RU2422802C1 - Procedure for evaluation of dust content of working zone - Google Patents

Abstract

FIELD: machine building. ^ SUBSTANCE: procedure for evaluation of dust content of working zone consists in forced sedimentation of aero-dispersed impurities on filter from certain volume of air. To determine weight of clean filter equipment is initially prepared and set. Further, the clean filter is weighted on a balance (analytical or electron). Successively, there is set an installation for forced sedimentation of dust aerosol in the working zone of a shop floor. Air is sampled with capture of dust particles on the filter. The filter with captured particles of dust is weighted. There is calculated concentration of dust aerosol in milligrams per cubic metre by formula: C=(m2 -m1)/V0, where m2 is weight of a dusted filter, mg; m1 is weight of a clean filter, mg; V0 is volume of air (m3), passed through the filter. Also, volume of air (m3) passed through the filter should be preliminary reduced to normal conditions (i.e. to volume, which it would occupy at temperature 0C and normal atmospheric pressure equal to 101325 Pa by formula: where 273 is absolute temperature, K; T is temperature of air (gas) C; Bact is actual barometer pressure at the moment of sampling, Pa; Bn is normal atmospheric pressure equal to 101325 Pa; v is flow rate of sampling, l/min; ä is time sampling, min; 1000 is coefficient of conversion of litres into cubic metres (1 m3=1000 l). There is evaluated dust content of the working zone by comparison of obtained concentration with an allowed value. ^ EFFECT: raised efficiency, operation speed and reliability of system response. ^ 2 tbl, 3 dwg

Description

The invention relates to mechanical engineering, in particular to devices of security systems.

The biological activity, in particular fibrogenic, allergenic, toxic and irritating properties, depends on the chemical composition of dust. The fibrogenicity of dust (the ability to turn elastic lung tissue into coarse, scarring, not involved in the absorption of oxygen from exhaled air) depends mainly on the content of free silicon dioxide (SiO ₂ ) in it. The higher the content of free silicon dioxide in the dust, the more aggressive it is considered.

It is known that to study the concentration of dust and its dispersed composition, weight, counting photometric and radiometric methods are used (see Belov S.V. Life Safety Textbook. - M.: Higher School, 2003).

In the gravimetric method, dust concentration is expressed in milligrams per cubic meter of air.

With the counting method, the number of dust particles contained in one cubic centimeter of the test air is calculated, and their sizes (dispersion - fractional composition of dust) are determined under a microscope or using projection equipment. The counting method is auxiliary to the weight method, it is used most often in hygienic studies.

Instruments for measuring air dust by photometry are called photo dust meters. The principle of operation of these devices is based on the photometric measurement of the change (attenuation) of the intensity of the light flux passing through dusty air. Photo dusters allow you to easily and quickly determine the concentration of dust in the air, but they are much inferior in accuracy to measurements by the weight method using AFA-B analytical filters.

The principle of operation of radiometric devices (for example, IZV-3) is based on determining the degree of absorption of alpha radiation of the sample taken on the filter. In the presence of radon in the air, the device simultaneously measures its short-lived daughter products.

Known devices whose operation is based on other principles of action. However, all of them, having one advantage - the speed of analysis, have one common drawback - lower accuracy of the result (error ± 30% or more).

The closest technical solution to the claimed object is a method for determining dust concentration according to SU No. 1631364, G01N 15/00, 1991 (prototype).

A disadvantage of the known solution is the relatively low response reliability and low speed of the sampling system.

The technical result is an increase in efficiency, speed and reliability of the system.

This is achieved by the fact that in the method for assessing the dustiness of the working area, which consists in the forced deposition of aerodispersed impurities on the filter from a certain volume of air, first prepare and set up the apparatus for determining the mass of the clean filter, then weigh the clean filter on the balance (analytical or electronic), and then set up the installation for forced deposition of dust aerosol in the working area of the production room, then take an air sample with the capture of dust particles on the filter p is weighed filter with the collected particles of dust, dust aerosol concentration is calculated in milligrams per cubic meter according to the formula:

C = (m ₂ -m ₁ ) / V _o ,

where m ₂ is the mass of dusty filter, mg; m ₁ - mass of pure filter, mg.

V _o is the volume of air (m ³ ) passed through the filter.

In this case, the air volume (m ³ ) passing through the filter must first be brought to normal conditions (i.e., to the volume that it would occupy at a temperature of 0 ° C and normal atmospheric pressure equal to 101325 Pa) according to the formula

where 273 is the absolute temperature, K; T - air (gas) temperature, ° C; In _f - the actual barometric pressure at the time of sampling, Pa; In _n - normal atmospheric pressure equal to 101325 Pa; ν is the sampling rate, l / min; τ is the sampling time, min; 1000 is the coefficient of conversion of liters to cubic meters (1 m ³ = 1000 l), and the dust content of the air of the working area is evaluated by comparing the concentration obtained with the permissible value.

Figure 1 shows a schematic diagram of a device for implementing a method for assessing the dust content of the working area (RE); figure 2 shows a diagram of an installation for sampling air, figure 3 is a filter for sampling air.

A device for implementing the method (figure 1) for assessing the dust content of the working area (RE) contains the following functional blocks: analytical filter, scales, installation for sampling.

The proposed method is intended to determine the concentration of aerodispersed impurities (dust, smoke, fog) in the air at temperatures up to 60 ° C. The essence of this method consists in the forced deposition (capture) of aerodispersed impurities on the filter from a certain volume of air, determining the increase in the mass of the filter and calculating the concentration of aerosol in milligrams per cubic meter.

The method is based on the use of analytical aerosol AFA filters (Fig. 3) made of hydrophobic high-performance nonwoven filter material FPP (perchlorovinyl Petryanov filters). Of the many filters used to capture various substances (dust, vapors, mists, etc.), AFA-VP-10 and AFA-VP-20 filters are used to study air dust. The letter B means that the filter is suitable for the weight method, and the numbers 10 and 20 indicate the area of the filter circle (cm ² ).

The method of assessing the dust of the working area (RE) is as follows.

Determination of aerosol concentration consists of four stages: preparation of equipment and filters; aerosol selection on the filter; determination of the change in filter mass after sampling; calculation of aerosol concentration.

Before sampling in the laboratory, it is necessary to check the serviceability of the equipment indicated in Table 1 and determine the initial weight of the filters. The filters are weighed on an ADV-200 analytical balance as follows: remove one set of the analytical filter from the holder, unfold the protective paper rings and remove the filter from them, then fold it with tweezers four times and place it in the center of the weighing pan. In this case, make sure that the edges of the filter do not protrude beyond the edges of the weighing pan, otherwise its mass will be incorrectly determined. After weighing, the filter is carefully spread out over the pressed edges with tweezers, placed again in protective paper rings and placed in a bag of tracing paper, which is inserted into a clip. In a similar way, the rest of the required filters are weighed. The mass of each filter and its serial number are recorded in the laboratory journal and at the same time put on the protrusions of the protective rings.

At the place of sampling, an allonge is mounted on a tripod (sample holder-filter holder) and connected with rubber hoses in series with the flowmeter and suction device, as shown in the circuit diagram shown in figure 2.

Test the operation of the installation and check the tightness of the joints at the joints, especially in the area between the allonge and the flow meter. Then a filter kit is removed from the holder, inserted into the allonge and secured with a union nut. After that, the suction device is turned on, a certain air flow rate is set by the control valve-valve, and a sampling is made by switching on the stopwatch simultaneously with the suction device. The control valve is usually located in the tee in front of the suction device. As a result of the vacuum (vacuum) created by the suction device, the air will begin to filter through the AFA filter cloth, leaving the smallest particles of the aerosol under study on it. The mass of the filter will begin to increase.

Installation for sampling air (figure 2) contains a clamping nut 1, an AFA filter (figure 3), a filter holder (allonge) 3, a flow meter 4, an adjusting valve 5, a tee 6, an aspirator 7.

The sampling rate is set taking into account the degree of dustiness of the air and the technical capabilities of the aspirator, but not higher than 100 l / min. At speeds of 30-100 l / min in the allonge, a support mesh is installed behind the filter, which prevents the filter from breaking. At the end of the sampling, the aspirator and stopwatch are turned off.

Throughout the entire sampling time, the aspirator control valve maintains a constant air volumetric flow rate. The need for such adjustment is due to an increase in the resistance of the filter material to the air flow as dust accumulates on it, as well as a possible voltage fluctuation in the network. Both of these reasons can cause deviations in the readings of the rheometer against the originally set air flow rate. The duration of sampling is selected depending on the dust content and flow rate (Table 2).

Table 2 Estimated dust content, mg / m3 Sampling rate, l / min Duration of sampling, min 0.3-1 one hundred No more than 30 1-10 one hundred 10 10-100 15-30 30-15 Over 100 5-10 10-5 Note. A lower speed corresponds to a longer sampling time.

The minimum required dust sample on the filter should be at least 1 mg, and the maximum allowable - not more than 100 mg.

After sampling, the allonge is disconnected from the aspirator, the filter is removed from it, taking on the protrusion of the paper rings, the outer side up (so as not to dust from the filter). Then the filter is folded in half (dusty side inward) and placed in the bag in which it was before taking the sample. The bag with the used filter should be placed in a cardboard box. The vacant allonge is charged with a clean filter to take the next sample.

At the end of sampling, all used (dust-contaminated) filters are weighed on the same balance.

When sampling for each filter, a separate entry is made in the journal, which indicates the date, place and conditions of sampling the aerosol, filter number, speed and duration of sampling, temperature and air pressure.

Calculation of aerosol concentration. The air volume (m ³ ) passing through the filter must first be brought to normal conditions (i.e., to the volume that it would occupy at a temperature of 0 ° C and normal atmospheric pressure equal to 101325 Pa) according to the formula

where 273 is the absolute temperature, K; T - air (gas) temperature, ° C; In _f - the actual barometric pressure at the time of sampling, Pa; In _n - normal atmospheric pressure equal to 101325 Pa; ν is the sampling rate, l / min; τ is the sampling time, min; 1000 - coefficient of conversion of liters to cubic meters (1 m ³ = 1000 l).

Due to the fact that the correction for barometric pressure has little effect on the accuracy of the result, in practice it is often limited to introducing corrections only to temperature. In other words, the calculation is carried out according to a simplified formula

The aerosol concentration (mg / m ³ ) is determined by the formula

where m ₂ is the mass of dusty filter, mg; m ₁ - mass of pure filter, mg.

Then assess the dustiness of the air of the working area, comparing the obtained concentration with an acceptable value.

Claims (1)

A method for assessing the dustiness of the working area, which consists in the forced deposition of aerodispersed impurities on a filter from a certain volume of air, characterized in that the apparatus for determining the mass of a clean filter is first prepared and tuned, then the clean filter is weighed on a balance (analytical or electronic), and then the setup is adjusted for the forced deposition of dust aerosol in the working area of the production room, then an air sample is taken with the collection of dust particles on the filter, eshivayut filter with the collected particles of dust, dust aerosol concentration is calculated in milligrams per cubic meter according to the formula:
C = (m ₂ −m ₁ ) / V ₀ ,
where m ₂ is the mass of dusty filter, mg; m ₁ - mass of pure filter, mg.
V ₀ - the volume of air (m ³ ) passed through the filter,
the volume of air (m ³ ) passing through the filter must first be brought to normal conditions (i.e., to the volume that it would occupy at a temperature of 0 ° C and normal atmospheric pressure equal to 101325 Pa) according to the formula

where 273 is the absolute temperature, K; Т - air (gas) temperature, ° С; In _f - the actual barometric pressure at the time of sampling, Pa; In _n - normal atmospheric pressure equal to 101325 Pa; ν is the sampling rate, l / min; τ is the sampling time, min; 1000 - coefficient of conversion of liters to cubic meters (1 m ³ = 1000 l),
and assess the dustiness of the air of the working area, comparing the concentration obtained with an acceptable value.

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