Nanosecond pulsed discharge type ozonizer with cooling structure

2017 IEEE 21st International Conference on Pulsed Power (PPC) Pub Date : 2017-06-01 DOI:10.1109/PPC.2017.8291300

D. Ikoma, D. Wang, T. Namihira

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Abstract

Dielectric Barrier Discharge type ozonizers has been used in water treatment, sterilization, and deodorization for many years. However, the yield in ozone generation leaves a room to expand its utilization. On the other hand, maximum ozone concentration remains lower value than that required for further industrial applications [1]. A main cause of ozone concentration saturation is assumed to be gas temperature rise near the H.V. central electrode of the coaxial cylindrical electrodes. This paper describes the effects of center electrode cooling on ozone concentration. In this study, a tube-cylinder reactor was used. The center electrode, with an inner diameter of 6 mm and outer diameter of 8 mm, allowed coolant to flow inside of it. Results show the possibility of high voltage application by increasing the diameter of the center electrode and suppressing gas temperature rise in the vicinity of the center electrode. Furthermore, higher ozone concentrations could be produced compared with conventional wire-cylinder reactors. These results suggest that suppression of gas temperature rise near the center electrode is efficient for suppressing ozone decomposition in ozone production using nanosecond pulsed discharge.

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带冷却结构的纳秒脉冲放电式臭氧发生器

介质阻挡放电型臭氧发生器已在水处理、杀菌和除臭中使用多年。然而，臭氧产生的产量留下了扩大利用的空间。另一方面，最大臭氧浓度仍然低于进一步工业应用所需的值[1]。认为臭氧浓度饱和的主要原因是同轴圆柱形电极高压中心电极附近的气体温度升高。本文介绍了中心电极冷却对臭氧浓度的影响。本研究采用管-筒反应器。中心电极的内径为6毫米，外径为8毫米，允许冷却剂在其内部流动。结果表明，通过增大中心电极的直径和抑制中心电极附近的气体温升，可以实现高电压的应用。此外，与传统的线筒反应器相比，可以产生更高的臭氧浓度。这些结果表明，抑制中心电极附近的气体温升对于抑制纳秒脉冲放电臭氧生产中的臭氧分解是有效的。

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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2017 IEEE 21st International Conference on Pulsed Power (PPC)

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