RU221582U1 - LABORATORY INSTALLATION FOR STUDYING THE EFFECTIVENESS OF DUST SUPPRESSING COMPOSITIONS - Google Patents

Abstract

The utility model is aimed at expanding technological capabilities by ensuring the determination of air dust concentration after treatment with dust-suppressing compounds in the range that is the most dangerous for the human respiratory system.

The laboratory installation for studying the effectiveness of dust suppression compositions contains a supply fan 4, a test chamber 2, inside of which a measuring probe 11 of the control unit 12 is installed. In the proposed solution, the chamber is made of two sections with a rigid partition 3, which has a technological window. In this case, a supply fan 4 is installed in the first 1 section, the diffuser 5 of which is associated with a technological window. Outside, on the upper plane of the first 1 section, there is a switch 6 to turn it off and on and a speed controller 7. The second 2 section has a table 8 for test samples and a filter 9, which is mounted on the transparent end movable cover 10 of the chamber. The internal cavity of the second section 2 communicates through a measuring probe 11 with a control unit 12, which is an optical dust meter. The control unit 12 is fixed to the second 2 section and connected by a wired communication channel 14 with a personal computer 15.

Description

The useful model relates to the field of occupational safety, in particular to means of studying the effectiveness of dust-suppressing compositions, and can be used to simulate the real aerodynamic impact on dust-forming dispersions in laboratory conditions.

The device “Wind tunnel for studying dusty surfaces” is known (patent for invention RU No. 2 748 144 C1, authors: Ivanov A. V., Smirnov Yu. D., Chupin S. A.; published 05.19.2021, bulletin No. 14 ). The wind tunnel includes an exhaust fan, an air supply pipe, a table for test samples, and a means for measuring dust concentration. Additionally, the device is equipped with an air exhaust pipe, both pipes are made in the form of a round pipe on the same axis, which rest on wheel supports with a stopper, and are movably connected to each other by a frame through movable guides. They are equipped with fastenings for hermetically sealed fixation with each other, a removable supply fan and a meteorometer are mounted on the air supply pipe with the possibility of removal, and deturbulizing grilles and removable adjustable deflectors are installed inside it. In this case, there is a hole in the nozzle into which a background dust intake device is installed, which is connected to the dust meter. An exhaust fan and a dust meter are attached to the air exhaust pipe, which can be removed. There is a hole in the nozzle into which an intake device for the measured dust is installed, which is connected to the dust meter. In the middle between the nozzles, a table for test samples is rigidly fixed on adjustable supports; under it, scales are rigidly fixed to the frame, with the possibility of locking with clamps.

The known device is designed to determine air dust concentrations in a wide range, but is difficult to use in laboratory conditions, which is primarily due to the massive design of the wind tunnel.

The closest in technical essence to the declared utility model, adopted as a prototype, is the “Air dust control device”. (Utility model patent RU No. 110 189 U1, authors: Belova T. I., Burak V. E., Gavrishchuk V. I., Agashkov E. M., Kravchenko D. A.; published 11/10/2011, bulletin. No. 31). The air dust control device contains an inlet pipe, a chamber (test chamber), a filter, and recording equipment. A sensitive element (measuring probe) of the dielectric constant of the medium sensor (control unit) is installed inside the chamber, the electrical output of which is connected to the corresponding input of the microprocessor control unit, and between the chamber and the double-sided valve with a filter mounted on it and the inlet pipe connected to it is located rotameter, and on the other side of the inlet pipe a supply fan is connected.

The essential features of the utility model coincide with the following set of features of the prototype: supply fan, test chamber, inside of which the measuring probe of the control unit is installed.

The disadvantage of the prototype design is the limited technological capabilities, which is associated with the impossibility of determining the air dust concentration in the range that is most dangerous for the human respiratory system, the particle size of the dust-forming dispersion: PM10 and PM2.5.

The utility model is aimed at expanding technological capabilities by ensuring the determination of air dust concentration after treatment with dust-suppressing compounds in the range that is most dangerous for the human respiratory system.

This is achieved by the fact that the laboratory installation for studying the effectiveness of dust suppression compositions contains a supply fan, a test chamber, inside of which a measuring probe of the control unit is installed. In the proposed solution, the chamber is made of two sections, separated by a rigid partition with a technological window. In this case, a supply fan is installed in the first section, the diffuser of which is connected to a process window. On the outside, on the upper surface of the first section, there is an on/off toggle switch and a speed controller. The second section has a table for test samples and a filter, which is mounted on a transparent movable end cover of the chamber. The internal cavity of the second section communicates through a measuring probe with a control unit, which is an optical dust meter mounted on the second section and configured to connect via a wired communication channel to a personal computer.

The design of the chamber is two-sectional with a rigid partition having a technological window, which makes it possible to simulate the speed of wind flow in the second section, which is ensured by coupling the fan diffuser with the technological window and the speed controller.

The second section is equipped with a table and a filter mounted on the end cover, which performs the function of forming the structure of the wind flow and makes it possible to freely remove the volume of dust-forming dispersion particles pumped during the action of the wind flow, which is necessary for the accuracy of measuring the dust suppression efficiency indicator of the dust suppressant under study.

The internal cavity of the section communicates through a measuring probe with an optical dust meter, which makes it possible to increase the accuracy of determining the dust concentration in the air in the range of PM10 and PM2.5.

Thus, the set of distinctive features provides a technical result that allows us to solve the problem: expanding technological capabilities by providing the ability to determine the concentration of air dust in the size range of dust particles of a dust-forming dispersion: PM10 and PM2.5, which are the most dangerous for the human respiratory system.

The essence of the utility model is illustrated by the drawing. In fig. 1 shows a general view of the laboratory setup; in fig. 2 - diagram of the control unit, which is an optical dust meter.

The laboratory setup for studying the effectiveness of dust suppression compounds is a rectangular two-section chamber. The first section 1 and the second section 2 are separated by a rigid partition 3 having a technological window. In this case, a supply fan 4 is installed in the first 1 section. The diffuser 5 of the fan 4 is connected, for example, by welding, to the second 2 section and is interfaced with the technological window of the partition 3. Outside the first 1 section there is a toggle switch 6 for turning the fan off and on, as well as wind flow speed controller 7.

The second 2 section, which acts as a test chamber, has a table 8 for test samples and a filter 9. The second 2 section has a side transparent end movable cover 10, on the wall of which a filter 9 is fixed. The internal cavity of the second 2 section communicates through a measuring probe 11 with the control unit 12, which is an optical dust meter (Nova SDS011), with a monochrome screen 13. The monochrome screen 13 of the control unit 12 serves for additional control of the measurement. The control unit 12 is installed outside and fixed to the second 2 section. The control unit 12 is connected by a wired communication channel 14 with a personal computer (PC) 15. The personal computer 15 serves as the main transmitter of numerical values for measuring dust concentration in the air from the control unit 12, after processing the dust-forming dispersion with a dust suppressant composition.

The control unit 12 (Fig. 2) is equipped with a dust collector 16, designed to move small particles of the dust-forming dispersion from the second section 2 of the laboratory installation into the internal channel 17 of the optical dust meter 12. Small particles that enter the optical dust meter block 12 fall into the coverage area of the photodiode 18. for reading the concentration of small particles of the dust-forming dispersion, the control unit 12 is equipped with a photodiode 18 and a laser 19 with a focusing lens 20. The laser beam 19 is extinguished when passing through the light absorber 21, and the small particles of the dust-forming dispersion enter the coverage area of the photoelectric converter 22 and then into the coverage area of the fan 23 Hole 24 serves to release dust-laden air from the control unit 12. Data on the concentration values of dust-forming dispersion particles PM2.5 and PM10 are transmitted to microcontroller 25, connected by a communication channel to personal computer 15.

A laboratory setup for studying the effectiveness of dust suppression compositions operates as follows.

During the research, the effectiveness of the dust suppression composition (DS) is determined, which is subsequently used for dust removal at industrial facilities during storage, storage and transportation of bulk materials

Dust suppression compounds can be, for example, polymer emulsions or water-based solutions. Before starting work, a sample of dust-forming dispersion is distributed onto table 8 and distributed using the PS irrigation method. Samples of dust-forming dispersion can be various bulk fine materials from construction, quarry and mining sites, transported cargo, stored raw materials, extracted minerals, as well as various wastes.

A sample of the dust-forming dispersion, treated with PS, with a layer thickness of at least 5 mm, distributed on table 8, is placed in the second section 2 of the installation, which acts as a test chamber.

The second section 2 is closed with a sliding transparent end cover 10 to observe the object of study during operation of the installation. Modeling of dust in the space is carried out with a continuous supply of air flow to section 2, due to injection by fan 4 located in section 1, through diffuser 5 in contact with the technological window made in partition 3, for 5 minutes. Modeling of dust in the space is carried out, among other things, thanks to the filter 9 located on the end transparent movable cover 10, which creates vortex flows in section 2.

The fan is turned on and off using toggle switch 6, which creates a wind flow. Regulation of the wind flow speed is ensured by regulator 7.

In this case, due to the location of the measuring probe 11 in the internal cavity of section 2, particles of the dust-forming dispersion are fed through the dust collector 16, coupled with the open end of the measuring probe 11, into the control unit 12.

In the control unit 12, the concentration of dust-forming dispersion particles in the air flow is measured. Through the internal channel 17 of the control unit 12, due to the operation of the fan 4, small particles enter the coverage area of the laser 19 with a focusing lens 20 and a photodiode 18, which reads the concentration of dust-forming dispersion particles - in the size range PM2.5 and PM10. After measuring the concentration of small particles of the dust-forming dispersion, quantitative data was displayed on the monochrome screen 13 of the control unit 12. Thanks to an external wired communication channel 14, the numerical values of measuring the concentration of dust in the air - , obtained after treatment with a dust-suppressing composition, were displayed on the PC 15 monitor and made it possible to determine the efficiency coefficient of the composition - .

After optical analysis, the laser beam 19 is extinguished as it passes through the light absorber 21, and particles of the dust-forming dispersion under the action of the fan 23 of the control unit 12 enter the coverage area of the photoelectric converter 22 and exit through the air outlet hole 24. Numerical data on the dust concentration in the air are transmitted to the microcontroller 25 and are displayed on the monochrome screen 13 of the control unit 12. The collection of dust-forming dispersion particles formed in the air zone of the test chamber 2 occurs cyclically during 5 minutes of testing the PS.

The displayed numerical values of dust concentration on the PC monitor 15 and the monochrome screen 13 of the control unit 12 in the dust size range PM2.5 and PM10 are translated into Excel. After forming the dust concentration value of the control, not treated with PS, sample of the dust-forming dispersion ( ) and the concentration of dust in the air after exposure to a wind flow on a dust-forming dispersion treated with PS ( ) the dust suppression efficiency coefficient is assessed ( ) when using a specific PS:

,

Where - dust suppression efficiency coefficient;

- concentration of dust in the air after exposure to a wind flow on a model dust-forming dispersion treated with PS, mg/m ³ ;

- concentration of dust in the air after exposure to wind flow, on a model dust-forming dispersion without PS treatment, mg/ ^m3 .

Based on the results obtained when studying several dust suppression compositions, the most effective one is determined, which is used as a dust suppressant at construction, quarry and mining sites when transporting goods by road, warehousing and storing raw materials, extracted minerals, and waste.

Air dust levels are monitored continuously for a certain period of time.

Thus, the proposed installation, aimed at expanding technological capabilities, makes it possible in laboratory conditions to determine the concentration of dust in the air, indicating the effectiveness of the dust-suppressing composition, by obtaining a quantitative value of the concentration of dust in the air of the test chamber of the installation after treatment with dust-suppressing compositions in the range that is most dangerous for human respiratory system - PM10 and PM2.5.

The work on creating a utility model was carried out within the framework of the Russian Science Foundation grant No. 23-19-00796 on the topic “Physical and chemical principles of designing organome-mineral composite materials for the repair and reconstruction of road pavements”, https://rscf.ru/project/23- 19-00796/, agreement No. 23-19-00796 dated May 15, 2023

Claims (1)

A laboratory installation for studying the effectiveness of dust suppression compositions, containing a supply fan, a test chamber, inside of which a measuring probe of the control unit is installed, characterized in that the chamber is made of two sections, separated by a rigid partition having a technological window, while in the first section there is a supply fan, the diffuser of which is installed is interfaced with the technological window, and on the outside on the upper plane of the first section there is a switch to turn it off and on and a speed regulator, the second section has a table for test samples and a filter, which is mounted on the transparent end movable cover of the chamber, the internal cavity of the second section communicates through a measuring probe with the block control, which is an optical dust meter mounted on the second section and configured to connect via a wired communication channel to a personal computer.