Magnetic-thermal-mechanical coupling behavior simulation for a porous high-temperature superconductor based on fractal derivatives

IF 1.3 3区物理与天体物理 Q4 PHYSICS, APPLIED Physica C-superconductivity and Its Applications Pub Date : 2024-03-06 DOI:10.1016/j.physc.2024.1354481

Feng Xue , Yunfei Huang , Xinxin Zhou , Xiaofan Gou

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Abstract

In this paper, the magnetic-thermal-mechanical coupling behavior for a porous high-temperature superconductor placed in a pulsed field is studied numerically within the framework of finite element analysis and based on fractal derivatives. Firstly, as a kind of oxide ceramic material, the porous properties of high-temperature superconductors (SCs) are characterized through fractal methods. Then, we obtained the Maxwell equation and heat conduction equation in the form of fractal derivatives, and thus the difficulties brought by the multi connectivity of materials to finite element (FEM) modeling can be overcome. The FEM simulation results indicate that the porous properties have a significant impact on the maximum trapped magnetic field, surface temperature of superconductors, and maximum stress inside superconductors. The presented method can also provide a more efficient solution for the multi-field coupling simulation of other porous electromagnetic media.

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基于分形导数的多孔高温超导体磁热机械耦合行为模拟

本文在有限元分析框架内，基于分形导数对置于脉冲场中的多孔高温超导体的磁-热-机械耦合行为进行了数值研究。首先，作为一种氧化物陶瓷材料，高温超导体（SCs）的多孔特性是通过分形方法表征的。然后，我们以分形导数的形式得到了麦克斯韦方程和热传导方程，从而克服了材料的多连通性给有限元（FEM）建模带来的困难。有限元模拟结果表明，多孔特性对最大捕获磁场、超导体表面温度和超导体内部最大应力有显著影响。该方法还能为其他多孔电磁介质的多场耦合模拟提供更有效的解决方案。

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来源期刊

Physica C-superconductivity and Its Applications 物理-物理：应用

CiteScore

2.70

自引率

11.80%

发文量

102

审稿时长

66 days

期刊介绍： Physica C (Superconductivity and its Applications) publishes peer-reviewed papers on novel developments in the field of superconductivity. Topics include discovery of new superconducting materials and elucidation of their mechanisms, physics of vortex matter, enhancement of critical properties of superconductors, identification of novel properties and processing methods that improve their performance and promote new routes to applications of superconductivity. The main goal of the journal is to publish: 1. Papers that substantially increase the understanding of the fundamental aspects and mechanisms of superconductivity and vortex matter through theoretical and experimental methods. 2. Papers that report on novel physical properties and processing of materials that substantially enhance their critical performance. 3. Papers that promote new or improved routes to applications of superconductivity and/or superconducting materials, and proof-of-concept novel proto-type superconducting devices. The editors of the journal will select papers that are well written and based on thorough research that provide truly novel insights.