铌三锡管内电缆导体交流损耗计算分析模型

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摘要为解决快变磁场中大电流和应变作用下, 铌三锡(Nb₃Sn)导体交流(Alternating Current, AC)损耗的模拟实验分析问题, 本文进行了瞬变电磁场中宽应变区间的AC损耗计算技术探索, 构建应变作用下的临界电流数学模型, 把复杂变化场中基于应变的临界电流密度运用到磁滞损耗功率计算, 对耦合损耗功率计算中的导体特征参数考虑应变效应, 获得CICC导体AC损耗功率计算技术。在激发等离子体的快速励磁以及等离子体放电和破灭等情况下, 由模拟对比分析发现应变作用算法的AC损耗功率更接近工程实际值;对比应变作用算法损耗功率和经典算法损耗功率的相对误差计算, 其误差的变化小于15%。

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	蒋华伟
	李国平
	武松涛
	赵玉娟
	刘继承

关键词 ：铌三锡, 管内电缆导体, 应变, 交流损耗

Abstract：To solve the problem of alternating current (AC) loss mechanism for Nb₃Sn conductor with strain under the condition of high-current and transient magnetic field, research of AC loss calculation method is carried out in the transient electromagnetic field and wide range of strain. The mathematical model of the critical current with effect of strain is built. Moreover, the critical current density based on strain is introduced for the calculation of hysteresis loss power. Taking into account strain effects, the characteristic parameters are obtained, and the calculation technology of CICC AC loss power is obtained. By comparative analysis of simulation, it is found that the AC loss power calculation of the conductor with strain model is close to the actual project value. For rapid excitation, in particular plasma discharge and burst, strain model and the traditional algorithm is consistent. From the calculation of AC loss power, it can be seen that the relative error is less than 15%.

Key words： NbSn cable-in-conduit conductor(CICC) strain AC loss

收稿日期: 2012-10-08 出版日期: 2014-03-25

PACS:	TM461
	TP392

基金资助:国际科技合作重点项目计划(2004CB720704)和河南省高等学校青年骨干教师资助计划(2010GGJS-088)资助项目

作者简介: 蒋华伟男, 1970年生, 博士, 教授, 研究生导师。研究方向为超导电电缆仿真设计。李国平男, 1978年生, 硕士研究生, 讲师, 研究方向为人工智能。

引用本文:

蒋华伟, 李国平, 武松涛, 赵玉娟, 刘继承. 铌三锡管内电缆导体交流损耗计算分析模型[J]. 电工技术学报, 2013, 28(8): 20-25. Jiang Huawei, Li Guoping, Wu Songtao, Zhao Yujuan, Liu Jicheng. Calculation and Analysis Model of AC Loss forNb₃Sn-Based CICC. Transactions of China Electrotechnical Society, 2013, 28(8): 20-25.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2013/V28/I8/20

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