SU902708A1 - Device for measuring ozone concentration in gas mixture of antisepsis plants - Google Patents

Description

The invention relates to the food and medical industries and can be used to measure the concentration of ozone in a gas mixture while antiseptising food products and medical preparations.

A device is known for measuring the concentration of ozone in a gas mixture, which contains a measuring tank for a potassium iodide solution, a device for feeding an analyzer into it. gas mixture and the required concentration meter 11.

The disadvantages of this device are the laboriousness of the analysis, the time consuming and the low accuracy of the concentration measurement due to the leakage of ozone and the presence of an airbag over the solution in the tank with KJ solution.

The purpose of the invention is to reduce the labor intensity and increase the accuracy and speed of measurement.

The goal is achieved by the fact that the known device is equipped with a mixing device consisting of a float installed in the container

perforated discs interconnected by rods of ferromagnetic material and electromagnets attached to the vessel walls, and the meter includes a light source and a photocell disposed in the wall of the measuring container opposite one another, and last communicated with the vacuum system.

FIG. 1 shows a block diagram of the device; in fig. 2 - a general view of the measuring device; in fig. 3 is a section A-A in FIG. 2; in fig. 4 - the float.

Claims (2)

The device comprises an opon 1 generator connected to a gas main 2 connected to a measuring device 3 and a capacity 4 with stored products. The meter of the desired concentration consists of a measuring transparent container 5, mounted in 1 orbit 6 and closing at the top and bottom with covers 7 and 8. The top cover is equipped with five nozzles 9 and five sealing valves 10-14, consisting of electromagnetic clamps and soft valves and the bottom one is equipped with about; and {it has a sleeve 15 and one sealing valve 16 and inside the case there are ring electromagnets 17 and 18, a light source 19 and a photocell 20, and inside the vessel there is a float 21 consisting of two perforated disks 22 and 23 with answer TIFA E 24 interconnected by rods 25 of a ferromagnetic material. The diameter of the upper disk 22 is larger than the diameter of the lower disk 23. The device operates as follows. With the taps 11, 12, 13, 14, 16 closed and the valve 10 open, air is pumped out of the tank with a discharge of up to 10 agms. Air pumping allows precise dosing of volumes of short-circuit solution and gas mixture saturated with ozone entering the tank, and, in addition, increases the purity and reliability of the experiment. After the air has been pumped out, the valve 10 is shut off, and through the valve 11 a certain amount of clear solution KJ is supplied to the tank. Then, when the valve 11 is turned off, the gas mixture under study is fed through the open valve 12, filling the entire volume free of the mortar solution, after which the valve 12 is turned off and the ring electromagnet 17 is turned on, while the float 21 is sharply retracted and sprays KtJ solution through the holes 24 over the volume of the capsule that provides a quick uniform absorbed. An ozone solution with a short-circuit solution and accelerates the reaction. After this reaction, the electromagnet 18 is turned off, returning the float to its original position, uniformly. Mix the KU solution with the precipitate as a result of a chemical reaction. Repeated repetition of manipulations with the float allows the reaction to accelerate the release of pure iodine from the KtJ solution by ozone and distribute it evenly throughout the entire volume of the liquid. The solution prepared for the analysis is subjected to translucency from the light source 19, whose light intensity when passing through the analyzed solution varies depending on the color intensity and optical density of the solution, and, accordingly, on the ozone concentration. The light passing through the solution from the light source 19 enters the photocell 2 and then through the simplest amplifying circuit of the photocell signal enters the recording device graduated to ozone concentration values. After registration of the ozone concentration in this analyzed gas mixture, the valve 16 opens and the used solution is discharged, at the same time when the valve 13 is open, the capsule is washed with a distillate, with the valve 14 open after the valve 13 is turned off, it is air dried and returned to its initial working position for the next analysis. Measuring the ozone concentration in the gas mixture using the proposed device reduces the measurement time by 5 times, eliminates the titration stage of the resulting solution with iodine, sodium thiosulfate. The use of the device eliminates the need to use additional chemical reagents (thiosulfate), chemical equipment for titration, provides high purity and reliability of the experiment. Claim 1. A device for measuring the concentration of ozone in a gas mixture in antiseptic plants, containing a measuring tank for a solution of potassium iodide, a device for supplying the analyte, a gas mixture and the required concentration meter to it, in order to reduce the labor intensity, increase accuracy and speed of measurement, the device is equipped with a device for mixing, consisting of a float mounted in the tank, made in the form of two perforated discs interconnected It is made of ferromagnetic material, and electromagnets attached to the vessel walls, and the meter includes a light source and a photocell located opposite one another in the wall of the measuring vessel. 2. The device according to claim 1, that is, with the fact that the measuring tank communicates with the vacuum system. Sources of information taken into account in the examination 1. Technical instructions on the use of ozone for the treatment of natural waters. Kiev, J976, p. sixteen. 1 7 one 20X / W aik) L / 7 ;. Fy