Demonstration of a three-dimensional current mapping technique around a superconductor in a prototype of a conventional superconducting fault current limiter

TL;DR

This paper presents a novel three-dimensional current mapping technique using Hall sensors around a superconductor, enabling real-time detection of current distribution and potential instabilities in superconducting fault current limiters.

Contribution

It introduces a new 3D current mapping method with Hall sensors for superconductors, allowing real-time monitoring and early detection of instabilities in superconducting devices.

Findings

Non-uniform current flow exists below critical current.

Real-time 3D mapping detects hotspots and instabilities.

Technique offers user-settable fault current thresholds.

Abstract

Here we describe a three-dimensional current mapping technology developed for a superconductor using an array of Hall sensors distributed around it. We demonstrate this in a prototype similar to a conventional resistive superconducting fault current limiter (SCFCL). By calibrating the Hall sensor voltage, we can directly measure the distribution of the currents in the superconductor and the shunt. Using pulsed measurements, we measure the fractions of current distributed between the superconductor and shunt resistor parallel combination when a fault-like condition is mimicked in the system. Using the Hall array measurements, we generate a real-time three-dimensional map of local average current distribution around the superconductor used in our prototype of SCFCL. Our measurements show that, even for currents less than the critical current a non-uniform current flow pattern exists around the superconductor which we have used in the prototype. The capability of real-time, three-dimensional monitoring of the average local current distribution offers a way for the early detection of instabilities like hotspots developing in a superconductor. We discuss the use of this technique to not only show how it offers early detection and protection against instabilities developing in the superconductor, but also how it offers an added flexibility, namely, a user-settable fault current threshold.