超导直流能源管道载流导体设计

黄伟灿; 蒋晓华; 薛芃; 李欣阳; 沈稚栋; 孙宇光

doi:10.16511/j.cnki.qhdxxb.2021.26.034

清华大学学报（自然科学版） >

2022 , Vol. 62 >Issue 10: 1715 - 1720

DOI: https://doi.org/10.16511/j.cnki.qhdxxb.2021.26.034

电机工程

超导直流能源管道载流导体设计

黄伟灿 ,
蒋晓华 ,
薛芃 ,
李欣阳 ,
沈稚栋 ,
孙宇光

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清华大学电机工程与应用电子技术系, 电力系统及大型发电设备安全控制和仿真国家重点实验室, 北京 100084

收稿日期: 2021-05-25

网络出版日期: 2022-09-03

基金资助

孙宇光,副教授,E-mail:sunyuguang98@mails.tsinghua.edu.cn

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Conductor design in bipolar superconducting DC energy pipelines

HUANG Weican ,
JIANG Xiaohua ,
XUE Peng ,
LI Xinyang ,
SHEN Zhidong ,
SUN Yuguang

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State Key Laboratory of Control and Simulation of Power Systems and Generation Equipment, Department of Electrical Engineering, Tsinghua University, Beijing 100084, China

Received date: 2021-05-25

Online published: 2022-09-03

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摘要

超导直流能源管道将高温超导直流输电技术和长距离液化天然气管道输送技术结合为一体,管道中流动的液化天然气起到超导电缆制冷剂的作用,能够大幅提高能量的输送密度和效率。为保证大容量超导输电系统在直流能源管道这种特殊运行工况下的安全可靠运行,有必要研究其中载流导体的设计方法。该文分析了能源管道运行温区中超导带材临界电流密度受磁场影响的衰减情况和铜支撑骨架在超导电缆短路失超中所起的作用。对±10 kV/1 kA双极同轴超导直流能源管道的载流导体进行了优化设计,得到单极电缆所需的超导带材最少数量为12根,铜支撑体最小截面积为1.48×10^-4m²。通过有限元仿真,验证了超导能源管道中的载流导体优化方案在短路故障下的热稳定性。该载流导体设计方法对于不同电压电流等级和管道结构的超导直流能源管道设计也具有普适意义。

关键词： 高温超导带材; 有限元仿真; 热稳定性; 超导直流能源管道

本文引用格式

黄伟灿 , 蒋晓华 , 薛芃 , 李欣阳 , 沈稚栋 , 孙宇光 . 超导直流能源管道载流导体设计[J]. 清华大学学报（自然科学版）, 2022 , 62(10) : 1715 -1720 . DOI: 10.16511/j.cnki.qhdxxb.2021.26.034

Abstract

Superconducting DC energy pipelines combine high temperature superconducting (HTS) DC transmission lines with long-distance liquefied natural gas (LNG) transmission lines where the flowing LNG acts as the refrigerant for the superconducting cable in the pipeline.This greatly increases the overall system energy transmission density and efficiency.The conductors then need to be carefully designed to ensure the safety and reliability of the high-capacity superconducting transmission system for the special operating conditions of superconducting DC energy pipelines.This study analyzed the critical current density degradations of the high temperature superconducting tapes influenced by the magnetic fields at the pipeline operating temperature and the effects of the copper former during short-circuit faults in the superconducting cable.The analysis was then used to optimize the conductor design of a ±10 kV/1 kA bipolar coaxial superconducting DC energy pipeline.The results indicate that at least 12 HTS tapes are required for a single pole and the minimum cross-sectional area of the copper former is 1.48×10^-4 m².The thermal stability of the superconducting DC energy pipeline during a short-circuit fault was then verified by finite element simulations.The conductor design method presented in this paper is also applicable to the design of superconducting DC energy pipelines with various voltage and current levels and pipeline structures.

Key words： high temperature superconducting (HTS) tapes; finite element simulation; thermal stability; superconducting DC energy pipeline

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