1.3 Đóng góp của đề tàiThe main con

1.3 Đóng góp của đề tài

The main contributions of this thesis are given as follows:
• Streamer characteristics of white oil (Exxsol-D140 and Marcol-52) in non-uniform field in a long gap are achieved. Streamers generally behave in similar way in these types of oilwith increasing applied voltage. When the applied voltage is raised, velocity of streamers increases in “step” and they become more branched at both the 2nd and 4th modes. Positive streamers are about ten times faster than negative streamers, and the breakdown and acceleration voltagesof positive streamers are about half of negative streamers.The process of shape shifting from multi-channels to few channels is associated with the transition from the 2nd to the 4thmodes of streamers. Finally, it is found that more branching results in lower speed and vice versa.

• This thesis presents the effect of various experiment conditions on streamers. Dissolved gases/air has no effect on streamer propagation while carbon particles significantly influence it especially for negative streamers.With the presence of a small amount of carbon particles, velocity of the 2nd mode negative streamers is increased by a factor of about ten. However, these particles do not seem to affect the 3rdor4thmode streamers. Carbon particles significantlyreduce both inception and breakdown voltages of both polarities. In addition, reduced pressure significantly facilitates streamer propagation of both polarities leading to a large reduction in breakdown voltage. Although reduced pressure markedly increases the number of streamer branches, the streamer velocity of positive polarity is still not reduced.However, reduced pressure decreases the velocity of non-breakdown negative streamers but raises that of breakdown streamers.

• The effect of additives on streamer propagation in a long gap is recorded. The propagation of streamers in white oil (Exxsol-D140 and Marcol-52) is significantly affected with the presence of a small amount of low ionization potential additive (DMA) or an electron scavenger (TCE).DMA can either increase or decrease the breakdown voltage of positive streamersdepending upon whether more filamentary channels or more branching is the dominating effect in the actual liquid. With more filamentary channels, DMA will speed up streamers whereas with higher number of branches, it will slow down streamers. However, DMA always makes breakdown streamers of positive polarity more branched with reduced speed and dramatically increased acceleration voltage. TCE accelerates streamers, especially negative polarity, and reduces both breakdown and acceleration voltages of both polarities. Positive streamers in white oil with DMA behave more like those of mineral oil while TCE has the same impact on negative streamers.

• The characteristicsof channels of the 2nd mode positive streamersareinvestigated and described. Streamer channels are dark channels with low conductivity during almost the entire propagation time. Some of channels show short illuminations severaltimes during propagation. During illuminations, the channels become highly conductive. Dark and illuminating channels (reilluminations) occur simultaneously and propagate equally fast. Reilluminations, possibly resulting from gas discharges,play a crucial role in breakdown, but have insignificant effects on propagation. Thus, it seems that processes occurring at the streamer tips are more important for the propagation than those inside streamer channels. The nature of the 2nd mode positive streamer channel is proposed: Gaseous plasma phase, i.e. “cold” plasma, exists inside channel, and high density of space charges accumulates at the streamer head.Anelectric field formed by the space charges may govern streamer propagation, i.e. streamers in liquidsbehave like those in gases.

• The mechanism behind the fast mode streamer is suggested. The propagation of streamer is possibly maintained with impact ionization occurring at streamer head. The fast mode streamer channel may contain “hot” plasma phase inside, i.e. high conductivity. Thus the streamer propagation acts as if it extends the point electrode. This results in a high electric field at the streamer tip as streamer approaches the plane electrode. This high tip field may cause photo-ionization in the volume around the streamer tip. Based upon the photo-ionization, the required seed electrons forimpact ionization are created in the stressed volume.