论文信息 - Development of subsonic electrical discharges in water and measurements of the associated pressure waves

Development of subsonic electrical discharges in water and measurements of the associated pressure waves

This paper first presents an experimental electrical and optical study of the development of an electrical discharge in water. The point–plane water gap is subjected to a 0.02 µs/350 µs impulse voltage. A Schlieren device associated with an image converter or a photomultiplier demonstrates that the discharge phenomenon requires heating of the water located around the extremity of the point. This thermal process leads to the formation of gas bubbles in which an electrical discharge propagates. In the experimental conditions a threshold value of 80 J is necessary to create bubbles. No UV or IR light emission is recorded before the presence of bubbles is detected. When the energy conditions are sufficient (≥200 J), the volume of bubbles grows until the whole inter-electrode space is filled; then a breakdown of the gap occurs. When this happens, a high amplitude pressure shock wave is generated. In the second phase of this work the shock wave created by the gap breakdown was studied for energy levels up to 100 kJ. It is clearly pointed out that the pressure shock wave peak value depends on the energy remaining at breakdown time. For a constant remaining energy, the peak pressure value increases with increasing gap length.

[1] Milan Simek,et al. Generation of chemically active species by electrical discharges in water , 1999 .

[2] K. Kist,et al. Propagation and structure of streamers in liquid dielectrics , 1998 .

[3] A. Beroual,et al. Bubble dynamics and transition into streamers in liquid dielectrics under a high divergent electric field , 2001 .

[4] J Dupuy,et al. Large air-gap discharge and Schlieren techniques , 1988 .

[5] W. C. Finney,et al. A Preliminary Study of Pulsed Streamer Corona Discharge for the Degradation of Phenol in Aqueous Solutions , 1993 .

[6] Shashank Chaturvedi,et al. Modeling of shock-wave generation in water by electrical discharges , 2000 .

[7] Karl H. Schoenbach,et al. Parallel streamer discharges between wire and plane electrodes in water , 2002 .

[8] Bing Sun,et al. Use of a pulsed high-voltage discharge for removal of organic compounds in aqueous solution , 1999 .

[9] I. M. Gavrilov,et al. Dynamics of prebreakdown phenomena in a uniform field in water , 1994 .

[10] Properties of ferroelectric polymers under high pressure and shock loading , 1995 .

[11] Time lag and recovery time of neutral depopulation in compressed gases in a point-plane discharge , 1990 .

[12] N. Ross Chapman,et al. Measurement of the waveform parameters of shallow explosive charges , 1985 .

[13] I. V. Lisitsyn,et al. Thermal processes in a streamer discharge in water , 1999 .