Roebel cables from REBCO coated conductors: a one-century-old concept for the superconductivity of the future

TL;DR

This paper reviews the development, manufacturing, and characterization of REBCO Roebel cables, highlighting their potential for efficient high-current superconducting applications and their historical evolution from copper cable designs.

Contribution

It provides a comprehensive overview of HTS Roebel cables from REBCO conductors, summarizing recent advancements and serving as a guide for users and developers.

Findings

Successful manufacturing of REBCO Roebel cables with high current capacity

Low AC losses achieved in developed cable variants

Flexible design options for specific applications

Abstract

Energy applications employing high-temperature superconductors (HTS), such as motors/generators, transformers, transmission lines and fault current limiters, are usually operated in the alternate current (AC) regime. In order to be efficient, the HTS devices need to have a sufficiently low value of AC loss, in addition to the necessary current-carrying capacity. Most applications are operated with currents beyond the current capacity of single conductors and consequently require cabled conductor solutions with much higher current carrying capacity, from a few kA to up to 20-30 kA for large hydro-generators. A century ago, in 1914, Ludwig Roebel invented a low-loss cable design for copper cables, which was successively named after him. The main idea behind Roebel cables is to separate the current in different strands and to provide a full transposition of the strands along the cable direction. Nowadays, these cables are commonly used in the stator of large generators. Based on the same design concept of their conventional material counterparts, HTS Roebel cables from REBCO coated conductors were first manufactured at the Karlsruhe Institute of Technology (KIT) and have been successively developed in a number of varieties that provide all the required technical features such as fully transposed strands, high transport currents and low AC losses, yet retaining enough flexibility for a specific cable design. In the past few years a large number of scientific papers have been published on the concept, manufacturing and characterization of such cables. Times are therefore mature for a review of those results. The goal is to provide an overview and a succinct and easy-to-consult guide for users, developers, and manufacturers of this kind of HTS cables.