 |
 |
 |
Abstract. The magnet design of the new ITER-FEAT machine comprises 18
Toroidal Field (TF) coils, a Central Solenoid (CS), 6 Poloidal Field (PF)
coils and Correction Coils (CCs). A key driver of this new design is the
requirement to generate and control plasmas with a relatively high
elongation (
k95 = 1.7) and a relatively high triangularity
(
= 0.35). This has lead to a design where the CS is
vertically segmented and self-standing and the TF coils are wedged along
their inboard legs. Another important design driver is to achieve a high
operational reliability of the magnets, and this has resulted in several
unconventional designs, and in particular, the use of conductors supported
in radial plates for the winding pack of the TF coils. A key mechanical
issue is the cyclic loading of the TF coil cases due to the out-of-plane
loads which result from the interaction of the TF coil current and the
poloidal field. These loads are resisted by a combination of shear keys and
``pre-compression'' rings able to provide a centripetal preload at assembly.
The fatigue life of the CS conductor jacket is another issue as it
determines the CS performance in terms of the flux generation. Two jacket
materials and designs are under study. Since 1993, the ITER magnet R&D
programme has been focussed on the manufacture and testing of a CS and a TF
model coil. During its testing, the CS model coil has successfully achieved
all its performance targets in DC and AC operations. The manufacture of the
TF model coil is complete. The manufacture of segments of the full scale TF
coil case is another important and successful part of this programme and is
near completion. New R&D effort is now being initiated to cover specific
aspects of the ITER-FEAT design.
IAEA 2001
