RU2114520C1 - Pulse-operated plasma plant - Google Patents

Abstract

FIELD: plasma engineering. SUBSTANCE: plant has two high-voltage electrodes, auxiliary- arc power supply, pulse-current generator, dielectric reflecting wall, and blowout coil; negative electrode is movable structure rigidly coupled with electromagnet armature whose coil is inserted between mentioned electrode and negative pole of auxiliary-arc power supply; mentioned coil is connected to electrode by means of flexible conductor. Arc stretching takes place due to setting electrodes apart by means of electromagnet. In the process, arc reference points are securely arranged at ends of electrodes and vapor jet of cathode flows over auxiliary-arc column and additionally stabilizes its electrical and physical characteristics. As soon as auxiliary arc attains desired parameters, blowout coil power supply is started, and high-voltage discharge is initiated between electrodes. Blowout coil is placed directly behind reflecting wall with the result that plasmoid is attracted to cold reflecting wall and as if rolls out over its surface into thin film. In the process, screening action of plasma particles greatly reduces and radiating surface increases. EFFECT: improved radiation intensity. 1 dwg

Description

 The invention relates to plasma technology, and more specifically to devices with indirect heating by an arc discharge, and can be used as a source of intense light radiation.

 Known pulsed plasma accelerator of an erosion type (Grishin S.D., Leskov L.V., Kozlov N.P. Electric rocket engines. -M.: Mechanical Engineering, 1975, S. 198 - 208), adopted as a prototype. Which contains a plasmatron having two high-voltage electrodes, a pulse current generator, an auxiliary discharge initiation source, a control unit, a discharge chamber and a nozzle. The acceleration of the plasma flow is achieved by creating high pressure in the chamber of the device, as well as due to the interaction of the axial Hall currents with the azimuthal magnetic field formed by the current flowing through the central electrode. Plasma-forming gas is obtained directly in the accelerator chamber under the action of an electric discharge on the chamber wall made of gas-generating material (for example, fiber, copper, plexiglass). In this case, the gas-dynamic and magnetic forces do not balance each other, as a result of which a self-contracting region of elevated temperature and density, the so-called plasma focus, which is a source of intense light radiation, forms on the edge of the accelerator.

 The movement of a high-voltage high-current pulse discharge along the electrodes of the device during the entire period of operation causes their increased wear, and the destruction of the wall of the discharge chamber that occurs during the generation of a plasma-forming gas reduces the life of the device. In addition, the mutual shielding of plasma focus particles limits the radiation intensity. Although the voltage and power of the discharge moving along the electrodes of the device can be reduced, although it can reduce the thermal load on its elements, it is, in turn, fraught with a sharp drop in the radiation intensity; moreover, when the arc moves along the guide electrodes in a transverse magnetic field, it is almost impossible to ensure stability such characteristics as current, conductivity, displacement velocity, constancy of shape (section, length, radius of curvature), which leads to a spread in the parameters of the discharge and generation process radiation.

 Compared with the prototype device, the present invention allows for the stabilization of the characteristics and shape of the arc directly at the time of the high-voltage discharge, significantly increase the radiation intensity at comparable energy costs, and significantly reduce the thermal load on the elements of the device.

 This is achieved by the fact that the proposed device containing positive and negative electrodes, an auxiliary arc power source and a pulse current generator is equipped with an electromagnet, a reflective wall of dielectric material and a magnetic blast winding connected to the rectified voltage source, while the negative electrode is rigidly connected to the armature an electromagnet whose winding is connected between the specified electrode and the negative pole of the auxiliary arc power source, and with the electrode about and associated flexible conductor, and magnetic blast coil is placed directly behind the reflective wall and connected to a source of rectified voltage.

 Significant differences of the proposed device from the prototype are that the device of the present invention contains an electromagnet designed to dilute the electrodes, a reflecting wall of dielectric material, when a plasma bunch comes into contact with the generation of intense light radiation, and a magnetic blast winding that provides plasma and reflective contact walls, while the negative electrode is movable and is rigidly connected to the armature of the electromagnet, the winding of which is connected between the specified electrode and the negative pole of the auxiliary arc power source, moreover, it is connected to the electrode by a flexible wire. This is done due to the fact that in the device of the invention, the arc is stretched until it reaches the specified energy and geometric parameters, after which it is broken by a high-voltage discharge. The arc is stretched by expanding the electrodes by means of an electromagnet. In this case, the reference points of the arc are stationary at the ends of the electrodes, and the steam cathode stream flowing around the column of the arc further stabilizes its electrophysical characteristics. In addition, placing the magnetic blast winding directly behind the reflective wall improves the dynamic contact of the plasma with the wall surface.

 The drawing shows a General diagram of a pulsed plasma installation.

 The installation contains high voltage electrodes 1 and 2 (1 - cathode, 2 - anode), auxiliary arc power source 3, which is an adjustable rectified current source, inductor 4, pulse current generator, including high voltage capacitor 5, high rectified voltage source 6, resistor 7 , an oscillator 8 and a spark gap 9, as well as a reflecting wall 10 of dielectric material, a magnetic blast winding 11 and an electromagnet consisting of a winding 12, an armature 13, a spring 14 and an insulating sleeve 15.

 The negative electrode 2 is rigidly connected to the armature 13 of the electromagnet, the winding 12 of which is connected between the electrode 2 and the negative pole of the source 3, and it is connected to the electrode by a flexible wire, and the electrode 1 is connected to the positive pole of the source 3 through the inductor 4. The high-voltage capacitor 5 is connected to the source 6 through a resistor 7 and through an oscillator 8 and a spark gap 9 is connected in parallel with the electrodes 1 and 2. The reflecting wall 10 is located near the discharge gap 16, and the winding 11 of the magnetic blast is located directly behind the wall. The control and control circuits of the source 3 are connected to the start circuit of the oscillator 8. The winding 11 is powered by a rectified voltage source, which, if necessary, can be made adjustable (not shown).

 Installation works as follows.

 In the initial position, the electrodes 1 and 2 are brought together. Before turning on the source 3, the capacitor 5 must be fully charged. When starting source 3, the following current circuit is formed: the positive pole of source 3, inductor 4, electrode 1, electrode 2, electromagnet winding 12, negative pole of source 3. As a result of the current flowing through winding 12, the armature 13 is drawn into the winding while moving electrode 2. As a result of the dilution of the electrodes 1 and 2, an auxiliary arc is ignited between them, the stability of the parameters of which (current, conductivity) is ensured by the regulatory action of the source 3 and inductor 4. Upon reaching the auxiliary arc of a given length, provided that its electrical characteristics are stable from source 3 to the oscillator 8 and to the power supply of the magnetic blast coil, a trigger pulse is supplied, the oscillator trips and breaks the gap of the spark gap 9, closing the discharge circuit of the high voltage capacitor 5 and initiating a high voltage discharge between electrodes 1 and 2. Discharger 9 in this circuit is designed to prevent the possibility of turning on the pulse current generator when the capacitor is insufficiently charged. The charge time of the capacitor 5 is determined along with its capacity by the resistance value of the resistor 7. As a result of the interaction of the magnetic fields of the arc and the winding 11 of the magnetic blast, the plasma bunch is attracted to the cold reflecting wall and, as it were, rolls through it into a thin film, which reduces the screening effect of the particles plasma. Moreover, due to the small thickness of the plasma film and the large area of the emitting surface, the plasma radiation intensity is significantly enhanced.

 This design allows you to pre-form the parameters of the auxiliary arc, which uniquely determines the nature of the process of the high-voltage discharge, so that a high-voltage discharge with specified characteristics is formed only at the end of the period of operation, which reduces the thermal load on the elements of the device. In addition, the mechanism of radiation generation using a reflecting wall, implemented in this device, can significantly reduce the screening effect of plasma particles, which, at comparable energy costs, provides a higher radiation intensity. In turn, placing the magnetic blast coil directly behind the reflective wall further improves the dynamic contact of the plasma with the wall surface.

Claims (1)

 A pulsed plasma installation containing positive and negative electrodes, an auxiliary arc power source and a pulse current generator, characterized in that it is equipped with an electromagnet, a reflective wall of dielectric material and a magnetic blast winding connected to a rectified voltage source, while the negative electrode is rigidly connected to an electromagnet anchor, the winding of which is connected between the specified electrode and the negative pole of the auxiliary arc power source, and with Trodena it involves a flexible cable and a magnetic coil is placed directly behind the blast reflective wall.