SU620160A1 - Plasma laser working chamber - Google Patents

Abstract

WORKING PLASMA LASER CAMERA, containing plasma accelerator, deceleration chamber and supersonic SOPLO, characterized in that, in order to increase the specific input energy, the working chamber is supplemented with at least two accelerators, all accelerators being identical and flat, and the total number of accelerators equals 2n + 1, where n "1; 2, 3, ..., accelerators are located in PLANES, passing at equal angles to each other through the axis of the braking chamber, equidistant from this axis and covered by solenoids, (with two adjacent solenoids, between which the nozzle is located, on, The prices are opposite, and the rest of the neighboring solenoids - by the FIELD (L "tei > &

Description

The invention relates to the field of quantum electronics and can be used to create plasma lasers. Working chambers of plasma lasers are known, in which the active plasma is created as a result of electric discharge between the electrodes tl. However, such chambers are distinguished by insufficient density and size of active plasma. This disadvantage is eliminated in the known working chamber of a plasma laser 2} containing a plasma accelerator, deceleration chamber and supersite nozzle. However, in such a chamber a considerable part of the energy that is consumed for plasma acceleration is not used to produce a laser generator. The aim of the invention is to increase the specific energy storage. The goal is achieved by the fact that the proposed working chamber is supplemented, at least by two accelerators, than all the accelerators are single and flat, and the total number of accelerators is 2n + 1, where the t 2, 3,. in planes passing under equal angles through the axis of the braking chamber, equidistant from this axis and covered by solenoids, two adjacent solenoids, between which the nozzle is located, are opposite, and the remaining neighboring solenoids. FIG. 1 and f g. 2 shows the working chamber of a plasma laser for case n 1, respectively, the plan and side view; in fig. 3 - cross sectional diagrams of the working chamber for cases n - 2. The plasma laser working chamber consists of flat plasma accelerators 1 with coaxial anodes 2 and cathodes 3, inputs of working gas 4 and solenoids 5. Accelerators 1 are symmetrically connected to the braking chamber 6 connected to a supersonic nozzle 7, which communicates with the cavity of the optical resonator 8 with mirrors 9. The resonator 8 communicates with the atmosphere through the exhaust diffuser 10. The anodes-2 and cathodes 3 are connected to the source 11. power supply. The dotted lines in the drawing show the magnetic field lines. The device works as follows. The internal cavities of the accelerators 1 and the braking chambers 6 are filled through the inlets 4 with a working gas, for example a mixture of COj + N2. After the inclusion of the splenoid 5, a discharge is made between the anodes 2 and the cathodes 3. As a result of this discharge, a plasma is formed. Variable fluxes that are accelerated in expanding magnetic fields collide in the braking chamber and then experience adiabatic expansion and additional acceleration in a supersonic nozzle 7, which generate laser radiation in the optical resonator 8. - The selected plasma is emitted into the atmosphere through diffuser 10. Due to the symmetric collision and contraction of plasma flows in a magnetic g / ole, the entire kinematic energy of plasma flows is transferred to the internal energy of the active plasma in the braking chamber audio, which allows to increase the specific energy of more than 20% compared with the prior art.

KN

Phage.Z

Claims (1)

A WORKING CAMERA OF A PLASMA LASER containing a plasma accelerator, a braking chamber and a supersonic nozzle, characterized in that, in order to increase the specific energy input, the working chamber is supplemented by at least two accelerators, all accelerators being identical and flat, and the total number of accelerators is equal to 2n + 1, where η «1; 2, 3, ..., accelerators are located in planes passing at equal angles through the axis of the braking chamber, are equidistant from this axis and covered by solenoids', ₍ in this case, two adjacent solenoids, between which the nozzle is located, are turned on in the opposite direction, and the rest neighboring solenoids - across the field. SU, 620160 f 620