Temperature- and field-dependent characterization of a conductor on round core cable

TL;DR

This study characterizes a high-temperature superconductor CORC cable under various conditions, demonstrating its performance stability and field- and temperature-dependent behavior relevant for high-field magnet applications.

Contribution

It provides comprehensive experimental data on CORC cable performance under mechanical, magnetic, and thermal stresses, including rapid current changes, with comparison to single tape data.

Findings

CORC cable performance remains stable under rapid current changes.

Performance correlates well with single tape data across conditions.

Transverse Lorentz forces impact the cable's current capacity.

Abstract

The conductor on round core (CORC) cable is one of the major high temperature superconductor cable concepts combining scalability, flexibility, mechanical strength, ease of fabrication and high current density; making it a possible candidate as conductor for large, high field magnets. To simulate the boundary conditions of such magnets as well as the temperature dependence of CORC cables a 1.16 m long sample consisting of 15, 4 mm wide SuperPower REBCO tapes was characterized using the 'FBI' (force-field-current) superconductor test facility. In a five step investigation, the CORC cable's performance was determined at different transverse mechanical loads, magnetic background fields and temperatures as well as its response to swift current changes. In the first step, the sample's 77 K, self-field current was measured in a liquid nitrogen bath. In the second step, the temperature dependence was measured at self-field condition and compared with extrapolated single tape data. In the third step, the magnetic background field was repeatedly cycled while measuring the current carrying capabilities to determine the impact of transverse Lorentz forces on the CORC cable sample's performance. In the fourth step, the sample's current carrying capabilities were measured at different fields (2-12 T) and temperatures (4.2-51.5 K). Through finite element method simulations, the surface temperatures are converted into average sample temperatures and the gained field- and temperature dependence is compared with extrapolated single tape data. In the fifth step, the response of the CORC cable sample to rapid current changes (8.3 kA/s) was observed with a fast data acquisition system. During these tests, the sample performance remains constant. The sample's measured current carrying capabilities correlate to those of single tapes assuming field- and temperature dependence as published by the manufacturer.