Building the heartbeat of ITER: Preparing a unique fabrication line for the central solenoid modules

A partial view of the General Atomics module fabrication line, with two winding station tables visible behind a yellow rail. Photo: GA
A partial view of the General Atomics module fabrication line, with two winding station tables visible behind a yellow rail. Photo: GA Photo: General Atomics

Lynne Degitz 

With winding of the first production module for ITER’s central solenoid well underway, US ITER and its contractor, General Atomics, are now commissioning all of the necessary tooling stations for the 13 Tesla 1,000 metric ton electromagnet. Eleven unique stations will form the module manufacturing line at the GA Magnet Technologies Center, a first-of-a-kind facility in Poway, Calif. US ITER, managed by Oak Ridge National Laboratory, is the project office for US contributions to the international ITER fusion reactor now under construction in France.

One challenge to commissioning the unique stations is coming up with an appropriate coil that does not use any production conductor. The commissioning process requires a variety of trials to assure that the tooling will perform specific fabrication tasks as predicted. After commissioning, the workstation undergoes a manufacturing readiness review. 

“General Atomics has been very clever,” said US ITER central solenoid systems manager David Everitt. “They made what we call a ‘Frankenstein-coil’ to test and commission numerous stations. This commissioning coil is made out of qualification samples of real conductor which were coupled with other samples such as empty jacket material.”

The commissioning coil is two layers high with real conductor on a portion of one layer of the coil.

“When you see everything that happens at General Atomics every day, you appreciate that they have a very talented crew out there. We have an innovative team who is highly invested in the project,” said Everitt.

So far, the coil has been used for commissioning activities at stations for joint and terminals preparation, stacking, joining plus helium penetrations, reaction heat treatment and part of turn insulation. All or part of ten of eleven stations are now in place at GA and eight of these stations have completed some or all acceptance testing and commissioning activities.

The turn insulation station will wrap fiberglass insulation tape around the wound conductor coils. Photo: GA
The turn insulation station will wrap fiberglass insulation tape around the wound conductor coils. Photo: GA

One of the more complex stations to install and commission handles turn insulation. This workstation wraps insulating fiberglass tape and Kapton around the conductor after the coils have been wound and heat treated. In order to wrap the conductor, the coil must be “un-sprung” for insulation wrapping and then reassembled. After insulation is completed, the coils move down the production line to the vacuum pressure impregnation station, where a three-part epoxy mixture is injected under vacuum to impregnate the previously applied turn and ground insulation materials that surround the coil. The epoxy provides both electrical insulation and structural support to the 110 metric ton magnet module. 

A major investment has been the construction of a cold testing facility for the final testing of each module at 4 Kelvin, comparable to ITER’s operating temperature for the central solenoid. Commissioning of the cold testing facility is planned for early 2016, and equipment installation has begun. 

As the home of the DIII-D National Fusion Facility, funded by the Department of Energy through the Office of Fusion Energy Sciences, GA has a half-century long history with fusion. The Magnet Technologies Center has not only a 4 Kelvin cryogenic system needed for superconducting magnets, but also a large vacuum cryostat for testing magnets, a 50 kA, 10 V power supply, and a fast discharge dump circuit for magnet protection. 

The vacuum pressure impregnation station includes a resin reservoir (foreground) and a vacuum chamber that can hold a seven foot tall module. Photo:GA
The vacuum pressure impregnation station includes a resin reservoir (foreground) and a vacuum chamber that can hold a seven foot tall module. Photo:GA

US participation in ITER is sponsored by the U.S. Department of Energy Office of Science (Fusion Energy Sciences) and managed by Oak Ridge National Laboratory in Tennessee, with contributions by partner labs Princeton Plasma Physics Laboratory and Savannah River National Laboratory. For more information, see usiter.org. ORNL is supported by the DOE Office of Science. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, see science.energy.gov. 

Media Contact: Lynne Degitz