Study on the magnetic self-levitation of the ring permanent magnet with inserted inner cores in ferrofluid

•The levitation of a magnetized object containing permanent magnet, soft magnetic, and nonmagnetic material in ferrofluid is studied.•A method for analyzing the levitation force of a magnetized object is presented.•It is a feasible method to study the levitation force through boundary interface of f...

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Bibliographic Details
Published in:Journal of magnetism and magnetic materials 2023-03, Vol.569, p.170464, Article 170464
Main Authors: Yu, Jun, Li, Decai, Wang, Deyi, He, Xinzhi
Format: Article
Language:English
Subjects:
Ferrofluid
Magnetic core
Magnetic levitation force
Magnetized object
Ring magnet
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Summary:•The levitation of a magnetized object containing permanent magnet, soft magnetic, and nonmagnetic material in ferrofluid is studied.•A method for analyzing the levitation force of a magnetized object is presented.•It is a feasible method to study the levitation force through boundary interface of ferrofluid. The self-levitation of a magnetized object composed of ring permanent magnet, soft magnetic pure iron core (Fe-core), and nonmagnetic aluminum core (Al-core) in ferrofluid (FF) is studied, and the focus is the influence of Fe-core (Al-core) on the magnetic fluid levitation force (MFLF) received by the immersed magnetized object. The formula for calculating MFLF is derived focusing on the gas–liquid and solid–liquid boundary interface between FF and surroundings, and experiments have been done to study the dependence between MFLF and the levitation height of the magnetized object and mass of FF. Researches show that Fe-core has a significant influence on MFLF, and the influence is determined by the magnetization of Fe-core and the distance between Fe-core and the boundary interface. In a word, the use of Fe-core is beneficial to obtain a smaller MFLF, the greater the magnetization of the Fe-core is and the closer it is to the boundary interface of FF, the smaller the MFLF is. The Fe-core near the bottom surface of the ring magnet tends to reduce the maximum MFLF corresponds to an approximate horizontal gas–liquid boundary interface when the levitation height is constant, and the Fe-core near the top surface of the ring magnet is more likely to reduce the change of MFLF caused by the disappearance of surface instability of FF. Or, in other words, the Fe-core near the top surface of the ring magnet tends to reduce the MFLF when magnetized object moves upward, and vice versa.
ISSN:0304-8853
DOI:10.1016/j.jmmm.2023.170464