RU2059436C1 - Apparatus for materials treatment and disintegration by electrical pulses - Google Patents

Abstract

FIELD: clearance of grain, powder and slake-shaped materials (oil slimes, crushed rock, polyethylene, etc) from surface pollution and DISINTEGRATION of ores and rock to produce super fine grinding. SUBSTANCE: main member of apparatus is pulsed voltage transformer made in accordance with symmetric scheme with two different poles high-voltage electrodes 1, that are secondary windings of puled voltage transformer. Each electrode 1 passes inside corresponding section of inductors, made of closed magnetic circuits 2 with primary one turn windings 3. Windings 3 of adjacent inductors in two sections from one side are communicate with each other through capacitor 4 and from other side are connected to two charge-discharge buses 5. Buses are connected to power leads of symmetric controlled discharger 6 and through current limiting coils 7 are connected to counterphase leads of high-voltage windings 8 of power transformer and through capacity accumulators 9 of power - with electrodes 1. Second counterphase leads of windings 8 of power transformer are connected with primary winding 10 of inductive former 11 of hysteresis type starting pulses, coil ed on toroidal magnetic circuit 12 wit meddle ground point 13. Secondary winding 14 of former 11 from one side is grounded and from other side is connected to control lead 15 of discharger 6. EFFECT: apparatus has increased reliability, durability and productivity. 5 cl, 2 dwg

Description

 The invention relates to electropulse technology and can be used to clean oil sludge and other granular, powdery, flocculent materials from surface contaminants, selective grinding of ores and rocks, emulsification, and also in other areas where the use of electropulse technology.

Known electrical pulse installation containing a pulse voltage generator (GIN), in parallel with which a high-voltage electrode is connected, immersed in a grounded container with technical fluid, and a managed switch and a pulse current generator (GIT) connected in series with the selection and output unit connected between the managed switch and the high-voltage pulse source control pulses [1]
The disadvantage of this installation is the presence of synchronization circuits of the two generators, which complicates the installation and reduces its reliability, large fronts and low pulse repetition rate due to the large time intervals required for recharging the storage capacitors, which limits the performance of the installation, the short life of the capacitors due to their heating, which is the main reason for the low reliability of the installation. Particularly low reliability of the operation of capacitors and synchronization circuits when generating powerful pulses with an amplitude of about 500 mV or more.

A number of these disadvantages are eliminated in the installation for electropulse destruction of materials, adopted as a prototype, and consisting of an induction transformer, the secondary winding of which is simultaneously a high-voltage electrode, the lower end of which is immersed in the working chamber for the disintegration of materials, and the upper one is grounded through a high-voltage high-current diode and induction current meter connected through a pulse amplifier to a pulse current generator, the output of which is connected through a high current thyristor p to the secondary winding (the high voltage electrode) induction transformer from its grounded end [2]
Such an installation has fundamentally new possibilities with respect to variations in the energy input mode due to the simple control of the voltage level at the induction transformer and pulse current generator. The pulse repetition rate is tens of Hz, and the pulse duration can be reduced to tens of nanoseconds. However, this installation also contains unreliable and expensive elements: high-voltage high-current diode and thyristor, which reduces the life of the installation as a whole, especially when generating pulses with an amplitude of 500 mV or more.

 The aim of the invention is to increase the reliability, service life and productivity of the device.

 This goal is achieved by the fact that in the device for electric pulse processing and disintegration of materials, consisting of a pulse voltage transformer, the secondary winding of which is a high voltage electrode immersed in a grounded working chamber having a loading and unloading hole, the pulse voltage transformer is made according to a symmetrical scheme with two different polar high-voltage electrodes, each of which is passed inside the section of inductors, consisting of the same number of closed magnets of conductors with primary single-turn windings, and the turns of adjacent inductors of each section on one side are interconnected via a pulse capacitor, and on the other hand are connected to two charge-discharge buses connected to the power terminals of a symmetrical controllable spark gap, in addition, charge-discharge buses through current-limiting chokes are connected to the antiphase terminals of the high-voltage windings of the power transformer, and through capacitive energy storage devices with bipolar high-voltage electrodes, orye antiphase high voltage terminals of the power transformer windings are connected to the primary winding of an induction generator firing pulses hysteresis type, torroidalny wound on the magnetic core and having an average grounded point, the secondary winding of the induction generator with one side grounded and the other connected to the control terminal of the symmetrical managed arrester. It is important that in this device the primary single-turn windings of the inductors can be connected in parallel through pulse inductors with charge-discharge buses.

 In addition, bipolar high voltage electrodes can be equipped with replaceable tips.

 A charging resistor can be connected in parallel to the circuit between the connection points of the bipolar high-voltage electrodes with capacitive energy storage devices.

 Replaceable tips of bipolar high-voltage electrodes can be made in the form of metal threads or plates mounted in parallel.

 The novelty and inventive step of the proposed device lies in the change in the design of well-known analogues and prototypes of unipolar electrodes and pulsed high voltage sources to bipolar. This is achieved by performing a pulse voltage transformer according to a symmetric scheme, supplying it with two capacitive energy storage devices, options for connecting primary single-turn windings with charge-discharge buses, using a symmetrical controllable spark gap, an hysteresis type inductor and a power transformer with antiphase leads in the electrical circuit. In addition, the high-voltage electrodes of the device are equipped with replaceable tips, which, depending on the material being processed and, as electroerosive wear and tear, can be replaced. The implementation of replaceable tips of high-voltage electrodes in the form of metal filaments or plates mounted in parallel will provide the possibility of electric pulse processing of various materials. For example, loose sand, diamond and glass dust, etc. in electric polarization mode. When using a gas or oil that is not conductive with a direct current, a charging resistor can be connected in parallel between the high-voltage electrodes of different polarity and capacitive energy storage devices.

 In FIG. 1 shows a General diagram of the proposed device.

 A device for electropulse processing and disintegration of materials consists of a pulse voltage transformer made in a symmetrical manner with two bipolar high-voltage electrodes 1, which are secondary windings, and two sections of inductors, consisting of the same number of closed magnetic circuits 2 with primary windings 3. Each of bipolar high-voltage electrodes 1 is omitted inside the corresponding section of the inductors. The primary single-turn windings 3 of adjacent inductors in two sections are connected to one another through a pulse capacitor 4 and, on the other hand, connected to charge-discharge buses 5. Charging-discharge buses 5 are connected to the power terminals of a symmetrical controllable spark gap 6 and through current-limiting inductors 7 are connected to the antiphase leads of the high voltage windings 8 of the power transformer, and through capacitive energy storage 9 to the electrodes 1. The second antiphase leads of the windings 8 of the power transformer are connected the primary winding 10 of the induction generator 11 trigger pulses hysteresis type, torroidalny wound on the magnetic core 12 and having a middle point 13 grounded.

 The secondary winding 14 of the induction driver 11 is grounded on one side and connected to the control terminal 15 of the symmetrical controllable spark gap 6 on the other hand.

 The working ends of the high-voltage electrodes are equipped with replaceable tips 16, between which there is a discharge gap 17, and placed in the chamber 18 for processing and disintegration of the material, which is fed through the loading hole 19 and removed through the discharge hole 20.

 Additionally, the proposed device provides for parallel connection between the connection points of the bipolar high-voltage electrodes 1 with capacitive energy storage devices 9 of the charging resistor 21. In addition, replaceable tips 16 of the electrodes 1 can be made filamentary or plate-like.

 In FIG. Figure 2 shows a parallel connection through a pulse capacitor of primary single-turn windings of inductors in a pulse voltage transformer with charge-discharge buses.

 A device for electric pulse processing and disintegration of materials works as follows.

 In the working chamber 18 through the feed hole 19 is fed the processed material. After connecting to the mains supply, the voltage of the out-of-phase terminals of the high-voltage windings 8 of the power transformer is supplied through current-limiting inductors 7 to charge-discharge buses 5. Depending on the voltage polarity, capacitive energy storage 9 is charged in the first cycle through bipolar high-voltage electrodes 1 and a discharge water gap 17. If a non-conductive direct current working medium is used in the processing chamber 18, the charge of the capacitive storage 6 occurs through a circuit specially connected in the circuit between high-voltage electrodes 1 and capacitive storage 6 charging resistor 21. Simultaneously with capacitive storage 6 are charged pulse capacitors 4 installed in the circuit of the primary turns 3 of the pulse voltage transformer.

 At the moment when the voltage on the pulse capacitors 3 and capacitive storage 6 reaches its maximum and the charge current changes its direction, a quick magnetization reversal occurs for the toroidal magnetic circuit 16 of the induction former 11 and a triggering pulse is formed on its secondary winding 14, which triggers the operation of the symmetrical spark gap 6. Discharge current pulsed capacitors 4, flowing through the primary turns 3 of the inductors, magnetizes the annular magnetic circuits 2 and introduces them into saturation. In this case, high-voltage voltage pulses of different polarity with steep fronts are formed on bipolar high-voltage electrodes 1. These pulse voltages, combined with the voltage on the capacitive energy storage 9, lead to the breakdown of the discharge gap 17 in the processing chamber 18. At the time of breakdown, all the energy of capacitive storage devices is rapidly released in the channel of the generated plasma. The duration of this process is determined by the forming long line with lumped parameters and is selected so that after the completion of the process of electro-hydraulic or electro-pulse processing, the energy release in the plasma channel is stopped. By such regulation of the energy input, a mode of minimal sludge is achieved, for example, during selective disintegration of ores.

 In the next cycle described processes are repeated with the only difference being that the polarity of the charging voltage changes. In this case, in each cycle there is a magnetization reversal of all closed magnetic circuits 2 with a maximum swing in the hysteresis loop. The frequency of operation of such a generator is determined only by the frequency of the supply network and, in the case of power supply from an industrial network of 50 Hz, is equal to 100 Hz, thereby increasing productivity.

 Filamentous or plate-like electrodes are used for ultrafine grinding of materials, for example, to produce diamond dust. When a strong pulsed electric field with a large potential gradient appears in the gap between the filaments, the particles of the substance become polarized, leading to their softening or grinding, after which they are removed through the discharge opening 20.

 Improving the reliability and service life of such a device is provided by a significant reduction in voltage across capacitive storage and pulse capacitors. For example, for the formation of pulses of a discharge voltage of 500 kV and the number of ring magnetic cores in each section of ten, the voltage on capacitive energy storage devices will be 25 kV. This will allow the use of capacitors at a lower voltage compared to the limit passport data.

 When connecting the primary single-turn windings 3 of the inductors 2 through pulse capacitors 4 in parallel with the charge-discharge buses 5, with the same number of inductors it is possible to obtain twice as much discharge voltage compared to the first connection options. This effect occurs due to the fact that twice the charging voltage between the charge-discharge buses in the discharge mode is fully applied to the single-turn winding of the inductor.

 In addition, the operation of pulse transformers in this device does not require special demagnetization circuits of magnetic cores, as in the prototype.

 The indicated advantages of this device will allow its widespread use in almost any field where the use of electric pulse technology is possible and advisable.

Claims (5)

 1. DEVICE FOR ELECTRIC PULSE PROCESSING AND DISINTEGRATION OF MATERIALS, consisting of a pulse voltage transformer, the secondary winding of which is a high-voltage electrode, immersed in a grounded working chamber, with loading and unloading openings, characterized in that, in order to increase reliability in operation and performance, the transformer the pulse voltage is made according to a symmetrical scheme with two bipolar high-voltage electrodes, each of which is passed inside the section of inductors, co consisting of the same number of closed magnetic circuits with primary single-turn windings, and the turns of adjacent inductors of each section on one side are interconnected via a pulse capacitor, and on the other hand are connected to two charge-discharge buses connected to the power terminals of a symmetrical controllable spark gap, in addition charge-discharge buses through current-limiting chokes are connected to the antiphase terminals of the high-voltage windings of the power transformer, and through capacitive energy storage from by volt electrodes, the second antiphase leads of the high-voltage windings of the power transformer are connected to the primary winding of the hysteresis-type trigger pulses, wound around the toroidal magnetic circuit and having a mid-ground point, the secondary winding of the induction shaper is grounded on one side and connected to the control terminal of the symmetrical control terminal .  2. The device according to claim 1, characterized in that the primary single-turn windings of the inductors through pulse capacitors are connected in parallel with charge-discharge buses.  3. The device according to paragraphs. 1 and 2, characterized in that the bipolar high voltage electrodes are equipped with replaceable tips.  4. The device according to paragraphs. 1 and 2, characterized in that a charging resistor is included in the circuit between the connection points of the bipolar high-voltage electrodes with capacitive energy storage devices.  5. The device according to paragraphs. 1 to 3, characterized in that the replaceable tips are made in the form of metal threads or plates installed in parallel.

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