RU1805302C - Spectrum excitation method - Google Patents

Abstract

Usage: the excitation of the spectra in the emission spectral analysis. SUMMARY OF THE INVENTION: a high voltage glow discharge is excited in a multi-electrode system in concentric circles in at least two parallel planes. The discharge is excited at the ends of the electrodes with an increase in the phase by π / 6 2n, where n is 0,1,2,3 .... The distance h between the circles and the diameters d of the circles are connected with the phase current of the phases by the ratio d h 2001phase. 1 ill.

Description

The invention relates to electrical discharges used to vaporize matter and to excite spectra in emission spectral analysis.

The purpose of the invention is to provide a closed plasma shell and increase discharge stability.

The drawing shows a diagram of the device by which the method was carried out.

The device is made in the form of a tube 1 made of a dielectric material, for example, quartz. Along the tube at a distance from each other equal to the diameter of the circle along which the inner ends of a separate group of electrodes are placed, holes 2 are made along the cross section, into which electrodes 3 are installed at an equal angular distance in the horizontal plane. Under specific conditions, quartz was used tube with a diameter of D 40 mm, length I 100 mm. Four rows of six holes in each row made along the tube section were made along the tube at a distance of h 20 mm from each other. In the holes x equal

At the angular distances x in each horizontal plane, six rod copper electrodes were fixed. The relative position of the electrodes relative to each other in parallel planes x is arbitrary. However, the best option offers angular displacement with respect to the parallel group with the establishment of equal angular distances. A high-voltage six-phase transformer C Upic 10 kV I (phases 0.4 A) was used as a power source. To the output busbars of the transformer (phases), electrodes placed in one horizontal plane were connected through ballasts, while electrodes placed in parallel planes connected in parallel.

The method is carried out as follows. At adjacent electrodes placed in the same plane, a high-voltage glow is generated with a sequential increase in phase on l I 6 2P, where n 0.1.2.3 ... Simultaneously smoldering electric times W

Yo

00

about

SP Sl)

about y

a series generates on electrodes located in other planes.

Thus, a stable torch is created at the ends of the electrodes placed in the same plane, propagating vertically to the region of the subsequent torch, merging uniformly with it. As a result, an extended continuous flare is formed with a stable boundary layer, which does not lose its continuity and stability during its arbitrary build-up. Inside the torch along the axis of the tube serves the test sample.

 The proposed method has significant advantages over the known one: it provides a high degree of accuracy of analysis, which is due to the burning mode of the electric discharge and the conditions under which the analysis is performed, namely: a realized glow discharge, in which there is practically no erosion of the electrodes, contributes to the stable flow of the discharge and the preservation of plasma purity. In addition, since the plasma torch is formed by currents, then not 0

5

0

the need for its forced formation, which ensures the natural convection of the sample and plasma, which also provides a high degree of plasma purity.

Claims (1)

SUMMARY OF THE INVENTION A method for exciting a spectrum, the method comprising exciting an electric discharge of a multi-electrode system with concentric circles in at least two parallel planes, characterized in that, in order to create a closed plasma shell and increase the stability of the discharge at the ends of the electrodes with a sequential increase in phase on l / 6-2n, where n 0,1,2,3 ... excite a high-voltage glow discharge along concentric circles whose diameters (d) and the distance (h) between them are connected with phase current numbing d h 200 1 phase, where phase is the phase current, A.