This thesis reports the development of the world's first 5 T conduction-cooled metal-insulated (MI) wavelength shifter (WLS) magnet using high-temperature superconducting (HTS) technology. Overcoming key challenges such as Lorentz force-induced stress, screening current effects, and the limitations of liquid helium cooling, this study introduces a conduction-cooled MI HTS magnet with innovative electromagnetic, mechanical, and thermal design methods.
The research establishes core manufacturing technologies, including precision winding, jointing, and cryogenic integration, ensuring stable operation below 20 K. A 3D screening current-induced field analysis model is developed and experimentally validated, offering insights into field distortions and mitigation strategies.
Achieving a record 5 T field, this is the first domestically produced HTS WLS magnet. Its application in the Pohang Light Source II storage ring is expected to enhance photon brightness by 1,000 times at 100 keV, advancing next-generation accelerator technologies.
Introduction.- Theoretial Background.- Design and Analysis Methods of
Iron-core MI HTS WLS Magnet.- Core Manufacturing Technologies of HTS WLS
Magnet.- Construction of HTS WLS Magnet.- Conduction Cooling Test Results of
HTS WLS Magnet.- Conclusion.- Appendix.
Dr. Jeonghwan Park received his B.S. (2019) and Ph.D. (2024) degrees in Electrical Engineering and Computer Science from Seoul National University, Korea. He is currently with the Applied Superconductivity Center at Seoul National University as a postdoctoral researcher. His research interests include large-scale superconducting machines such as high-field magnets and particle accelerator magnets. His expertise covers design, multi-physics analysis, and manufacturing of high-temperature superconductor magnets.
