Abstract
This study focusses on a low-frequency induction heating (LFIH) effect in a thermoplastic polymer (acrylonitrile butadiene styrene, ABS) filled with iron oxide magnetic particles. The LFIH effect in such ferromagnetic composites appears as soon as the sample is exposed to an alternating magnetic excitation field and is mainly due to the so-called “microscopic” eddy currents linked to the motions of the magnetic domain wall. To generate an AC magnetic field with significant amplitude under a low-frequency range of a few thousand Hz, a specific test bench has been designed using a rotating motor and strong permanent magnets. Theoretical hysteresis modeling, together with thermal transfer based Comsol simulation and experimental tests, demonstrated the feasibility of significantly increasing the temperature of a magnetic composite through a simple induction heating effect. To better highlight such an effect, a comparison with conductive but non-ferromagnetic samples was performed. As opposed to the ferromagnetic composite, its conductive counterpart exhibited a very weak response to the magnetic field excitation, and no temperature effect was achieved. This observation can be explained by “microscopic” eddy currents (i.e., the fact that domain wall motions are predominant mechanisms under low frequency), leading to local temperature variations inside the ferromagnetic particles. These preliminary results seem to be promising, and this effect could be exploited in a medical application, especially for treatment of superficial venous insufficiency, where local heating remains a true challenge. As normal tissues and muscles are conductive, it is necessary to bring the heat “where it is needed”. We believe that LFIH would be able to destroy varicose veins without damaging the neighboring tissues.
Highlights
Ferromagnetic composites with magnetic particles embedded in a polymer matrix are currently of great interest from a scientific viewpoint
We discuss the influence of three relevant parameters including fraction content of fillers, frequency, and strength of the magnetic fields on the low-frequency induction heating (LFIH) effect of ferromagnetic composite
Polymer filled with sufficient ferromagnetic particles led to substantially improved permeability, as well as hysteresis losses, giving rise to a drastically increased magnetic power density and boosting the induction heating effect
Summary
Ferromagnetic composites with magnetic particles embedded in a polymer matrix are currently of great interest from a scientific viewpoint. Incorporation of particles, fibers or nanomaterial reinforcements into polymers permit the fabrication of polymer matrix composites, which can be characterized by high mechanical performance and excellent functionality [1]. Particle reinforcements have been developed to improve mechanical properties: enhance tensile/storage modulus by adding glass beads [2], iron or copper particles [3], and enhance wear resistance by adding aluminum and aluminum oxide (Al2O3) [4]. Combining ferromagnetic particles with a polymer matrix creates an opportunity for potential enhancements in both mechanical and magnetic properties. Among applications based on ferromagnetic composites, induction heating is currently one of the hot topics related to numerous fields, such as self-healing polymers, thermal welding, and magnetic hyperthermia. The main benefits over other heating methods include the selectivity of the heated area, the fast response time, and good efficiency [5]
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