Performance Evaluation of Current Leads for a 5 Tesla Electromagnetic Properties Measurement System

Yeon Suk Choi,Young Jin Hwang,Jae Young Jang,Myung Su Kim

doi:10.3390/app10196712

Yeon Suk Choi, Young Jin Hwang + Show 2 more

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https://doi.org/10.3390/app10196712

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Journal: Applied Sciences	Publication Date: Sep 25, 2020
Citations: 4	License type: CC BY 4.0

Affiliation: Korea Basic Science Institute

Abstract

The development of the Electromagnetic Property Measurement System is underway at the Korea Basic Science Institute. The Electromagnetic Property Measurement System is used for electrical, thermal, and magnetic specimen property measurements in variable magnetic fields and temperatures with a low-temperature superconducting magnet. To activate low-temperature superconducting magnet that operates with liquid helium, we propose the use of vapor-cooled current leads. The low-temperature superconducting magnet is connected to the power supply at room temperature through a pair of current leads. Accordingly, heat inflows through the current leads and represents one of the major contributory factors of the entire heat inflow. Therefore, design optimization and evaluation of the current leads is necessary to minimize heat and liquid helium consumption. Vapor-cooled, and hybrid current leads were designed and fabricated, and testing in liquid helium cryostat was conducted. The low-temperature superconducting magnet was charged with electrical current up to the operating level, and the liquid helium boil-off rate was measured with respect to the supplied electrical current level. The performances of the two current leads were accessed based on the thermal load and boil-off rate of the liquid helium. The experimental and analyzed liquid helium boil-off rates associated with the current leads were in close agreement.

Highlights

Increased magnetic fields required for power applications are generated by superconducting magnets
The objective of the project is the development of an efficient low temperature superconducting (LTS) magnet system cooled by continuous liquid helium
We successfully designed, fabricated, and tested current leads used for the generation of magnetic field in superconducting magnet systems

Summary

Introduction

Increased magnetic fields required for power applications are generated by superconducting magnets. Superconducting magnets are usually activated by currents supplied from a power source at room temperature [1]. The power source must be connected to the superconducting magnet by a pair of current leads with the operating temperatures in a range between room temperature and 4.2 K. The use of superconducting devices for energy application has attracted considerable attention because it generates relatively high-magnetic field strengths as compared with the conventional power device [2]. Zhu et al demonstrated the implementation and use of a high-temperature superconducting energy storage system for renewable power grids. They used yittrium barium copper oxide (YBCO)

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