Strategic cooperation in fusion technology research

By Joanne McIntyre, Stainless Steel World

It is the dream of mankind… unlimited energy without harming the environment. The team at Rolf Kind GmbH, based in the small town of Lindlar, approximately 40 km east of Cologne, Germany, works diligently every day to make this dream a reality in the hopefully not-too-distant future.

“Our components will help ignite a huge fire that has never been seen before, and our collaboration with CERN plays a crucial role in this process,” says Markus Kind, Commercial Director and one of the two shareholders in the family business. The fire refers to the last primary energy source that is known but not yet usable: nuclear fusion, the fusion of nuclei. Atoms are to be shot together with enormous forces in order to generate much more energy than that needed to produce the collisions. The power of the sun and stars, as the physicists say. Because in the sun, many billions of such nuclei fuse every second, releasing enormous amounts of heat in the process.

Markus Kind with a large stainless steel forging for a fusion machine magnet production. Photo courtesy of Rolf Kind.

High hopes for fusion

There are high hopes for nuclear fusion. Supporters describe a safe and inexhaustible source of energy that does not harm the environment. The fuel used in fusion, usually isotopes of hydrogen, does not release any greenhouse gases. This will be an advantage over fossil fuels. It is clear that the demand for electricity will grow enormously, not only in other regions of the world but also as a result of climate change. Renewable energies alone will not be able to meet this demand in the future. Unlike nuclear fission with uranium, for example, nuclear fusion produces virtually no radioactive waste.

Fusion research is likely to create a whole new industry for the construction and operation of tomorrow’s power plants. Startups, spin-offs of research institutes and industrial companies, are currently developing prototypes and raising funds from investors. In addition to the best-known project, the ITER fusion research reactor in Cadarache, France, there are approximately 40 fusion projects worldwide, primarily located in the USA, Germany, Japan, and China. Billions have already been invested.

Complex, heavy-duty forgings

For more than two decades, Rolf Kind GmbH has been supplying complex and heavy-duty forgings that help control the fusion fire, known as “plasma” to the experts, which provides the metallic structure around the powerful magnets. Over the years, the company has supplied more than 7,000 tons of stainless steel components for fusion projects all over the world.

“Fusion technology has the potential to become a real game changer and transform our planet for good”, explains Markus Kind. “If we succeed in bringing this technology to market maturity, we will have a safe, inexhaustible and reliable source of energy.”

However, the technical challenges are not easy. The forces experienced by the components in future fusion power plants will be enormous.

To address these challenges, the company has been working with experts from CERN for more than a year to test whether new stainless-steel grades can withstand these extreme loads. This collaboration has now been extended for another two years to test further candidate materials.

Inside CERN

CERN is one of the largest and most renowned institutes for basic research in fundamental physics in the world. Here, researchers search for the fundamental laws of the universe. To design, build and maintain the infrastructure needed to perform its unique experiments, CERN has a number of the world’s best experts in the field of materials science. The stainless steel produced by Rolf Kind GmbH can be tested at the laboratories at CERN at temperatures as low as 4K or -269°C. The superconducting magnets of the fusion power plants will later work with liquid helium at precisely this temperature.

“Our collaboration with CERN means working with one of the world’s most modern laboratories alongside experts with a wealth of expertise to find the right steel for the requirements of
the fusion power plants of tomorrow,” explains Markus Kind. “We have the technical expertise in material selection and forging technology and at CERN the material can be tested exactly according to our specifications.”

“Mechanical characterization at cryogenic temperatures has been essential for the construction of the Large Hadron Collider (LHC). A large amount of high strength structural materials were qualified through thousands of tests at cryogenic temperature”, says Stefano Sgobba, head of the Materials, Metrology and Non-Destructive Testing section of the Mechanical and Materials Engineering group at CERN.

“We are now thrilled that these unique facilities and know-how developed over several decades can contribute, together with Rolf Kind’s expertise in advanced forging technologies, to the future of such a promising energy source as nuclear fusion”, says Ignacio Aviles Santillana, responsible of the cryogenic mechanical testing activity of the section.

About this Tech Article

Appearing in the June 2025 issue of Stainless Steel World Magazine, this technical article is just one of many insightful articles we publish. Subscribe today to receive 10 issues a year, available monthly in print and digital formats. – SUBSCRIPTIONS TO OUR DIGITAL VERSION ARE NOW FREE.

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