Abstract
A system for matching the output of a multimodular plasma opening switch (POS) to a “liner”-type load having a small initial impedance is described. The main element of this system is an isolating spark gap that allows synchronization of the POS modules and prevents a repeated POS closure cutting off the inductive storage from the load. A spark gap based on a multigap explosive-emission diode, which was proposed and tested earlier, is insufficiently strong electrically to be used in the Baikal project aimed at the development of a superpowerful pulsed generator. An urgent problem of increasing the electrical strength of a 1-mm-wide vacuum gap, which is a basic element of the aforementioned spark gap, is being solved. It is proposed to use electrodes of the point (anode)-plane (cathode) type that allow the electric field to be concentrated at the point-type anode, thereby increasing the gap’s electrical strength. The results of experiments aimed at the study of vacuum breakdown in this system of electrodes are presented. It is shown that this design allows the gap’s strength to be raised by several times, a long service life of electrodes to be ensured thanks to the low energy-deposition density, and a multichannel (i.e., low-inductance) breakdown to be stably attained. A diagram of the spark-gap prototype is presented, its breakdown characteristics are obtained, and a full-scale scheme of the spark gap is presented.
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Original Russian Text © G.I. Dolgachev, D.D. Maslennikov, A.G. Ushakov, A.S. Fedotkin, I.A. Khodeev, 2007, published in Pribory i Tekhnika Eksperimenta, 2007, No. 3, pp. 106–116.
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Dolgachev, G.I., Maslennikov, D.D., Ushakov, A.G. et al. Electric strength of a vacuum gap during breakdown in an inhomogeneous electric field for switching high-power pulses. Instrum Exp Tech 50, 383–392 (2007). https://doi.org/10.1134/S0020441207030153
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DOI: https://doi.org/10.1134/S0020441207030153