具有低频和高频功率耦合配置的环形二氧化碳等离子源,可提高能量传输效率

Plasma Pub Date : 2024-07-24 DOI:10.3390/plasma7030030
E. J. Devid, W. Bongers, P. Groen, M. van Ginkel, S. Doyle, F. M. A. Smits, C. F. A. M. van Deursen, K. Serras, S. Labeur, M. A. Gleeson, M. C. M. van de Sanden
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引用次数: 0

摘要

无电极低频(LF)/射频(RF)等离子体源由于缺乏与动态等离子体负载的重叠场,通常功率耦合效率较低。然而,这些等离子体源的电源通常具有非常高的功率效率(大于 90%),与微波源相比更具成本效益。如果能提高与等离子体的耦合效率,这些等离子体源将为化工行业的可持续电气化提供具有竞争力的技术。这项工作通过实验研究了五种应用于石英容器中环形二氧化碳等离子体的功率耦合方法。研究以节能等离子灯中使用的类似铁氧体耦合为基础。二氧化碳等离子体的电阻较高,在 1 毫巴时,功率耦合从 90%(汞蒸汽等离子体)降至 66%。低频/射频供电放电中的高耦合效率可以通过两种方式实现:要么增加变压器磁芯的电感,要么提高电磁波频率。此外,还可以使用与初级线圈并联的附加铁氧体磁芯来增加阻抗变换。用六个铁氧体磁芯并联一个初级线圈,频率约为 10 兆赫,功率为 1 千瓦的实验表明,该频率对磁导率有不利影响,铁氧体中的损耗导致耦合降低到 1.5 毫巴时的 33%。在频率为 66 kHz、使用纳米晶软磁材料磁芯的情况下,在 1.5 毫巴等离子体中,功率为 3.1 kW 时的耦合度达到 89%。由于等离子体阻抗增加,这种配置的耦合效率在较高压力下会下降,这又会因缺乏电感而限制变压器的耦合。通过对其他无芯线圈等离子体配置的研究,在 102 毫巴压力下,由环形螺旋线圈包围的环形等离子体的耦合效率最高可达 89%,最低为 50%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Toroidal CO2 Plasma Sources with Low- and High-Frequency Power Coupling Configurations for Improved Energy Transfer Efficiencies
Electrodeless Low-Frequency (LF)/Radio-Frequency (RF) plasma sources often suffer from low power coupling efficiencies due to the lack of overlapping field with the dynamic plasma load. However, the power supplies for these plasma sources typically have very high power efficiencies (>90%) and are more cost-effective compared to microwave sources. If the coupling efficiency to the plasma can be increased, these plasma sources offer a competitive technology for the sustainable electrification of the chemical industry. This work experimentally investigates five power coupling methods, applied to toroidal CO2 plasmas in a quartz vessel. The research was based on similar ferrite coupling as used in energy-efficient plasma lamps. The higher resistance of the CO2 plasma decreased the power coupling from 90% (for mercury-vapor plasma) to 66% at 1 mbar. High coupling efficiencies in LF/RF powered discharges can be achieved in two manners: either the inductance of the transformer cores can be increased, or the electromagnetic wave frequency can be increased. Furthermore, additional ferrite cores in parallel with the primary coils can be used to increase the impedance transformation. An experiment with six ferrite cores with a single primary winding in parallel, at a frequency of about 10 MHz and a power of 1 kW, showed that this frequency has a detrimental effect on the magnetic permeability and the losses in the ferrite result in a decrease of coupling to 33% at 1.5 mbar. At a frequency of 66 kHz with a nanocrystalline soft magnetic material core, a coupling of 89% was achieved in 1.5 mbar plasma for a power of 3.1 kW. This configuration exhibits decreasing coupling efficiencies at higher pressures since the plasma impedance increases, which again limits the coupling of the transformer due to a lack of inductance. The investigation of alternative coreless coil plasma configurations resulted in coupling efficiencies up to 89% decreasing to 50% at 102 mbar for a toroidal plasma enclosed by toroidally spiraling coils.
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