부산대학교 도서관

The Magnetized Disc and Mirror Axion eXperiment (MADMAX) project aims at detecting axion dark matter in the mass range of 100 μeV. To facilitate axion to photon conversion with detectable rate, a superconducting dipole magnet with a large bore is needed. The MADMAX dipole magnet has to generate ∼9 T in a 1.35-m aperture over ∼1.3 m in length. A key challenge for a magnet made of a cable-in-conduit conductor (CICC) operating at 1.8 K with an indirect bath cooling is the quench detection. In order to validate feasibility, a mock-up coil with a quench behavior scalable to MADMAX was designed and produced. This article gives an overview of the technical details of the MAdmax Coil for Quench Understanding (MACQU) test coil. The conductor, magnet, busbar, and the supporting and cryogenic systems were designed at Commissariat à l'Énergie Atomique (CEA). The cable was manufactured in China at the Chang Tong, Inc. from WST Nb–Ti strands, and the insertion and compaction were achieved in the Academy of Science: Institute of Plasma Physics (ASIPP) with a copper profile from Aurubis. The winding of the coil and the busbar preforming were performed at Bilfinger Noell as well as the assembly of the supporting structure and the thermal shield. The magnet was integrated in the JT60 test station at CEA Saclay and extensively tested. The magnet current reached 80% on the load line instead of 90% as expected at nominal. The limitation is likely coming from uneven current distribution at the extremity of the magnet at the connection box location. Nevertheless, quench tests were successfully performed at constant currents from 10 to 17 kA. They proved that the initial quench velocities are of the order of 1–10 m/s, high enough to safely detect a voltage drop in MADMAX and discharge the magnet. In addition, a thermo-hydraulic quench back effect was observed in the MACQU coil cooled by superfluid helium.