Compact atmospheric pressure plasma self-resonant drive circuits

• Published in: Journal of physics. D, Applied physics Vol. 45; no. 7; pp. 75202 - 1-14
• Main Authors: Law, V J, Anghel, S D
• Format: Journal Article
• Language: English
• Published: IOP Publishing 22.02.2012
• Subjects: Atmospheric pressure; Atmospheric pressure plasma; Barometric pressure; Circuits; Density; Devices; drive circuit; frequency pulling; Plasma (physics); self-resonance; Switching; Transformers
• ISSN: 0022-3727; 1361-6463
• DOI: 10.1088/0022-3727/45/7/075202

This paper reports on compact solid-state self-resonant drive circuits that are specifically designed to drive an atmospheric pressure plasma jet and a parallel-plate dielectric barrier discharge of small volume (0.5 cm3). The atmospheric pressure plasma (APP) device can be operated with helium, argon or a mixture of both. Equivalent electrical models of the self-resonant drive circuits and discharge are developed and used to estimate the plasma impedance, plasma power density, current density or electron number density of three APP devices. These parameters and the kinetic gas temperature are dependent on the self-resonant frequency of the APP device. For a fixed switching frequency and APP device geometry, the plasma parameters are controlled by adjusting the dc voltage at the primary coil and the gas flow rate. The resonant frequency is controlled by the selection of the switching power transistor and means of step-up voltage transformation (ferrite core, flyback transformer, or Tesla coil). The flyback transformer operates in the tens of kHz, the ferrite core in the hundreds of kHz and Tesla coil in the MHz range. Embedded within this work is the principle of frequency pulling which is exemplified in the flyback transformer circuit that utilizes a pickup coil for feedback control of the switching frequency.