RU223792U1 - Device for bacteriological analysis of air - Google Patents

Abstract

The utility model relates to microbiology, including veterinary, namely to laboratory equipment for bacteriological analysis of air. The device for bacteriological analysis of air includes a cylindrical housing mounted on a base, which houses an electric motor connected to an impeller, above which a support disk with a Petri dish is placed. On the top cover of the cylindrical body there is a ring resting on a flat plexiglass disk equipped with a slot for air intake. The cross-sectional area of the upper end of the slot is twice as large as the cross-sectional area of the lower end of the latter. Moreover, the slot is located in the diametrical plane of the disk. The use of a utility model makes it possible to improve the quality of bacteriological analysis of air. 2 ill.

Description

The utility model relates to microbiology, including veterinary, namely to laboratory equipment for bacteriological analysis of air.

The principle of the aspiration method is known - aspiration of a certain volume of air with sowing of the bacteria contained in it onto the surface of the nutrient medium using a slotted Krotov device (see Google or Yandex, Study of air microflora - Microbiology with microbiological research techniques, Fig. 125, Krotov device). The latter is a cylinder with a removable top cover, in which there is an electric motor with a centrifugal fan (impeller), above which there is a support disk with a Petri dish, and on the top cover of the cylindrical body there is a ring resting on a flat plexiglass disk equipped with a suction slot air. Krotov's device was chosen as a prototype.

The principle of operation of the Krotov apparatus (Fig. 1) is based on the fact that air, sucked through a wedge-shaped slot in the lid of the apparatus, hits the surface of the nutrient medium, while particles of dust and aerosol stick to the medium, and with them microorganisms in the air . A Petri dish with a thin layer of medium is mounted on a rotating table of the apparatus, which ensures uniform distribution of bacteria on its surface. The device operates from the mains. After taking a sample with a certain exposure, the cup is removed, closed with a lid and placed in a thermostat for 48 hours. Typically, sampling is carried out at a speed of 20-25 l/min for 5 minutes.

Thus, the flora in 100-125 liters of air is determined. If sanitary-indicative microorganisms are detected, the volume of air being tested is increased to 250 liters.

The operating principle of Krotov’s device is based on the inertial deposition of aerosol particles onto the surface of the nutrient medium. The air being tested is sucked in through a gap in the lid of the device, hits the surface of a dense nutrient medium, and microbes are retained on its wet surface from the released microorganisms, then the grown colonies are counted.

The main disadvantage of Krotov's device is that a stream of air from the environment enters the nutrient medium under the lid of the device unevenly, through a single slot in the lid of a size equal to the radius of the lid. Consequently, the main part of the microorganisms settles in the area of the nutrient medium located directly under the gap in the lid of the Krotov device. This gives a less reliable picture of the true content of microorganisms in the air in other areas of the nutrient medium.

The technical result of the utility model is to improve the quality of bacteriological analysis of air.

The technical result is achieved by the fact that the device for bacteriological analysis of air includes a cylindrical body installed on the base, in which an electric motor is located, connected to an impeller, above which there is a support disk with a Petri dish, and on the top cover of the cylindrical body there is a ring resting on a flat disk made of plexiglass, equipped with a slot for air intake, and the cross-sectional area of the upper end of the slot is twice as large as the cross-sectional area of the lower end of the latter, and the slot is located in the diametrical plane of the flat disk.

The essence of the utility model is illustrated by drawings, where

Fig. 1 shows a diagram of the device;

figure 2 - cross section A-A, flat disk

The device for bacteriological analysis of air includes a cylindrical body 1 installed on the base 2, in which an electric motor 3 is located, connected to the outer 4 and inner 5 impeller, above which there is a support disk 6 with a Petri dish 8, and on the top cover 9 of the cylindrical body 1 there is a ring 13 resting on a flat disk 11 made of plexiglass, equipped with a diametrical slot 12 for air suction, in which the cross-sectional area of the upper end of the slot is twice as large as the cross-sectional area of the lower end of the latter. The width of the upper end of the slot (Fig. 2) is twice as large as the width B of the lower end of the slot of the flat disk 11. Air is discharged from the device through fitting 14 connected to an air tube 15, which is connected to a rotameter (not shown) to determine the air flow through the device . A spring 7 is used to secure the Petri dish 8; a cap lock 10 is used to secure the top cover 9.

The proposed device is used as follows.

To distribute microorganisms evenly over the entire surface of the dish, the flat disk 6 with the Petri dish 8 should not rotate very quickly (60 rpm). The cup exposure is no more than 10 minutes, after which the electric motor 3 is stopped. Remove the cover 9 of the device. Take out a Petri dish 8 with the inoculation and cover it with a lid. When determining aerobic flora, a Petri dish with inoculation is placed in a thermostat at a temperature of 37° for 24 hours, and then left for 24 hours at room temperature and all grown colonies on the surface are counted. The air flow is regulated by a rotameter. The total sample volume for significant air pollution should be 40-50 liters, and for minor air pollution - more than 100 liters.

The utility model differs from the prototype in that the device is equipped with a diametrical slot 12 for air intake, in which the cross-sectional area of the upper end of the slot is twice as large as the cross-sectional area of the lower end of the latter. Thus, with the required volume of air sample ranging from 40 to 100 liters, the speed of action of the air stream on the nutrient medium increases by 2 times, which gives a more reliable picture of the true content of microorganisms in the air

Claims (1)

A device for bacteriological analysis of air, including a cylindrical body mounted on a base, in which an electric motor is located, connected to an impeller, above which a support disk with a Petri dish is placed, and on the top cover of the cylindrical body there is a ring resting on a flat plexiglass disk equipped with a slot for air suction, characterized in that the cross-sectional area of the upper end of the slot is twice as large as the cross-sectional area of the lower end of the latter, and the slot is located in the diametrical plane of the disk.

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