Elastic-plastic conductor damage evaluation at over 0.4% strain using a high-stress REBCO coil

Superconductor Science and Technology Pub Date : 2024-08-11 DOI:10.1088/1361-6668/ad6a9d

Jeseok Bang, Griffin Bradford, Kwangmin Kim, Jonathan Lee, Anatolii Polyanskii and David Larbalestier

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Abstract

Recent reports on screening current stress simulations of high-field REBCO magnets frequently present peak stresses over 1 GPa. However, this result is probably an unrealistic artifact of purely elastic calculations, considering the macroscopic yield and fracture stresses of approximately 900 MPa and less than 1.1 GPa for Hastelloy substrate-coated conductors. Here, we evaluate elastic-plastic conductor damage at over 0.4% strain using a high-stress REBCO coil exposed to a high field to explore this elastic-plastic regime. The coil was located off-center in a low-temperature superconductor magnet so as to induce a significant screening current in the enhanced radial field. Voltage taps, a Hall sensor, and two strain gauges were used for the instrumentation. We obtained strains exceeding 0.4% near the outward edge during the coil current charge from 350 A to 390 A, where the coil was exposed to external axial and radial magnetic fields of 13 T and 0.5 T. Post mortem results showed wavy plastic deformation, electrical damage, and REBCO defects. An elastic-plastic simulation reproduced the measured strains and predicted that ∼1 GPa stress is sufficient to induce ∼0.9% strain, thus validating our initial concerns with purely elastic models. This paper provides our experimental and simulation results.

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使用高应力 REBCO 线圈对应变超过 0.4% 的弹塑性导体损伤进行评估

最近关于高磁场 REBCO 磁体屏蔽电流应力模拟的报告经常显示峰值应力超过 1 GPa。然而，考虑到哈氏合金基材涂层导体的宏观屈服应力和断裂应力分别约为 900 兆帕和小于 1.1 GPa，这一结果很可能是纯弹性计算中不切实际的假象。在此，我们使用暴露在高场中的高应力 REBCO 线圈来评估应变超过 0.4% 的弹塑性导体损伤，以探索这种弹塑性机制。线圈位于低温超导体磁体的偏心位置，以便在增强的径向磁场中产生显著的屏蔽电流。仪器使用了电压抽头、霍尔传感器和两个应变计。在线圈电流从 350 A 充至 390 A 期间，我们在外缘附近获得了超过 0.4% 的应变，线圈暴露在 13 T 和 0.5 T 的外部轴向和径向磁场中。弹塑性模拟再现了测量到的应变，并预测 1 GPa 的应力足以引起 0.9% 的应变，从而验证了我们最初对纯弹性模型的担忧。本文提供了我们的实验和模拟结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Superconductor Science and Technology

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