1. Diplexers for power combination and switching in high power ECRH system
- Author
-
Bruschi, A., Erckmann, V., Kasparek, W., Petelin, M. I., Thumm, M., Bin, W., Cirant, S., D'Arcangelo, O., Hollmann, F., Lubyako, L., Noke, F., Plaum, B., Purps, F., Zohm, H., ECRH Team at IPP Greifswald, and ECRH Team at IPP Greifswald
- Subjects
Physics ,Diplexers ,Millimeter wave switches ,Plasma control ,Nuclear and High Energy Physics ,business.industry ,Electrical engineering ,Plasma heating ,Power combiners ,Condensed Matter Physics ,Power (physics) ,law.invention ,Resonator ,Electric power system ,Electricity generation ,Electric power transmission ,law ,Gyrotron ,Power dividers and directional couplers ,Resonators ,business ,Diplexer - Abstract
Electron Cyclotron Resonance Heating (ECRH) systems for next step large fusion-devices operate at a Continuous Wave (CW) power well beyond 10 MW generated by a large number of gyrotrons with typically 1 MW power per unit. The combination of the power of two (or more) gyrotrons and switching of the power between different launchers for different physics applications is an attractive feature for such systems. The combination of beams from different gyrotrons would reduce the number of transmission lines and the requirements on port space. Fast switching between two antennas synchronously with the Magneto-Hydro Dynamic (MHD) modes frequency would increase the efficiency of mode stabilization. Both combination and switching as well as power sharing between different ports can be performed with high-power four-port diplexers using small frequency differences or small frequency-shift keying of the gyrotrons, respectively. Fast directional switches (FADIS) and beam combiners (BC) can be designed on the basis of different physical mechanisms: some selected design variants were investigated and the results are presented. Considerations on the integration of FADIS/BC's into large ECRH systems and their use in test arrangements are presented.
- Published
- 2010