Microwave breakdown studies of He-N/sub 2/ mixtures in a pillbox cavity from 760 to 3040 torr

Conference Record of the Twenty-Fifth International Power Modulator Symposium, 2002 and 2002 High-Voltage Workshop. Pub Date : 2002-06-30 DOI:10.1109/MODSYM.2002.1189459

D. Hemmert, A. Neuber, J. Dickens

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Abstract

Microwave breakdown of various He-N/sub 2/ mixture combinations is investigated utilizing an S-band double window pillbox cavity. The objective is to determine the best combination of the two gases to maximize the mixture's ability to cool a dielectric surface while maintaining high breakdown thresholds. Helium is known to be an excellent source to dissipate heat from a dielectric, but it also has a low microwave breakdown threshold. Nitrogen does not transport heat as well, but has a much higher breakdown threshold. The studies focused on generating a series of E-field vs pressure curves for breakdown to help identify optimum He-N/sub 2/ mixture ratios. The S-band double window pillbox has a 333 cm/sup 3/ cavity with two ports to flow the gas mixture through. The pillbox is placed in a traveling wave resonant ring (TWRR) coupled to a 2.85 GHz, 4 MW, magnetron. This combination of double window pillbox and TWRR allows for testing power levels up to 40 MW. High speed diagnostics are used to measure the incident/reflected power and discharge luminosity. Coupled mass flow controllers maintain the gas mixture ratio and continuous gas flow through the cavity. Investigations can be conducted with single or multiple pulsed operations. Results ranged from a minimum of 5 MW for pure helium at 760 torr, to greater than 40 MW for pure nitrogen at 3040 torr.

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在760 ~ 3040托的药箱腔中He-N/sub - 2/混合物的微波击穿研究

利用s波段双窗口丸盒腔研究了不同He-N/sub - 2/混合物组合的微波击穿。目标是确定两种气体的最佳组合，以最大限度地提高混合物冷却介电表面的能力，同时保持高击穿阈值。众所周知，氦是一种极好的电介质散热源，但它的微波击穿阈值也很低。氮也不传递热量，但它的分解阈值要高得多。研究的重点是生成一系列用于击穿的e场与压力曲线，以帮助确定最佳的He-N/sub - 2/混合物比。s波段双窗药箱有一个333厘米/sup /腔，有两个端口使气体混合物流过。碉堡被放置在一个行波谐振环(TWRR)中，与一个2.85 GHz, 4 MW的磁控管耦合。这种双窗丸箱和TWRR的组合允许测试功率水平高达40兆瓦。高速诊断用于测量入射/反射功率和放电光度。耦合质量流量控制器保持气体混合比和连续的气体流过腔。可以用单脉冲或多脉冲操作进行检测。结果范围从760 torr的纯氦至少5 MW到3040 torr的纯氮大于40 MW。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Conference Record of the Twenty-Fifth International Power Modulator Symposium, 2002 and 2002 High-Voltage Workshop.

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