RU2666225C1 - Pulsed current generator for high-voltage electrohydraulic technologies - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to impulse technology, in particular to electric discharge technologies, and can be used for electro-hydraulic fragmentation, crushing and disintegration of materials. Generator includes a discharge circuit, the equivalent circuit of which consists of a series connection of resistance (R) of the power generation unit, electrical capacitance (C) of high-voltage energy storage based on pulse capacitors, inductance (L) of connecting cables, a key on the basis of the high-voltage switch (S) and crowbar circuit based on high-voltage semiconductor diodes (VD), installed after the switch, which makes it possible to reduce the values of the inverse components of the discharge current and voltage, thereby transferring the discharge regime from oscillatory to aperiodic, which helps to increase the service life of a pulsed high-voltage capacitor and a high-voltage switch at a high efficiency of electromechanical energy transformation in the working spark channel.EFFECT: technical result consists in increasing the reliability of the pulse current generator by increasing the service life of its assemblies – energy storage device based on a pulsed high-voltage capacitor and high-voltage switch based on tyratron, ignitron or any other key, with high efficiency of electromechanical energy transformation in the working spark channel.1 cl, 4 dwg

Description

The invention relates to a pulse technique, in particular to electric-discharge technologies, and can be used for electro-hydraulic destruction, crushing and disintegration of materials.

Known "Pulse current generator", (patent of the Russian Federation for the invention No. 2014730. Publ. June 15, 1994), comprising: a capacitor bank, a load, a multi-channel spark gap, containing two main electrodes equipped with auxiliary electrodes forming parallel spark gaps. Auxiliary electrodes are connected to the main electrode using inductors with mutual inductive coupling. In parallel with the arrester, a circuit is connected consisting of a series-connected auxiliary controlled arrester connected to the anode of a multichannel arrester, a current-limiting element, for example, in the form of an additional inductor, the ignition device is made in the form of a pulse voltage generator according to the Arkadyev-Marx scheme.

The disadvantage of this device is the design complexity of the multichannel arrester, and the unstable operation of its airborne spark gaps due to the influence of the environment.

The well-known "Generator of pulsed currents", (patent of the Russian Federation for the invention No. 2282936. Published. 08/27/2006), containing a charger, a discharge circuit, consisting of a capacitor bank, a load, a two-electrode spark gap, a spiral generator of two plates connected between controlled switch, and one lining of the spiral generator is included in the discharge circuit, and the other is connected to the charger.

Despite the increased stability of operation of the pulse current generator achieved in the device, a two-electrode air gap having a low pulse repetition rate is still used as a switch.

The closest in technical essence to the claimed device is a discharge circuit of a pulse current generator that has become widespread in electro-hydraulic technologies (Yutkin L.A. Electro-hydraulic effect and its application in industry. L .: Engineering, 1986), consisting of a series connection of a capacitor, a switch ( forming gap) and the working spark channel - the gap in the liquid. This bit circuit is represented by an electrical equivalent circuit of a series connection of C, L, R elements and key S.

The disadvantages of this discharge circuit in the oscillatory mode of operation of the generator is a decrease in the efficiency of the electromechanical transformation of energy on the working spark channel; reduced service life and premature failure of pulsed capacitors and thyratron-based switches. So, for example, when the value of the relative reverse voltage during the discharge U _ar ̸ U ₀ = 0.2, the durability coefficient, and therefore the capacitor life is reduced by almost half - by 50%, and when the value of U _ar ̸ U ₀ = 0.6, the coefficient longevity is already reduced by 9 times - by 90%. These circumstances hinder the use of electro-hydraulic technology in many technological processes.

The objective of the proposed technical solution is to increase the life of the capacitor and switch in the discharge circuit of the pulse current generator in electro-hydraulic technologies while achieving maximum efficiency of the electromechanical energy transformation in the technological unit - the working spark channel.

To solve this problem, in the "Pulse current generator for high-voltage electro-hydraulic technologies", the discharge circuit of which on the equivalent circuit contains: an energy storage device based on pulsed high-voltage capacitors, a switching device (forming a gap) based on a thyratron, a working spark channel, and an additional crowbar circuit is installed.

A significant difference of this technical solution is that in the discharge circuit of the pulse current generator after the high-voltage switch, a crowbar diode circuit is introduced based on power semiconductor diodes. The implementation of the proposed technical solution became possible due to the current level of development of power electronics semiconductor devices, in which the parameters of some types of modern diodes allow the transmission of pulsed currents of several tens of kA and withstand reverse voltage of several kV.

The technical result is an increase in the service life of such nodes of the discharge circuit of a pulse current generator as a capacitive storage device and a switch, as well as an increase in the efficiency of electromechanical energy transformation on a working spark channel. This is achieved by reducing the inverse components of the discharge current and voltage, which affect the durability coefficient of the capacitor and commutator, due to the fact that the shape of the discharge changes from oscillatory to aperiodic.

In FIG. 1 is a structural diagram of the equivalent circuit of the discharge circuit of the pulse current generator, including the Crowbar diode circuit. In FIG. 1, the following notation is adopted: C is the capacitance of a high-voltage energy storage based on pulse capacitors; R is the resistance of the technological unit (working spark channel); L is the inductance of the connecting cables distributed over the length; S - key (high voltage switch); VD - Crowbar circuit made of series connection of power semiconductor diodes.

In FIG. Figure 2 shows the time dependences of the discharge current for the traditional discharge circuit of the pulse current generator 1 and for the generator circuit with a crowbar diode circuit 2 proposed in the technical solution. A comparative analysis of the time dependences showed that when the crowbar diode circuit 3 is turned on, the discharge current 2 has one polarity typical for aperiodic discharge mode, but at the same time retains the amplitude and steepness characteristic of the oscillatory process.

In FIG. Figure 3 shows the time dependences of the voltage on the capacitive storage for the traditional discharge circuit of the pulse current generator 1 and for the generator circuit proposed in the technical solution with the crowbar diode circuit 2. It follows from the graphs that turning on the crowbar diode circuit eliminates the reverse voltage during discharge, which eliminates the recharging of pulse capacitors , which means it increases their durability coefficient and service life by more than 9 times. The value of the reverse voltage on the capacitive storage is determined by the voltage drop on the straight segment of the current-voltage characteristic of the power diodes in the crowbar circuit and does not exceed 0.1% relative to the initial charge voltage of the capacitor banks.

In FIG. Figure 4 shows the time dependences of the specific energy in the technological unit or the rate of energy release in the discharge channel for a traditional discharge circuit of a pulsed current generator 1 and for a generator circuit with a crowbar diode circuit proposed in a technical solution 2. The time to reach power and, consequently, pressure in the channel When the Crowbar diode circuit is turned on, it does not change its maximum value and remains, as in the case of the oscillatory mode, minimal, but at the same time, the electromechanical energy conversion is carried out It occurs without oscillations, which increases its efficiency.

Let us explain the technical result of solving the stated problem - increasing the life of the capacitor and the switch of the discharge circuit of the pulse current generator in electro-hydraulic technologies while achieving the maximum efficiency of electromechanical energy transformation in the technological unit due to the crowbar diode circuit included after the switch. In the first stage - when the thyratron, ignitron, or any other high-voltage switching device installed in the generator is triggered, the discharge of accumulated electric energy by a high-voltage capacitive storage (pulse capacitors) in the working spark channel begins. In the second stage, when the maximum current value is reached by the law of self-induction, the polarity of the voltage across the inductance of the discharge circuit, due to the length of the cables connecting the pulse capacitors to the technological unit for energy release, is reversed. In this case, a crowbar diode circuit opens, shunting the capacitor and switch, and the magnetic energy accumulated in the distributed inductance of the discharge circuit of the magnetic circuit is discharged in a closed loop "crowbar diode circuit - cable inductance - working spark channel". Thanks to the shunting of the capacitor and the switch by the cube-diode circuit, the oscillations of voltage and current are eliminated, that is, the oscillatory mode of the discharge is converted into aperiodic in shape. The value of the reverse voltage at the capacitive storage is determined only by the voltage drop in the forward segment of the current-voltage characteristic of the semiconductor power diodes of the Crowbar circuit in the pulsed mode of operation and does not exceed 0.1% relative to the initial charge voltage of the capacitor banks, which allows us to neglect it. The absence of reverse voltage on the pulse capacitors during the discharge eliminates their recharging, which increases their durability coefficient and service life by more than 9 times compared to their use in the traditional generator circuit. The absence of current oscillations eliminates the mutual alternating two-way charge transfer between the switch electrodes, leading to their erosion, which contributes to an increase in the durability coefficient and service life of the switch compared to its use in the traditional generator circuit. The discharge current at the load (in the technological unit) has one polarity that is characteristic of the aperiodic discharge mode, but retains the maximum amplitude and slope, as in an oscillatory process. At the same time, the time when the power and pressure in the channel reach its maximum value remains minimal, and the electromechanical transformation of energy in the technological unit is carried out without hesitation, which improves the efficiency of the process.

This technical solution allows to increase the operating life of the most expensive components of the pulse current generator in electro-hydraulic technologies - energy storage based on pulsed high-voltage capacitors and a high-voltage switching device based on thyratron in a discharge circuit, while achieving high efficiency of electromechanical energy conversion in the technological unit.

A positive technical effect from the implementation of the technical solution is to reduce the cost of the technological process of electro-hydraulic destruction, crushing and disintegration of materials by increasing the life of the pulse current generator.

 The proposed technical solution can be implemented industrially.

Claims (1)

Pulse current generator for high-voltage electro-hydraulic technologies, including a discharge circuit, the equivalent circuit of which consists of a series connection of the resistance R of the technological unit for energy extraction, electric capacitance C of a high-voltage energy storage device based on pulse capacitors, inductance L of connecting cables and a key based on a high-voltage switch S, characterized by installing after the switch S a crowbar circuit based on power semiconductor diodes in this way ohm, that when the accumulated energy is discharged along the indicated series-connection circuit, when the maximum current is reached, when, according to the self-induction law, the polarity of the voltage across the inductance L of the discharge circuit is reversed, the capacitor and switch are bridged by a corona circuit of the power semiconductor diodes to transfer the discharge mode from oscillatory to aperiodic.

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