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Thin CVD-diamond RF Pill-Box vacuum windows for LHCD systems

Authors :
Francesco Mirizzi
A. Cardinali
Silvio Ceccuzzi
Giuseppe Schettini
G. L. Ravera
R. Cesario
A. A. Tuccillo
Ravera, G.L.
Ravera, G. L.
Ceccuzzi, S.
Cardinali, A.
Cesario, R.
Mirizzi, F.
Schettini, G.
Tuccillo, A. A.
Source :
AIP Conference Proceedings.
Publication Year :
2014
Publisher :
American Institute of Physics, 2014.

Abstract

The preliminary assessment of a Lower Hybrid Current Drive (LHCD) system for the DEMOnstration power plant (DEMO) is mainly focused on the R&D needs of the less conventional RF components of the Main Transmission Line (MTL) and of the launcher. 500 kW, CW klystrons will be used to deliver the RF power to independent Passive Active Multijunction (PAM) launcher modules at 5 GHz. This paper describes the criteria followed to investigate the optimum solution for the RF window used as vacuum barrier between the MTL and the launcher, an open issue in the LHCD system for ITER too. The best candidate, capable of withstanding a power level of, or above, 0.5 MW in CW operation and to satisfy the electrical and thermonuclear requirements, is a Pill-Box assembly, based on a thin single disk of CVD-diamond as dielectric, water cooled at the edge. A thickness of 3 mm, much shorter than half a wavelength of the TE°11 mode in the dielectric as in the conventional window (unfeasible and too expensive with CVD-diamond at these frequencies), is sufficient to limit the exerted stress at the edge under the fracture stress for a maximum pressure applied of 0.9 MPa. In this paper the simulation results of conventional and thin CVD-diamond vacuum windows are presented comparing S-parameters, losses and electric fields in both matching condition and with VSWR = 2, using WR284 and WR229 as input/output rectangular waveguide. © 2014 American Institute of Physics.

Details

ISSN :
0094243X
Database :
OpenAIRE
Journal :
AIP Conference Proceedings
Accession number :
edsair.doi.dedup.....8996e72a8bed02ee7b7c282c32309ff3