Differentiation of Performance‐Limiting Voltage Transients during Nb3Sn Magnet Testing

Advances in cryogenic engineering Pub Date : 2006-04-21 DOI:10.1063/1.2192394

A. Lietzke, S. Mattafirri, A. Mcinturff, M. Nyman, D. Dietderich, S. Gourlay, G. Sabbi

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引用次数: 14

Abstract

The Superconducting Magnet Group at Lawrence Berkeley National Laboratory has been developing high‐field, brittle‐superconductor, accelerator magnet technology for several years. While recent dramatic increases in Nb3Sn superconducting current density, (Jc = 3000 A/mm2 at 12 Tesla, 4.2 K) have facilitated the achievement of record peak dipole bore‐fields (16 Tesla), the number and size of fast intra‐coil flux‐adjustments of the “flux‐jump” variety have increased with the current density. In 2000, with state‐of‐the art (Jc = 2000 A/mm2 at 12 T) Nb3Sn conductor, the associated coil voltage transients were observed to be large enough to cause nuisance “quench‐detector” magnet‐protection false‐alarms. Subsequent Jc increases have resulted in large enough flux‐jumps to cause premature quenches in some magnets, at currents well below those predicted by their virgin strand superconducting “short‐sample” measurements.This paper will examine various types of quench‐onsets and their distinguishing characteristics. ...

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Nb3Sn磁体测试中性能限制电压瞬变的差异

劳伦斯伯克利国家实验室的超导磁体小组多年来一直在开发高场、脆性超导体、加速器磁体技术。虽然最近Nb3Sn超导电流密度的急剧增加(在12特斯拉，4.2 K时，Jc = 3000 A/mm2)促进了偶极子钻孔场的创纪录峰值(16特斯拉)，但“磁通跳变”的快速线圈内磁通调节的数量和大小随着电流密度的增加而增加。在2000年，使用最先进的(12 T时Jc = 2000 A/mm2) Nb3Sn导体，观察到相关线圈电压瞬变大到足以引起“猝灭检测器”磁保护误报警。随后的Jc增加导致了足够大的通量跳跃，导致一些磁体在远低于其原始链超导“短样本”测量所预测的电流下过早淬火。本文将研究各种类型的淬火和他们的特点. ...

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Advances in cryogenic engineering

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