Plasma Gas Temperature Control Performance of Metal 3D-Printed Multi-Gas Temperature-Controllable Plasma Jet

The aim of the study was to design and build a multi-gas temperature-controllable plasma jet that can control the gas temperature of plasmas with various gas species, and evaluated its temperature control performance. In this device, a fluid at an arbitrary controlled temperature is circulated throu...

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Bibliographic Details
Published in:Applied sciences 2021-12, Vol.11 (24), p.11686
Main Authors: Suenaga, Yuma, Takamatsu, Toshihiro, Aizawa, Toshiki, Moriya, Shohei, Matsumura, Yuriko, Iwasawa, Atsuo, Okino, Akitoshi
Format: Article
Language:English
Subjects:
3-D printers
Analytical chemistry
atmospheric plasma
Atmospheric pressure
Body temperature
Carbon dioxide
Computational fluid dynamics
Computer applications
Design
Fluid dynamics
Gas exchange
Gas temperature
Gases
Heat conductivity
Heat transfer
Hydrodynamics
Low temperature
metal 3D printing
Nitrogen
Plasma
Plasma jets
Plasma temperature
Plasmas (physics)
Temperature control
temperature-controllable plasma gas
Turbulence models
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Summary:The aim of the study was to design and build a multi-gas temperature-controllable plasma jet that can control the gas temperature of plasmas with various gas species, and evaluated its temperature control performance. In this device, a fluid at an arbitrary controlled temperature is circulated through the plasma jet body. The gas exchanges heat with the plasma jet body to control the plasma temperature. Based on this concept, a complex-shaped plasma jet with two channels in the plasma jet body, a temperature control fluid (TCF) channel, and a gas channel was designed. The temperature control performance of nitrogen gas was evaluated using computational fluid dynamics analysis, which found that the gas temperature changed proportionally to the TCF temperature. The designed plasma jet body was fabricated using metal 3D-printer technology. Using the fabricated plasma jet body, stable plasmas of argon, oxygen, carbon dioxide, and nitrogen were generated. By varying the plasma jet body temperature from −30 °C to 90 °C, the gas temperature was successfully controlled linearly in the range of 29–85 °C for all plasma gas species. This is expected to further expand the range of applications of atmospheric low temperature plasma and to improve the plasma treatment effect.
ISSN:2076-3417
2076-3417
DOI:10.3390/app112411686