Field-Time Breakdown Characteristics of Air, N-2, CO2, and SF6

Field-Time Breakdown Characteristics of Air, N-2, CO2, and SF6

The dielectric performance of gases in insulation systems used in high voltage power and pulsed power applications is a subject of intensive theoretical and experimental investigations. Transient breakdown processes in gases stressed with short, high-field impulses, have been studied for many decade...

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Bibliographic Details
Published in:IEEE transactions on plasma science Vol. 48; no. 10; pp. 3321 - 3331
Main Authors: Liu, Ting, Timoshkin, Igor, Macgregor, Scott J., Wilson, Mark P., Given, Martin J., Bonifaci, Nelly, Hanna, Rachelle
Format: Journal Article
Language:English
Published: Institute of Electrical and Electronics Engineers 01-10-2020
Subjects:
Electric power
Engineering Sciences
Plasmas
Transient breakdown in gases
ionization front
time-field breakdown characteristics
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Summary:The dielectric performance of gases in insulation systems used in high voltage power and pulsed power applications is a subject of intensive theoretical and experimental investigations. Transient breakdown processes in gases stressed with short, high-field impulses, have been studied for many decades. However, there are still significant gaps in the understanding of the main breakdown processes and mechanisms associated with fast transient breakdown processes in gases. This knowledge is important for the optimization of gaseous insulating systems and for the coordination of gaseous insulation in power and pulsed power apparatuses. This information is also required for the development of gas-filled components such as circuit breakers and plasma closing switches. This article is aimed at the analysis of the field-time breakdown characteristics of air, N-2, CO2, and SF6, using kinetic and drift-diffusion approaches. The kinetic approach is based upon the avalanche-to-streamer transition criterion, while the fluid drift-diffusion model requires self-consistent numerical solution of the continuity equations for charged species, and the Poisson equation for the electric field. The time to breakdown as a function of the applied field was obtained for all investigated gases. The obtained analytical results agree well with the experimental data reported in the literature, which suggests that both approaches can be used for insulation coordination, and for the development of gas-insulated power and pulsed power systems and components.
ISSN:0093-3813
1939-9375
DOI:10.1109/TPS.2020.2991860