Electromagnetic and Thermal analysis of an Intra-layer no-insulation coil during Quench

IF 1.3 3区 物理与天体物理 Q4 PHYSICS, APPLIED
Kangshuai Wang , Yong Chen , Qiuliang Wang , Quanyue Liu , Lei Wang , Jianhua Liu
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Abstract

The intra-layer no-insulation (LNI) layer-wound REBCO coil has been widely studied for its excellent high thermal stability in the research of nuclear magnetic resonance superconducting magnets. Due to the complex structure of the LNI layer-wound coil and the numerous factors that affect thermal stability, its quench characteristics are not clear. In this paper, a numerical multiphysics coupling model is established to study the transient electromagnetic and thermal behaviors of the LNI layer-wound coil during quench. The results indicate that temperature follows the diffusion law, while the currents evolve through electrical connection and electromagnetic induction. Due to the high contact resistance, the azimuthal current and axial current vary almost in units of the entire coil layer. The direction of the radial current upstream of the turn where a quench occurs is positive due to the bypassing behavior, while the radial current direction is negative downstream. The insulation material inside the LNI layer-wound coil strongly affects the quench propagation. When its thickness decreases, the equivalent radial thermal conductivity increases, thereby increasing the quench propagation velocity and current peak, and shortening the duration of the current response during quench.

淬火过程中层内无绝缘线圈的电磁和热分析
在核磁共振超导磁体的研究中,层内无绝缘(LNI)层绕 REBCO 线圈因其出色的高热稳定性而被广泛研究。由于 LNI 层绕线圈结构复杂,影响热稳定性的因素众多,其淬火特性并不明确。本文建立了一个多物理场耦合数值模型,研究 LNI 层绕线圈在淬火过程中的瞬态电磁和热行为。结果表明,温度遵循扩散定律,而电流则通过电连接和电磁感应演变。由于接触电阻较大,方位电流和轴向电流几乎以整个线圈层为单位变化。由于旁路行为,发生淬火的匝道上游径向电流方向为正,而下游径向电流方向为负。LNI 层绕线圈内部的绝缘材料对淬火传播有很大影响。当其厚度减小时,等效径向热导率会增加,从而提高淬火传播速度和电流峰值,并缩短淬火期间电流响应的持续时间。
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来源期刊
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.
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