Surface charging of dielectric barriers under positive lightning impulse stress

Abstract: Abstract-The complex geometry of gas-insulated substations makes it difficult to predict withstand voltages. A key challenge is the characterization of the interaction between electrical discharges and dielectric surfaces. A 60 mm rod-plane air gap with a dielectric barrier is stressed with positive lightning impulse, initiating discharges that are characterized with a PMT, a current measurement system and a high-speed camera. The discharges do not lead to breakdown at the tested voltages. The residual potenti… Show more

“…This is mainly because of restrikes (also called back discharges), which create a "volcano" shape. The discharges have previously been observed by the authors as pulses with some 100 kHz at the tail of the lightning impulse [3]. Five other tested configurations, not included in table I, show similar agreement with the simulation model.…”

“…Leaders will charge the surface to a greater extent [6]. This was observed in experiments partly published in [3], see fig. 5.…”

“…The barrier was subsequently cleaned with isopropyl alcohol before the next experiment, resulting in a residual surface potential magnitude below 300 V. Local potential differences smaller than the surface area seen by the probe are not resolved [2]. This circular area can be assumed to be around 6-18 mm diameter [3]. Local charge peaks or sharp gradients are therefore smoothened.…”

“…Surface potential along the center line and saturation charge after a leader-less discharge. The measurements are taken from a previous publication where a high-speed camera was also used [3]. Image of the discharge with only streamers and image of the measured discharge with an arrested leader inset.…”

Surface charging of dielectric barriers in short rod-plane air gaps-experiments and simulations

“…This is mainly because of restrikes (also called back discharges), which create a "volcano" shape. The discharges have previously been observed by the authors as pulses with some 100 kHz at the tail of the lightning impulse [3]. Five other tested configurations, not included in table I, show similar agreement with the simulation model.…”

“…Leaders will charge the surface to a greater extent [6]. This was observed in experiments partly published in [3], see fig. 5.…”

“…The barrier was subsequently cleaned with isopropyl alcohol before the next experiment, resulting in a residual surface potential magnitude below 300 V. Local potential differences smaller than the surface area seen by the probe are not resolved [2]. This circular area can be assumed to be around 6-18 mm diameter [3]. Local charge peaks or sharp gradients are therefore smoothened.…”

“…Surface potential along the center line and saturation charge after a leader-less discharge. The measurements are taken from a previous publication where a high-speed camera was also used [3]. Image of the discharge with only streamers and image of the measured discharge with an arrested leader inset.…”

Surface charging of dielectric barriers in short rod-plane air gaps-experiments and simulations

“…With dielectric barriers in the discharge path, streamers typically propagate along and around the barrier to ground [11], [22]. Barriers can also inhibit secondary streamer development [23], cause leaders to propagate a longer path in the gas phase [24] or stop them [25].…”

Breakdown mechanisms of rod-plane air gaps with a dielectric barrier subject to lightning impulse stress

Breakdown Voltage Fluctuation and Breakdown Path Dispersion in a Hybrid Gas-Solid Insulation System Under Alternating Voltages