SU1038816A1 - Pulse atomizer for nuclear absorption measurements - Google Patents

Abstract

PULSE ATOMIZER FOR NUCLEAR ABSORPTION MEASUREMENTS, comprising a housing with a chamber for feeding a combustible mixture, two hollow coaxially arranged cylinders connected to each other, forming a burner, characterized in that, in order to increase the sensitivity of the analysis and reduce the amount of consumed analyzed solution , an additional burner is installed on the casing, the flame axis of which is perpendicular to the flame axis of the main burner, and the holder with a refractory plate for the test sample, with This additional burner and plate are installed with the possibility of moving relative to each other. (L from 00 oo 05

Description

This invention relates to atomic sorption spectroscopy and microscopes to be used for elemental analysis of biological, agricultural, geochemical, metallurgical and other samples. In atomic absorption spectroscopy, slot burners are known, during operation of which a four-sided flame is formed, along the length of the directed beam of light, and the flame gases propagate across the beam of light 1. The disadvantages of the slit burners are relatively low sensitivity and the inability to increase the length of the absorber guide layer without increasing the flow of gases used and anal | 1ziruemoy sample. Atomizers are known that provide higher sensitivity without increasing the flow rate of gases and the sample to be analyzed, for example, an atomizer comprising a housing with a chamber for feeding a combustible mixture — two hollow cylinders coaxially arranged relative to each other of the cylinder, which form an annular gap for passing the combustible mixture and creating a cylindrical pls1meni 2. The use of the specified burner. requires the consumption of a large amount of the test solution) at the same time, the absolute and relative sensitivity, which is provided by the burner, is often not sufficient for many analytical tasks. It is known that if atomization of a portion of a sample is carried out pulsedly (within a short period of time), sensitivity increases with a relatively small consumption of the sample being analyzed. There are a number of tasks, for example, i-analysis of difficult-to-receive biological samples, such as DNA, proteins, various cell fractions, etc., which can be solved by pulsed atomization of the sample. The purpose of the invention is to increase the sensitivity and decrease the amount of the analyzed solution consumed. This goal is achieved by the fact that in a pulse atomizer for atomic absorption, containing a housing with a chamber for feeding a combustible mixture, two hollow cylinders coaxially arranged relative to each other, surrounding the burner, have an additional burner installed on the housing, the axis of the flame is perpendicular the core of the main burner, and the holder with a refractory plate for the test sample, with an additional burner. And the plate is mounted with the possibility of moving about a friend. The invention is illustrated in the drawing, where, in FIG. 1, a proposed atomizer is shown, frontal projection (FIG. 2), the same horizontal projection. The atomizer comprises a housing 1, which serves to supply a combustible mixture of gases and a slit 2, intended to create a cylindrical flame. The slit 2 is formed by two hollow cylinders 3 and 4 located coaxially relative to each other. In the cylinder 3 there is an opening 5 intended to pass the beam from the source 6 of the light through the flame. The tube7 is located perpendicular to the light beam (the movement of the flame gas) and is designed to direct a jet of air to the flame, limiting the flame along its length and preventing its hot gases from entering the monochromator. A low-power burner 8 is attached to the housing 1 to create a flame that is perpendicular to the main flame. The cross section of the flame from the additional burner is much smaller than the main flame section. The holder 9 with the refractory plate 10 intended for applying the sample is positioned in such a way that the plate is perpendicular and higher than the flame received from the additional burner 8. The guides 11 of the holder 9 g are designed for the forward translation of the plate 10 in the vertical direction. The spring 12 is intended to return and hold the plate 10 in its initial position (above the incremental flame). The end of the direction of the caddy 11 is fastened on the core | Pus 1 with a screw 13 for which a hole is made in the guide. The guide 11 is attached to the casing with a screw 14 and has a slot for it so that when loosening the screws 13 and 14 it would be possible to move the counter clockwise around the center of the screw 13. The arrows indicate the direction of movement of the flame gases. Atomizer works as follows. . The combustible gas mixture emerging from the slit 2 forms a cylindrical flame, which extends along the length to tube 7, from the flat butt of which a stream of air escapes, preventing the main flame from spreading to the monochromator. The burner 8 creates a flame that connects with the main flame near the slot 2. At the beginning of the main flame, the gases of the additional flame enter the center of the main section and then move in the direction of the main flame. The speed of the gas of the flame of the additional burner is chosen such that the flame, the income to the central part of the main part, further moves in the direction. main flame. A sample is applied to the plate 10, which is dried as it approaches the additional flame. Then, the plate 10 with the dried sample is introduced into the additional flame so that the flame r covers the entire portion of the plate with the sample. With an increase in the plate temperature, the sample evaporates in a short time and is added with an additional flame to the central part of the main flame. The atomized sample passes the entire length of the main flame and participates in the process of absorbing the light passing from the light source 6 to the monochromator through the hole 5 and through the entire length of the flame. In order to study a large amount of the analyzed solution, the part of the plant that is placed in the additional flame i can be bent. To replace the used new plate, loosen the screws 13-14, turn the guide 11 together with the holder 9 and the plate 10, replace the plate and fix the guide with screws 13 and 14 in the working position. Such an atomizer design allows pulsed atomization of the sample. The relative and absolute detection limit of the system is greatly improved. The amount of the solution being analyzed is reduced (by a factor of 10-50.). The baseline perturbation is reduced when the sample is introduced into the flame. Interference caused by the physical properties of the analyzed solution (viscosity, surface tension) is completely eliminated. It is possible to use inert gas jets with independent heating of the plate, for example, with electric current, instead of an additional flame. The proposed atomizer is improved. We determine the conditions for such elements, which are determined with sufficient sensitivity only in the center of the flame, without the additional expenditure of the combustible mixture for broadening the flame.

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Claims (1)

PULSED ATOMIZER FOR ATOMIC-ABSORPTION MEASUREMENTS, comprising a housing with a chamber for supplying a combustible mixture, two hollow cylinders coaxially arranged relative to each other and forming a burner, connected to the housing, characterized in that, in order to increase the sensitivity of the analysis and reduce the amount of the analyzed solution , an additional burner is installed on the body, the axis of the flame of which is perpendicular to the axis of the flame of the main burner, and a holder with a refractory plate for the test sample, while additional burner and plate are mounted with the possibility of movement relative to each other.