| Autor: |
Whyte, D. G., LaBombard, B., Doody, J., Golfinopolous, T., Granetz, R., Lammi, C., Lane-Walsh, S., Michael, P., Mouratidis, T., Mumgaard, R., Muncks, J. P., Nash, D., Riva, N., Santoro, F., Sattarov, A., Stillerman, J., Uppalapati, K., Vieira, R., Watterson, A., Wilcox, S., Hartwig, Z. S. |
| Zdroj: |
IEEE Transactions on Applied Superconductivity; 2024, Vol. 34 Issue: 2 p1-18, 18p |
| Abstrakt: |
In this article, the SPARC Toroidal Field Model Coil (TFMC) experimental tests are described. The tests include detailed comparisons to a hierarchy of electromagnetic and structural models of the coil. The tests confirm the ability of the no-insulation no-twist (NINT) configuration to provide highly stable dc operations with peak magnetic field in excess of 20 T at the rare earth yttrium barium copper oxide (REBCO) tape stacks. The advantages of the modular TFMC approach are validated including the ability to test and probe the REBCO and structural response of the coil in stages, a strategy that will be applied to large-scale coil production for SPARC. The electromagnetic models show high fidelity agreement to the dc and charging coil performance in terms of current distribution, voltages, and heating. The transient response of the TFMC to open-circuit events is examined. The coil exhibits the positive features of the NINT design with very low induced voltages and a predictable redistribution of current and resulting volumetric heating. However, highly localized damage occurs during a programmed open circuit at operational conditions similar to those used in the SPARC tokamak, in agreement with calibrated electromagnetic models. This reveals the cause and remedy to the thermal instability that gives rise to the damage. Therefore, the conclusion of the tests is that the NINT TFMC is confirmed as meeting the programmatic requirements for SPARC and, more generally, for high-field tokamaks. |
| Databáze: |
Supplemental Index |
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