D-shaped coils will be tested at 4 K
The ITER superconducting magnets will operate at 4 K (minus 269 °C, a temperature barely above absolute zero) and will carry extremely strong electrical current (up to 68 kA). How will these first-of-kind components behave in such extreme conditions? Part of the question can be answered by testing the magnets at 80 K (minus 194 °C), which is not overly complex or costly and reproduces 90 % of the thermal and mechanical constraints a coil will be exposed to during its lifetime. However, as superconductivity is only established when a magnet is brought to 4 K, a test at 80 K says nothing about the electrical behaviour of a coil under operating conditions. Although not planned initially, a window of opportunity has just opened for testing some of the ITER coils at 4 K—a big project within the project.
All six ITER ring-shaped poloidal field coils and 14 out of 19 D-shaped toroidal field coils will have been tested at the more clement temperature of 80 K before their installation in the ITER machine. Testing at 4 K, however, was only done for the US-procured central solenoid modules. "US ITER demanded that a full-current 4 K factory acceptance test be performed on each central solenoid module before shipment to ITER," says Neil Mitchell, ITER's historical magnet expert. "It definitely made sense as a 4 K test can achieve conditions pretty close to a module's operating point in ITER."
For reasons that have to do with size, shape, the nature of the conductor and with how individual magnets (central solenoid modules or single toroidal field coil) contribute to the total field generated by the coil arrangement (6 stacked modules in one case, 18 coils circling the vacuum vessel in the other), a 4 K test on a toroidal field coil does not completely reproduce the actual conditions the coil will face during the machine's operational phase.
It has, however, an important virtue: it enables the testing of the strategic joints that connect the seven double pancakes that constitute a toroidal field coil. "Making these joints is a hand operation and although we take lots of precautions, deviations are always possible."
Proceeding to 4 K tests has long been discussed inside ITER. For years, experts and management have confronted their analyses and debated the pros and cons. Confidence in the manufacturing process and other considerations eventually led to the decision not to proceed.
"Although we are not starting from scratch—coils at JT60-SA and W7-X have been tested at 4 K—the size of the ITER coils and hence the dimensioning of the installation present considerable challenges. Also, we need to finalize the facility in two years when it would normally take twice that time," says David.
But things are moving quickly. The project is presently in its preliminary design phase and the main contracts are already being signed. After a final design review, planned next April, the installation's assembly phase could begin in the first months of 2025 and operation by the end of that year.
"Considering that by that time one or two sector modules will already be installed in the assembly pit, and that a complete cold test at 4 K requires 4 to 6 months, the plan is to test at least one coil from each manufacturer (Mitsubishi and Toshiba in Japan; ASG-SIMIC in Europe)," says David.
The installation and its 350-tonne cryostat (11 m x 22 m—the widest and longest load to travel the ITER Itinerary) will be located in the vacated eastern part of the winding facility used by the European Domestic Agency to fabricate four largest poloidal field coils, and which is still equipped with powerful lifting systems. As a side benefit to building the cold test facility for the toroidal field coils, the size of installation's cryostat will allow for the testing at 4 K of PF1 from Russia, the smallest of the tokamak's six poloidal field coils.