Energy and powerNewsPower transmission

CABLEGNOSIS project to study superconducting cable technologies

CABLEGNOSIS project to study superconducting cable technologies

Picture courtesy Glasgow University, via ASG Superconductors.

Researchers from the University of Glasgow are lending their expertise to CABLEGNOSIS, a new European project which aims to study and advance the role of superconducting cable technologies.

Principal investigator Dr Mohammad Yazdani-Asrami and co-investigator Dr Wenjuan Song of the James Watt School of Engineering will lead the Glasgow University’s contribution to the Life Cycle Centre for Power CABLE diagnosis project (CABLEGNOSIS).

CABLEGNOSIS, which is supported by €6 million (£5 million; $6.3 million) in funding from the HORIZON Research and Innovation Action, kicked off this year in September, bringing together 17 partners from five countries to study and develop superconducting cable technology.

The project aims to develop advanced insulation and conductor design technologies, high-performance and environmentally friendly cable insulation materials and ageing studies of conventional and superconducting cables.

Additionally, the project will explore recyclability technologies for power cable materials and introduce Al-based tools for pre-fault condition monitoring, ageing analysis and remote diagnostics.

The University of Glasgow will support the project’s aims by developing predictive maintenance models for superconducting cables, which require cooling to extremely low temperatures of around minus 250 degrees Celsius in order to transmit electricity with virtually no resistance.

The CABLEGNOSIS project officially kicked off on 17-18th of September 2024. Image courtesy CABLEGNOSIS

The researchers will develop AI-based models to study how the cables, made from an advanced superconducting material called magnesium diboride (MgB2), will age during long-term exposure to hydrogen gas.

Their models will be tested and validated in specially designed laboratory tests, where they will be aged in a hydrogen cryostat – a piece of equipment which mimics the low temperatures they will be exposed to in the real world.

Their results will help guide the future process of estimating the health of superconducting cables, allowing power providers to predict when maintenance might be needed and minimise maintenance cost as well as downtime across the grid.

Have you read:
Oman’s OAPIL ventures into advanced conductor manufacturing
How advanced conductors solve four key grid challenges

Dr Yazdani-Asrami said: “The James Watt School of Engineering is uniquely well-placed to contribute to this aspect of the development of AI-based models for superconducting cables in CABLEGNOSIS, which is one of the world’s biggest projects in superconducting cable research.

Picture courtesy Glasgow University, via ASG Superconductors – 1GW superconducting cable for the transport of energy without dispersion and with reduced ecological footprint, IRIS project – INFN.

“Understanding how these cables age is crucial for their practical implementation, but we don’t know for sure yet how MgB2 and high temperature superconductors will be affected by long-term exposure to hydrogen at low temperatures.

However, we do know that if a superconducting cable’s performance degrades significantly after life cycles, it could mean replacing infrastructure years earlier than planned, leading to increased costs and potential disruption to power supplies.

“Our research will help energy providers better predict when maintenance is needed, making these systems more reliable and cost-effective. The models we develop will shed new light on the aging mechanism in the superconducting cable. Ultimately, this will accelerate the development of life estimation tools which will create substantial impact in the future design and operation of superconducting cables in a wide range of energy applications.”

Added Dr Song: “This research will be an important part of the work across the CABLEGNOSIS consortium, but it has implications beyond just power transmission.

“The techniques and models we’re developing could help inform how similar technology might be used in other sectors, from the development of electric aircraft to fusion energy reactors, both of which will rely on superconducting cables and technology too. Getting this correct now is essential to boost the transition to net-zero energy target across the Scotland, the UK and Europe.”

The project is the latest development in the University of Glasgow’s broad base of net-zero research, which includes multidisciplinary projects at the Glasgow Centre for Sustainable Solutions and the Glasgow Centre for Sustainable Energy.

The University has pledged to reach net-zero emissions by 2030.