阴极线圈对用于 SST-1 和 Aditya-U ECRH 系统的 42-GHz 陀螺仪调试的影响

IF 1.3 4区物理与天体物理 Q3 PHYSICS, FLUIDS & PLASMAS

IEEE Transactions on Plasma Science Pub Date : 2024-09-10 DOI:10.1109/TPS.2024.3423345

Braj Kishore Shukla;Jatin Patel;Harshida Patel;K. G. Parmar;Hardik Mistry;Dharmesh Purohit;Paresh Patel;Artyom Kuzmin;Andrey Mazunin;Elena Soluyanova;Evgeny Tai

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引用次数: 0

摘要

一个新的42 GHz回旋加速器能够提供500千瓦的功率，持续500毫秒，已经成功地为SST-1和Aditya-U更新现有的ECRH系统。回旋管在~50千伏的光束电压下提供500千瓦的功率，并吸收20 A的光束电流。Gyrotron在工厂用不同的低温磁体进行了全参数（500 kW-500 ms）测试，并在IPR在SST-1和Aditya-U上现有的42 GHz ECRH系统的另一个低温磁体上进行了测试。新的回旋管成功地安装在现有的低温磁体上，并进行了脉冲操作测试。匹配光单元出口的燃烧模式保证了回旋管良好的高斯输出。Gyrotron开始在虚拟负载上进行高功率、长脉冲工作测试，当在42 kV下将功率增加到350 kW以上时，观察到束流随着束流电压的增加而增加，功率保持不变。这对回旋管来说是不安全的，因为它会增加收集器的热负荷。分析了不同磁组态下的磁场分布。因此，设计了一个合适的阴极线圈来控制回旋管的工作状态。阴极线圈安装在低温磁铁下方的回旋管上，在阴极和腔体之间。在0.5 ~ 2.0 A的电流范围内，逐渐观察到阴极线圈的作用。因此，没有观察到束流不受控制增长的影响，并且可以安全地将束流电压提高到50kv，这是全功率所需的值。最后，在50kv波束电压和18a波束电流下，对回旋加速器进行了500kw的全功率测试。阳极电压设为+22 kV，低温磁体电流为28.2 A，阴极线圈电流为1.0 A，满功率工作。当实际输入功率为~1 MW （50 kV-20 A）时，回旋管的效率在50%以上，如果考虑阳极电压和净加速电压~70 kV，回旋管的净电子效率约为37%。

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Effect of Cathode Coil on the Commissioning of 42-GHz Gyrotron for ECRH System in SST-1 and Aditya-U

A new 42 GHz Gyrotron capable to deliver 500 kW power for 500 ms duration has been commissioned successfully to renew the existing ECRH system for SST-1 and Aditya-U. The Gyrotron delivers 500 kW power at ~50 kV beam voltage and draws 20 A beam current. The Gyrotron was tested at factory for full parameters (500 kW–500 ms) with a different cryomagnet and commissioned at IPR on another cryomagnet magnet of existing 42 GHz ECRH system on SST-1 and Aditya-U. The new Gyrotron installed successfully on the existing cryomagnet and tested for the pulse operation. The burn pattern at the exit of matching optic unit ensures good gaussian output of Gyrotron. The Gyrotron started testing on dummy load for high power and long pulse operation, while increasing power beyond 350 kW at 42 kV, it was observed that the beam current increases with beam voltage and power remains constant. It was not safe condition for the Gyrotron as it would increase the thermal loading on the collector. An analysis is carried out to study the distributions of magnetic field with different magnetic configuration. Accordingly, a suitable cathode coil is designed to control the regime of Gyrotron operation. The cathode coil is installed on the Gyrotron below the cryomagnet in between cathode and cavity. The effect of cathode coil is observed gradually by varying the current from 0.5 to 2.0 A. As a results, the effect of uncontrolled growth of beam current was not observed and beam voltage can be increased safely up to 50 kV which is a required value for full power. Finally, the Gyrotron is tested successfully for full power 500 kW at 50 kV beam voltage and around 18 A beam current. The anode voltage was set to +22 kV, cryomagnet current was 28.2 A, and current in cathode coil was 1.0 A for full power operation. The efficiency of Gyrotron is more than 50% as actual input power is ~1 MW (50 kV-20 A), if we include anode voltage also with net accelerating voltage ~70 kV, the net electronic efficiency of Gyrotron is around 37%.

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来源期刊

IEEE Transactions on Plasma Science 物理-物理：流体与等离子体

CiteScore

3.00

自引率

20.00%

发文量

538

审稿时长

3.8 months

期刊介绍： The scope covers all aspects of the theory and application of plasma science. It includes the following areas: magnetohydrodynamics; thermionics and plasma diodes; basic plasma phenomena; gaseous electronics; microwave/plasma interaction; electron, ion, and plasma sources; space plasmas; intense electron and ion beams; laser-plasma interactions; plasma diagnostics; plasma chemistry and processing; solid-state plasmas; plasma heating; plasma for controlled fusion research; high energy density plasmas; industrial/commercial applications of plasma physics; plasma waves and instabilities; and high power microwave and submillimeter wave generation.