SU1034157A1 - Helical generator - Google Patents

Abstract

SPIRAL GENERATOR, contain an even number of conductors and TiaKoe the same number of insulating tapes, alternately superimposed one on another and rolled into a spiral, spark discharge. The source of high voltage charging voltage and load, characterized in that, in order to increase the output voltage, it is equipped with droplets, which are two bifilary wound on a ferromagnetic core. windings, with 9TOM primary and secondary windings are connected separately in series and a chain of primary. The windings are connected to the beginning of the daseMnetr, and the chain of secondary windings is connected to the other side of the source of high voltage charging voltage, and the ends of these windings are connected respectively to the beginning of the like conductive tapes and parallel to the sources of high voltage charging voltage (L is included switching the spark spar dn. O s N sd

Description

The invention relates to high-voltage and impulse technology, in particular, to a pulse voltage generator, and can be used as a source of high-voltage pulses in installations for various purposes. A spiral generator is known, which is made up of two conductive ribbons that are coiled into a choir and are isolated from one another along the entire length by a film dielectric. At one of the ends of the spiral or in the middle of it, a spark gap is connected to the conducting tapes. Day 1. The disadvantage of this spiral generator is the impossibility of obtaining large output voltages (100 kV and above) due to the destruction of the insulation resulting from such voltages partial discharges between conductive tapes. The closest to the proposed is the spiral generator containing an even number of conducting conductors and the same number of insulating tapes, alternately superimposed one on another and coiled, a spark discharge, a source of high voltage charging voltage, and a load of C2. A disadvantage of the known generator is that an increase in the voltage of the charging device is required to obtain a large amplitude output voltage. To charge strip lines formed when coiled into a coil, having 2K conductive tapes, for example, up to the voltage Up, a charging voltage U is necessary. With a large number of conductive charge strips, the device becomes quite large, which leads to an increase in its weight and cost. The purpose of the invention is to increase the amplitude of the output voltage. The goal is achieved by the fact that the spiral generator, which contains an even number of conductive and the same number of insulating tapes, alternately superimposed one on another and coiled up in a spiral, spark, voltage source and charging voltage, is represented by two biphilar windings, which are wound around a ferromagnetic core, the primary and secondary windings are connected separately in series and the chain of primary windings is connected to the grounded one, and the secondary winding The windings are connected by the beginning to another - the source terminal is high. foot. of the charging voltage, and the ends of the electric windings are connected respectively with the beginnings of the same-name conductive linen, and parallel to the terminals of the high-voltage charging voltage source, the switching spark is turned on. The drawing shows the electrical circuit of the spiral generator. The generator contains six conductive tapes 1-6 (insulating tapes not shown) coiled into a coil having three turns, chokes 7-9, each consisting of two bifillary-wound windings 10-15, a spark 16, the source 17 high voltage charging voltage and load 18. The spiral generator operates as follows. The high-voltage charging voltage source 17 through the windings 15, 13 and 11 charges all the conductive tapes (strip lines) formed during the spiraling up to a voltage UQ equal to the voltage at the high-voltage clamp, the source 17, iT.e. to do and. At time tO, the spark gap 16 is triggered, the closure of the stripe lines formed by the conductive tapes 1 and 2, 3 and 4, 5 and 6. The possibility of switching all the strip lines by a single spark discharge in this circuit is due to the fact that the strip lines are connected to the spark gap in parallel through bifilar windings 14 and 15, 12 and 13, 10 and 11, which are low-inductive in discharge mode. Yes. In strip lines, a voltage wave begins to propagate (indicated by arrows.) By the time t 2 t the arrival of reflected from opposite ends of the strip lines of the waves to a spark discharge at a load 18, the voltage amplitude is equal to the sum of the pulse voltages. of all strip lines U (, (2knU3. 2knU0, where K is the number of strip lines, equal to half of the conductive tapes 2K); n is the number of turns of the spiral generator. The subsequent process (t 2t5; the spiral generator is determined by the movement and reflection of the voltage waves and represents damped oscillations. Due to the fact that inductance of bifillary windings of chokes is much less than the inductances of the strip lines themselves, the distortion of the shape of the output pulse introduced by the throttles is insignificant. Placement of bifilary windings on the core from a ferromagnetic The material allows to significantly reduce the length of the winding. The use of the proposed scheme increases the efficiency of the charge of the helium generator, since the use of the charge and reactive elements in the center of active resistance at 1034157 /; leads to savings in electrical energy heating last.

Claims (1)

SPIRAL GENERATOR containing an even number of conductive and the same number of Insulating tapes, alternately superimposed one on top of another and coiled into a spiral, spark. arrester, high voltage charging voltage source and load, different. the fact that, in order to increase the output voltage, it is equipped with chokes, which are two bifilar windings wound around a ferromagnetic core, while the primary and secondary windings are connected separately in series and a chain of primary ones. • the windings are connected at the beginning to the grounded one, and the secondary winding chain is connected at the beginning to another terminal of the high-voltage charging voltage source, and the ends of these windings are connected respectively to the beginnings of the conductive tapes of the same name, and a switching spark gap is connected in parallel with the terminals of the high-voltage charging voltage source. e s 3 *