Abstract
During the induction heating process, carbon fiber-reinforced polymer (CFRP) exhibits anisotropic magnetic and thermal properties due to changes in fiber arrangement, which affect the variation of the temperature field distribution on the material’s surface and reduce the magnetic field utilization rate. Therefore, this paper adopts the CFRP induction heating finite element microanalysis model to improve the heating efficiency of the material and regulate the temperature field distribution reasonably. The study investigates the coupling relationship between the magnetic field’s spatial state and the magnetocaloric properties of the fiber texture, analyzing the map** relationship between the magnetic field state and the material’s calorific value and temperature field distribution. The intrinsic correlation between the magnetic field state and the material’s magnetocaloric properties on the temperature field distribution is characterized, providing a theoretical analysis basis for designing and optimizing the temperature and magnetic field distribution during the induction heating process of CFRP. The study aims to achieve effective control of temperature field distribution during the CFRP heating process.
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This study was acknowledged by General Project of Basic Science (Natural Science) Research in Jiangsu Universities (22KJD430003); Changzhou City Applied Basic Research Programs (CJ20220035).
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DOI: https://doi.org/10.1007/s10853-023-08646-6