RU2282177C1 - Chemiluminescence detector of toxic materials in air - Google Patents

Abstract

FIELD: investigating or analyzing materials.

SUBSTANCE: detector comprises specimen to be analyzed, illumination unit, and recording unit. The detector is additionally provided with nontransparent chamber that is provided with the photocathode of photomultiplier made of potentiometer with digital liquid crystal indication powered from the power source. The chamber receives reactor made of quartz cell with transparent bottom and is filled with the indicative solution made of a mixture of sulfuric acid and ozone. The Peltier element used for condensing moisture from air is mounted above the reactor. The cell is connected with the gas-discharge ozonizer through a glass tube. The photomultiplier is connected with the recording unit.

EFFECT: enhanced sensitivity and precision.

1 dwg

Description

The invention relates to devices for the analysis of toxic sulfur-containing substances in the air of the working area and in the materials of personal protective equipment of production workers associated with the treatment of toxic substances.

The closest technical solution to the claimed object is a device for the analysis of harmful substances, containing the studied object and registration units, known from the book: Life safety under the general. ed. S.V. Belova, Moscow: Higher School, 1999, p. 213, fig. 4.14 (prototype).

A disadvantage of the known device is the relatively low accuracy of determination of toxic substances in the air of the working area, as well as the complexity of the design.

The technical result of the invention is to increase the sensitivity of the device and the accuracy of determination of toxic substances in the air of the working area.

This is achieved by the fact that the chemiluminescent detector of toxic sulfur-containing substances in the air of the working area, including the test sample, lighting and registration units, additionally contains a light-tight camera, in which the photocomputer photocathode is mounted in the form of a potentiometer with a digital liquid crystal display, operating from the power supply, and inside the camera a reactor is installed, which is a quartz cuvette with an optically transparent bottom, which is filled with an indicator solution, which is a mixture of sulfuric acid and ozone, with a Peltier element installed above the reactor to condense moisture from the air, and the cuvette is connected by a glass tube to a gas-discharge ozonizer, which sparges the air-ozone mixture into a solution of sulfuric acid, and the photomultiplier is connected to a recording unit designed to assess the intensity of the indicator light solution.

The drawing shows a block diagram of a chemiluminescent detector of toxic substances in the air of the working area.

In the lightproof chamber 1, the photocathode of the photomultiplier 2 is mounted, which is a potentiometer with digital liquid crystal display, operating from the power supply unit 8, over which a reactor 3 is installed, which is a quartz cell with an optically transparent bottom, which is filled with an indicator solution - a mixture of sulfuric acid and ozone (hydrogen peroxide). The Peltier element 4 is placed above the reactor 3, as a result of which condensed moisture from the air flows into the reactor and causes chemiluminescence, the luminosity of which, proportional to the magnitude of the photocurrent, is recorded as a signal of the photomultiplier. The gas-discharge ozonizer 5 using a compressor sparges the air-ozone mixture into a solution of sulfuric acid. The ovonator vinyl chloride hose is connected to a glass tube 6 lowered into a solution of sulfuric acid, as a result of which the mixture is bubbled. If the induction solution contains peroxide, only a compressor mixing the chemiluminescent solution is used. The registration unit 7 estimates the intensity of the glow of the solution.

A chemiluminescent detector of toxic substances in the air of the working area works as follows.

A chemiluminescent detector is designed to detect toxic sulfur-containing compounds in any form, chemiluminescent in concentrated sulfuric acid saturated with ozone acting as an oxidizing agent, or in sulfuric acid solutions containing hydrogen peroxide, in which sulfur-containing particles precipitate from sulfur-containing compounds in the form of finely dispersed forms. The intensity of the chemiluminescence of the solution in this case will be determined by the amount of sulfur, and consequently, sulfur-containing toxic substances. In order to increase the sensitivity of the analysis, cooling is used, which causes the condensation of air vapor and the concentration of toxic substances contained in it. If the amount of sulfur-containing substances in the air is too small, a significant increase in the sensitivity of the method is required, which is achieved through the use of bubbling the test air through an indicator solution without its preliminary condensation.

To increase the sensitivity of the measurement, uranyl ions are introduced into the reaction mixture, which increase by several orders of magnitude both the chemiluminescence intensity and the reaction sensitivity to sulfur-containing compounds (the mechanism of luminescence is caused by a bright chemiluminescent reaction in the solution, which was detected and recorded for sulfuric acid containing uranyl )

Claims (1)

A chemiluminescent detector of toxic sulfur-containing substances in the air of the working area, including the sample under study, lighting and registration units, characterized in that it additionally contains a light-tight camera, in which a photocathode photocathode is mounted in the form of a potentiometer with a digital liquid crystal display, operating from the power supply, and inside the camera a reactor is installed, which is a quartz cuvette with an optically transparent bottom, which is filled with an indicator solution, which is a mixture of sulfuric acid and ozone, with a Peltier element installed above the reactor to condense moisture from the air, and the cuvette is connected by a glass tube to a gas-discharge ozonizer, which sparges the air-ozone mixture into a solution of sulfuric acid, and the photomultiplier is connected to a recording unit designed to assess the intensity of the indicator light solution.