Non-uniform current distribution in parallel-wound no-insulation high-temperature superconductor coil during ramping and fast discharging operations

Fu, Yutong; Wang, Yawei; Peng, Weihang; Zhao, Yue; Ma, Guangtong; Jin, Zhijian

doi:10.1088/1361-6668/acff26

Cited by 4 publications

(1 citation statement)

References 49 publications

(53 reference statements)

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“…Multi-tape-bundled REBCO tape windings, as a kind of NI windings, have recently been employed for large-scale REBCO magnets to improve the current characteristics, especially for a short excitation delay [18], [19]. It was reported that the tape-longitudinal currents were unbalanced within bundled tapes during a magnetic field excitation as well as de-excitation [20], [21]. The unbalanced current may deteriorate the thermal stability on the coil, whereas further investigations on the coil stability are needed (e.g., the current distribution during the sudden discharging).…”

Section: Introductionmentioning

confidence: 99%

Numerical Investigation on Current Behaviors of NI/PI REBCO Coils Wound with Many Bundled Tapes for Sudden Discharge

Sato,

Ishiyama,

Noguchi

2024

J. Phys.: Conf. Ser.

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For future applications such as compact fusion reactors, it is necessary to investigate some characteristics of meter-class D-shaped no-insulation (NI) REBCO coils. In recent years, several kinds of NI winding techniques, such as multi-tape-bundled REBCO tapes and a partial-insulation winding technique, have been proposed and experimented to improve the current characteristics of REBCO coils, such as an excitation delay and a large induced current. In this paper, the sudden discharging has been simulated to investigate not only the current behaviors but also the Joule heats for meter-class D-shaped REBCO coils with a few different NI winding techniques: (1) complete no-insulation between tape-to-tape/turn-to-turn for multi-tape-bundled windings and (2) partial-insulation for turn-to-turn of multi-tape-bundled windings without tape-to-tape insulation. The simulation results show that the amount of Joule heats emitted in a short time is large for many-tape-bundled NI REBCO coils. Also, the simulation result show that the greater number of tapes bundled on an NI REBCO coil, the more unbalanced current distributions are observed among the bundled tapes. Furthermore, the partial-insulation REBCO coils show a particular current distribution. These results reveal that cooling systems should be considered depending on the winding techniques.

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