Field-Time Breakdown Characteristics of Air, N2, CO2, and SF6

Liu, Ting; Timoshkin, I. V.; MacGregor, S.J.; Wilson, M. P.; Given, M.J.; Bonifaci, Nelly; Hanna, Rachelle

doi:10.1109/tps.2020.2991860

Cited by 8 publications

(10 citation statements)

References 61 publications

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“…The numerical values of the fitting parameters, C and D, obtained in OriginPro graphing software for each gas are given in Table 2. 11 shows Nt as a function of E/N for air, N2 and CO2 and includes: the results obtained in the present work (Ntbr as a function of Etip/N), the kinetic model results (Ntf as a function of E/N), and the results previously published in the literature, [10,11,[22][23][24], and [34][35][36][37]. Each experimental point shown in Figure 11 represents the average value obtained using 20 individual data points, the error bars show the 95% confidence interval values, (some original experimental points do not appear to have error bars as a result of these bars being too small to display relative to the size of the point).…”

Section: Breakdown Voltage and Time To Breakdown In Investigated Gasesmentioning

confidence: 75%

“…To obtain the analytical "breakdown field-formative time to breakdown" characteristics, a kinetic model can be used. The kinetic model discussed in detail in [34] links the formative time and the normalised breakdown field, E/N:…”

Section: Breakdown Voltage and Time To Breakdown In Investigated Gasesmentioning

confidence: 99%

“…where, t f is the formative time, α eff is the effective ionization coefficient and µ e is the mobility of electrons; the numerical values of α eff and µ e used in the present analysis are listed in [34].…”

Section: Breakdown Voltage and Time To Breakdown In Investigated Gasesmentioning

confidence: 99%

“…The literature data are based on both formative and (in some cases) total time to breakdown and were obtained under various experimental conditions (type of electrodes, inter-electrode distances, gas pressures, high-voltage pulse characteristics). Details of each specific set of experimental conditions can be found in [10,11,[22][23][24][34][35][36][37]. -positive polarity (monocone) [24]; - [23]; solid line, fitting curve, Equation ( 6).…”

Section: Breakdown Voltage and Time To Breakdown In Investigated Gasesmentioning

confidence: 99%

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The Nanosecond Impulsive Breakdown Characteristics of Air, N2 and CO2 in a Sub-mm Gap

Liu

Timoshkin

Wilson

et al. 2021

Plasma

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The present paper investigates the breakdown characteristics—breakdown voltage, with breakdown occurring on the rising edge of the applied HV impulses, and time to breakdown—for gases of significance that are present in the atmosphere: air, N2 and CO2. These breakdown characteristics have been obtained in a 100 µm gap between an HV needle and plane ground electrode, when stressed with sub-µs impulses of both polarities, with a rise time up to ~50 ns. The scaling relationships between the reduced breakdown field Etip/N and the product of the gas number density and inter-electrode gap, Nd, were obtained for all tested gases over a wide range of Nd values, from ~1020 m−2 to ~1025 m−2. The breakdown field-time to breakdown characteristics obtained at different gas pressures are presented as scaling relationships of Etip/N, Nd, and Ntbr for each gas, and compared with data from the literature.

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Section: Breakdown Voltage and Time To Breakdown In Investigated Gasesmentioning

confidence: 75%

Section: Breakdown Voltage and Time To Breakdown In Investigated Gasesmentioning

confidence: 99%

Section: Breakdown Voltage and Time To Breakdown In Investigated Gasesmentioning

confidence: 99%

Section: Breakdown Voltage and Time To Breakdown In Investigated Gasesmentioning

confidence: 99%

See 2 more Smart Citations

The Nanosecond Impulsive Breakdown Characteristics of Air, N2 and CO2 in a Sub-mm Gap

Liu

Timoshkin

Wilson

et al. 2021

Plasma

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“…As a matter of fact, the computation of streamer integrals (15) requires knowledge ofᾱ for a large range of operational parameters. For common insulating gases empirical relations well-fitting experimental data over a wide range of E/P are listed in the literature [21,26]. Using the ideal gas law, relating gas pressure and density N [1/m 3 ], the reduced effective ionization coefficient of SF 6 , can be expressed as [26]:…”

Section: Effective Ionizationmentioning

confidence: 99%

Automatic Optimization of Gas Insulated Components Based on the Streamer Inception Criterion

2021

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Gas insulated transmission lines (GILs) are used in electrical systems mainly for power transmission and High Voltage substation interconnection. In this paper, we focus on the development of complex numerical tools for the optimization of gas insulated HVDC components by the estimation of realistic electric field distribution and the voltage holding of the designed geometry. In particular, the paper aims at describing the correct modelling approach suitable to study high voltage components in DC, considering the nonlinear behaviour characterizing the electrical conductivity of solid and gas insulators. The simulated field distribution is then adopted to estimate the voltage holding of the dielectric gas, with a convenient engineering technique, based on the streamer criterion. These two tools are integrated in an automatic optimization package developed in COMSOL® and MATLAB®, with the purpose of adjusting the critical geometry features, suffering from excessive electrical stress and possibly giving rise to electrical breakdown, in order to guide the designer towards a robust solution.

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Investigation of air breakdown and plasma evolution on microstrip antenna surface using the particle-in-cell method

Jiang

Xie

et al. 2023

Physics of Plasmas

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This paper investigates the breakdown of two microstrip antennas through experiments and particle-in-cell simulations. The breakdown thresholds of a microstrip dipole antenna and a double-layer patch microstrip antenna are investigated experimentally and found to be 15.6 and 30.8 kW, respectively. Ablation is observed on the surface of the antennas, indicating that the local electric field is particularly intense. To further understand the breakdown process, the particle-in-cell and Monte Carlo collision methods are combined to investigate the inception and development of partial discharge on the surface of the antennas. Under the criterion of continuous electron density growth, the breakdown thresholds of the dipole and double-layer patch antennas are estimated to be 19.4 and 52.9 kW in our simulations. The simulation results are in reasonable agreement with the experimental measurements. In the microstrip dipole antenna, the plasma evolution of the partial discharge is initiated near the tip, while the electric field close to the tip is distorted and a positive streamer directed toward the tip is observed. In the double-layer patch microstrip antenna, a more uniform discharge is observed at the edge of the circular patch in the simulations.

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Field-Time Breakdown Characteristics of Air, N₂, CO₂, and SF₆

Cited by 8 publications

References 61 publications

The Nanosecond Impulsive Breakdown Characteristics of Air, N2 and CO2 in a Sub-mm Gap

The Nanosecond Impulsive Breakdown Characteristics of Air, N2 and CO2 in a Sub-mm Gap

Automatic Optimization of Gas Insulated Components Based on the Streamer Inception Criterion

Investigation of air breakdown and plasma evolution on microstrip antenna surface using the particle-in-cell method

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