一种X波段过模高效率相对论返波管

史彦超; 滕雁; 陈昌华; 肖仁珍; 邓昱群; 杨德文; 王东阳; 孙钧

doi:10.11884/HPLPB201830.170491

一种X波段过模高效率相对论返波管

doi: 10.11884/HPLPB201830.170491

西北核技术研究所高功率微波技术重点实验室，西安 710024

详细信息

作者简介:
史彦超(1986—), 男，助理研究员，主要从事高功率微波技术研究; shiyanchao@nint.ac.cn

中图分类号: TN125;TN122
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出版历程
- 收稿日期: 2017-12-01
- 修回日期: 2018-01-29
- 刊出日期: 2018-07-15

A high efficiency X-band over-mode relativistic backward wave oscillator

Science and Technology on High Power Microwave Laboratory, Northwest Institute of Nuclear Technology, Xi'an 710024, China

摘要

摘要: 设计了一种X波段过模高效率相对论返波管(RBWO)，主要结构包括双谐振腔反射器、7周期梯形慢波结构与提取腔。该器件慢波结构的过模比为2.6，电子束与结构波TM₀₁模的近π模相互作用，在慢波结构区域束波作用产生的TM₀₁模表面波主要转化为TM₀₂模的体波，其输出微波的模式主要为TM₀₂模，占比为81%，其余为TM₀₁模。提出一种过模条件下谐振腔反射器的设计思路，结合模式匹配法，优化得到了一种双谐振腔反射器结构，其对TM₀₁模与TM₀₂模的反射系数均大于0.99，可实现过模条件下RBWO慢波结构与二极管区的良好隔离; 同时双谐振腔反射器两个谐振腔中的纵向电场可以对电子束进行充分的预调制，将促进慢波结构区域的束波作用，有利于提升效率。通过在慢波结构后端加入提取腔，进一步提升了转换效率。PIC仿真中, 在二极管电压900 kV，电流14.3 kA，得到了6.6 GW的输出功率，转换效率约51%。
- 高功率微波 /
- 相对论返波管 /
- 过模 /
- 谐振反射器
Abstract: This paper studies a high efficiency X-band over-mode relativistic backward wave oscillator (RBWO), which is composed of a dual-cavity reflector, a 7-periods trapezoid SWS and extraction cavity. The ratio of D to λ of the generator is 2.6, and the electron beam interacts with the TM₀₁ near π mode of the structure wave. In the SWS region the TM₀₁ mode surface wave mainly transfers to the TM₀₂ mode body wave, the primary mode of the output microwave is TM₀₂ mode with the proportion 81%, and the remainder is TM₀₁ mode. A method to design the resonant reflector under over-mode condition is proposed, a dual-cylindrical cavity reflector is optimized by using the mode-matching method, and the reflection coefficients for the TM₀₁ and TM₀₂ modes are larger than 0.99, hence good insulation between the SWS and the diode is achieved. Simultaneously, the longitudinal electric field of the resonant reflector could pre-modulate the electron beam sufficiently, which would promote the beam-wave interaction in the SWS. Furthermore, the transfer coefficient is increased by loading the extraction cavity after the SWS. Simulation results indicate that microwave output power of 6.6 GW is achieved, the diode voltage is 900 kV and beam current is 14.3 kA, and the transfer efficiency is 51%.
- high power microwave /
- relativistic backward wave oscillator /
- over-mode /
- resonant reflector

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图 1 RBWO结构示意图

Figure 1. Schematic of the RBWO

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图 2 色散曲线与电子束Doppler线

Figure 2. Dispersion line and electron Doppler line

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图 3 圆柱形谐振腔TM₀₁模S₁₁参数随谐振腔半径R与谐振腔宽度L的二维图

Figure 3. 2D figure of S₁₁ parameter with R and L in cylindrical cavity

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图 4 双谐振腔反射器S₁₁参数随两腔间距d变化曲线

Figure 4. S₁₁ parameter vs distance between two cavities in the reflector

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图 5 双谐振腔反射器S₁₁参数随频率变化曲线

Figure 5. S₁₁ parameters vs frequency of dual-rectangular cavity reflector

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图 6 双谐振腔反射器内E_z场分布

Figure 6. E_z field distribution of dual-rectangular cavity reflector

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图 7 RBWO电子束相空间图-无提取腔

Figure 7. Phase space plots of electrons in RBWO without extraction-cavity

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图 8 RBWO电子束相空间图-带提取腔

Figure 8. Phase space plots of electrons in RBWO with extraction cavity

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图 9 RBWO输出功率曲线

Figure 9. Plot of output power vs time for the RBWO

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图 10 RBWO输出微波频谱图

Figure 10. Frequency spectrum of microwave for the RBWO

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图 11 RBWO内部E_z场分布

Figure 11. E_z field distributions in the RBWO

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图 12 RBWO输出波导E_z场模式分析

Figure 12. Mode analysis of E_z in the output waveguide of RBWO

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参考文献(10)

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