A high-voltage barrier discharge generator: Modeling and experimental verification

The paper describes a power unit model of a device generating a plasma barrier discharge at atmospheric pressure in a gas-discharge gap. This model includes a power unit, a high-voltage transformer, and a control system, which are all produced using physical simulation tools. The research presents both the modeling results and the experiment findings of obtaining dielectric barrier discharges.

1. Penetrante B. M., Schultheis S. E. Non-Thermal Plasma Techniques for Pollution Control. Parts A and B. Berlin, Heidelberg : Springer-Verlag, 1993.

2. Fridman A., Kennedy L. A. Plasma Physics and Engineering. Boca Raton : CRC Press, 2004. 853 p.

3. Plasma Technology for Hyperfunctional Surfaces: Food, Biomedical, and Textile Applications / Rauscher H., Perucca M., Buyle G., eds. Weinheim : Wiley-VCH Verlag GmbH & Co. KGaA, 2010. 428 p.

4. Weltmann K. D., Kindel E., Brandenburg R. et al. Atmospheric Pressure Plasma Jet for Medical Therapy: Plasma Parameters and Risk Estimation // Contribution to Plasma Physics, 2009. Vol. 49, no. 9. P. 631–640.

5. Рыбкин В. В., Титов В. А. Кинетика и механизма взаимодействия окислительной плазмы с полимерами // Энциклопедия низкотемпературной плазмы. М. : Янус-К, 2005. Т. 8. С. 130–170.

6. Wolf R., Sparavigna A. C. Role of plasma surface treatments on wetting and adhesion // Engineering. 2010. Vol. 2, no. 6. P. 397–402.

7. Masuhiro K., Okazaki S. Raising of ozone formation efficiency in a homogeneous glow discharge plasma at atmospheric pressure // Journal of Physics D. 1994. Vol. 27, no. 9, P. 1985–1987. https://doi.org/10.1088/0022-3727/27/9/026.

8. Kogelschatz U. Dielectric-barrier discharges: Their history, discharge physics, and industrial applications // Plasma Chemistry and Plasma Processing. 2003. Vol. 23, no. 1. P. 1–46.

9. Peeters F. J. J., The electrical dynamics of dielectric barrier discharges. Eindhoven : Technische Universiteit Eindhoven, 2015. 197 p.

10. Erickson R. W., Maksimovic D. Fundamentals of Power Electronics. 2nd ed. Springer, 2001. 883 p.

11. Yang B. Topology Investigation for Front End DC / DC Power Conversion for Distributed Power System. Doctoral Thesis. Virginia Tech, 2003. 317 p.

12. Liu C., Gu B., Lai J.-S. et al. High-efficiency hybrid Full-Bridge–Half-Bridge converter with shared ZVS lagging leg and dual outputs in series // IEEE Transactions on Power Electronics, 2013. Vol. 28, no. 2. P. 849–861. https://doi.org/10.1109/TPEL.2012.2205019.

13. Power electronics handbook / Rashid M. H., ed. Oxford : Butterworth-Heinemann, 2017. 1522 p.

14. Baliga B. J. Advanced Power MOSFET Concepts. New York : Springer, 2010. 570 p.

15. Green P. B., Zheng L. Gate drive for power MOSFETs in switching applications. A guide to device characteristics and gate drive techniques. URL: https://www.infineon.com/assets/row/public/documents/24/42/infineon-gate-drive-for-power-mosfets-in-switchtin-applications-applicationnotes-en.pdf (дата обращения: 28.09.2025).

16. Balogh L. Fundamentals of MOSFET and IGBT Gate Driver Circuits. URL: https://www.ti.com/lit/an/slua618a/slua618a.pdf (дата обращения: 28.09.2025).

17. Simscape. MATLAB Help Center. URL: https://www.mathworks.com/help/simscape/ (дата обращения: 26.09.2025).

18. FQPF20N60-VB Datasheet. VBsemi. URL: https://www.vbsemi.com/Package/TO220F/FQPF20N60CVB.pdf (дата обращения: 28.09.2025).

19. ЛЭПКОС. URL: https://ferrite.ru (дата обращения: 28.09.2025).