T. Mutoh et al., Steady-state tests of high-voltage ceramic feedthroughs and coaxial transmission line for ICRF heating system of the large helical device, FUSION TECH, 35(3), 1999, pp. 297-308
Steady-state ion cyclotron range of frequency (ICRF) heating technologies h
ave been developed to heat plasma for >30 min in the Large Helical Device (
LHD). Steady-state-operation tests of high voltages up to 40 kV(Op) for >30
min were carried out on radio-frequency (rf) vacuum feedthroughs and a coa
xial transmission line in a test set. Four types of ceramic feedthroughs, e
ach having a 240-mm diameter were tested. Cone-type alumina ceramic and cyl
inder-type silicon nitride composite-ceramic feedthroughs produced good per
formances of 40 kV/30 min and 50 kV/10 s. The others had vacuum leaks when
subjected to long-pulse duration. The temperature of the cone-type alumina
ceramic feedthrough was measured during the ICRF operations. By using gas-c
ooling techniques, the temperature increase of the ceramic was substantiall
y reduced and saturated within 20 min. Without any gas-cooling techniques,
the temperature increased linearly and did not saturate. Therefore, this ap
proach could not be used for steady-state operation. The rf dissipation on
the ceramic was calculated using the ANSYS finite element computer code. It
was found that damaged feedthroughs had local high heat spots, which could
result in vacuum leaks. A 240-mm-diam water-cooled coaxial transmission li
ne was designed and tested for steady-state operation. Specially designed c
onnector components and Teflon insulator disks were tested. During the test
operation, the insulation gases of nitrogen, sulfur hexafluoride, and carb
on dioxide were used to compare their insulation capabilities for steady st
ate. For the duration of a 10-s pulse, these gases performed well up to 60
kV(Op). However, for steady-state operation, carbon dioxide gas could not w
ithstand voltages >40 kV(Op). The connector components of the transmission
line performed without problems below 50 kV(Op) and 1 kA(Op) for 30-min ste
ady-state operation. The performance of the feedthroughs and transmission l
ine exceeded the specifications for steady-state heating in the LHD.