Abstract

We have developed a novel critical current and stability measurement experimental setup, which utilizes a closed electric circuit with a multi-strand superconducting cable. The feature of this setup is mechanical loading appliedtothe multi-strand cablein thetransversedirection. It wasreported that Lorentz forces causeddegradation in the critical current of the ITER-TFMC conductor. Furthermore, these phenomena were mainly observed in the ITER full-size conductors with large Lorentz forces under high magnetic fields. The advantage of our setup is critical current measurement under mechanical stresses comparable to those in the full-size conductor under high magnetic fields. By employing an inductive critical current measurement technique, we conducted an experiment with a transport current of about 10kA without any power supply or current leads. In our experiments, we observed significant degradation in critical currents due to a compressive stress of about 30MPa. We applied an innovative technique to mitigate the critical current degradation in mechanically loaded Nb3Sn superconducting multi-strand cables. We molded one such cable with ice and tested it. No degradation occurred in the icemolded cable. In addition, stability was also ensured due to the large thermal conductivity of ice. Thus, we have successfully mitigated the degradation in the critical current of the Nb3Sn conductor by ice molding. c

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