The Development of 170 GHz, 1 MW Gyrotron for Fusion Application.

Zhang, Yichi; Zeng, Xu; Bai, Ming; Jin, Ming; Hao, Wenteng; Gao, Dongshuo; Liu, Qiao; Feng, Jinjun

This paper presents the overall conceptual design of a 170 GHz, 1 MW gyrotron for plasma heating applications in thermonuclear fusion reactors. The operating mode is carefully selected with consideration of mode competition. The TE25,10 mode is determined as the operating mode in the present study. A weakly tapered conventional resonator is used for the study of the RF behavior, and multimode calculations are carried out for power and efficiencies. The optimized structure of the beam tunnel can further attenuate low-frequency oscillation. The design studies of a triode-type magnetic injection gun, quasi-optical mode converter, and single-disc sapphire window are also described. In addition, novel cold test methods which can effectively validate assembles are designed. In 2021, a prototype gyrotron was fabricated to validate the electronic–optic system and RF system. The current results obtained support an output power of 210 kW and efficiency of 15.9% through an initial low-power experiment. On the basis of the optimized design, an industrial prototype gyrotron is under fabrication as the heating source for the thermonuclear experimental reactor.

GYROTRONS; THERMONUCLEAR fusion; FUSION reactors; CONCEPTUAL design; SAPPHIRES

Electronics (2079-9292), 2022, Vol 11, Issue 8, p1279

2079-9292

Academic Journal

10.3390/electronics11081279