magnets Pumps Solar energy Solar power Spinning
title	Designing moving magnet pumps for high-temperature, liquid-metal systems
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