RU2445605C2 - METHOD FOR COMPARATIVE EVALUATION OF PROTECTIVE PROPERTIES OF FILTER MATERIAL BASED ON β,β'-DICHLORODIETHYL SULPHIDE IN DYNAMIC CONDITIONS USING MIMIC THEREOF - METHYL SALICYLATE - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to investigation of protective properties of packets of filter materials for skincare agents based on activated carbon-containing sorbents in dynamic conditions. The method is realised by using methyl salicylate which mimics the penetrating power of ypertite in an air stream at temperature 26±1°C, concentration of methyl salicylate vapour in air stream of 0.05±0.01 mg/l, relative humidity of 65±5% and pressure gradient on the thickness of the packet with surface area 22 cm² equal to 49 Pa, with subsequent analytical determination of the minimum amount of methyl salicylate penetrating the packet and the minimum time for protective action, calculation of the external effective dose of DDS, which the packet of the filter protective material protects from based on the given relationship.

EFFECT: high safety, reliability and information content of the evaluation process.

2 cl, 1 tbl, 2 dwg

Description

The invention relates to the field of studying the protective properties of packages of filtering materials for personal protective skin (SIZK) based on activated carbon-containing sorbents (AUS) under dynamic conditions, when exposed to vapors of β, β'-dichlorodiethyl sulfide (DDS), by using its simulator - salicylic methyl ester acid (MESK), which simulates the penetration of mustard gas.

The use of the simulator is due to the fact that in connection with the entry into force of the "Convention on the Prohibition of Chemical Weapons ..." the number of toxic chemicals (TX) intended for research and testing to evaluate the protective properties of SIZK has been reduced. Carrying out these tests is expensive, associated with the risk to the health of the personnel taking part in them, and is also associated with possible pollution of the environment TX.

In the current situation, the cardinal way to solve these problems is to use non-toxic TX simulators, in particular, in methods for assessing the protective properties of filter-type (FT) SIZK.

It is known that, in some countries, salicylic acid methyl ester (MESC) is used as a simulator of DDS to evaluate the protective effectiveness of promising samples of filtering protective materials (FMS) and products from them [1, 2].

It is known that the quantitative analysis of MESC vapors that passed directly through the SIZK FT materials, as well as at the joints and leakages of the product structure, is carried out using the MIRA 1A device - an infrared detector [3].

However, this method requires complex hardware design and expensive reagents.

It is known that the quantitative analysis of DDS that has passed through the FZM SIZK package is determined by the colorimetric method according to GOST [4].

In the course of preliminary tests on the use of the colorimetric method to assess the protective properties of filtering materials in pairs of the simulator, it was found that this method is of little use due to its low sensitivity according to MESC, therefore, we considered the considered method to be unsuitable for achieving the goals of the work.

Closest to the proposed invention are methods for determining the penetration of MESC vapor through protective filter clothing in general using passive adsorption samplers (dosimeters).

According to the data of [5], film adsorption dosimeters with the sorbent “Tenax” are placed on the testers under protective filtering clothing. At the end of the experiment, dosimeters are analyzed by extraction of the adsorbent with ethanol, followed by determination of the amount of adsorbate by high performance liquid chromatography. The threshold sensitivity of this method is 50 ng MESC.

Tubular adsorption dosimeters with a diameter of 6 mm and a length of 89 mm are placed on mannequins under protective filtering clothing. MESC vapors are concentrated in tubes with the sorbent Tenax. At the end of the experiment, dosimeters are analyzed by thermal desorption in combination with gas chromatographic analysis with an efficiency of 95% [6].

The use of methods using film and tube dosimeters is practically impossible to evaluate the packages of materials of SIZK FT. The use of such dosimeters will lead to the creation of an artificial air gap and a significant change in the filtration area of the SIZK material package, which will change the aerodynamics of the air flow and thereby affect the test results.

The use of tubular dosimeters is possible only for evaluating SIZK samples on mannequins in connection with the need to deepen the dosimeter body.

The objective of the present invention is to develop a safe, rapid method for the comparative evaluation of packages of filter materials SIZK based on active carbon sorbents (AUS). allowing using gas-liquid chromatography to carry out a quantitative determination of the MESC, which penetrated the package of FZM.

The technical result achieved in the claimed invention is:

- the use of MESC as the closest analogue of DDS for the combination of physico-chemical properties;

- assessment of the possibility of using MESC to determine the penetrating ability of DDS through the FMS package of SIZK based on AUS in dynamic conditions using modern analytical equipment;

- modeling of dynamic mass transfer of DDS vapors using MESK, in the frontal sector of the FSM SIZK package, with normal wind pressure;

- improving the safety of ongoing studies on the evaluation of the protective properties of the packages FZM SIZK;

- the possibility of conducting studies to evaluate the protective properties of not only existing, but also promising fabrics of protective filtering clothing based on AUS with air permeability in the range of 30 ... 80 dm ³ · m ^-2 · s ^-1 ;

- the possibility of conducting research under the terms of the “Convention on the Prohibition of the Development, Production, Stockpiling and Use of Chemical Weapons and Their Destruction”.

The problem is solved by performing the following research steps to justify the choice of a DDS simulator:

1. Assessment of the possibility of determining MESK using gas-liquid chromatography.

2. Conducting comparative studies to determine the amounts of DDS and MESC penetrating packets of filtering protective materials in dynamic conditions.

3. Establishment of the relationship between the main indicators during the penetration of the DDS and its simulator MESC through the FMS package of SIZK based on the AUS.

4. Determination of the external effective dose of DDS vapors by MESC, from which the FMS package of SIZK based on AUS protects under dynamic conditions.

A quantitative assessment of the DDS and MESC vapors that penetrated the sample of the FZM package was carried out using gas-liquid chromatography on a gas chromatograph with a flame ionization detector, using the calibration method. The sensitivity of the determination of MESC in this case is up to 1 · 10 ^-6 mg · ml ^-1 [7].

To confirm the above, a comparative assessment of the protective properties of the packages of filtering protective materials for DDS and MESC using the method proposed in this work.

The essence of the method consists in the dynamic mass transfer of the MESC steam-air flow through the FZM packet with a space velocity equal to its air permeability coefficient through a 22 cm ² sample with a standard pressure gradient across the packet thickness of 49 Pa, followed by an analytical determination of the amount of MESC penetrating the sample in time FMS package based on AUS.

The time of the protective action for the pairs of the simulator is conditionally tied to the criterion value for the DDS vapors and corresponds to the number of MESCs that penetrated the FMS package on the basis of the ACS during its protective action from the DDS vapors.

The objects of the study were two packages of FZM with different versions of the chemical protective layer, while in both packages the Viniliskozha-T fabric with a discrete polymer coating was used as a covering layer, and calico as a hygienic layer.

Package No. 1:

- fire retardant layer - “Viniliskozha-T” fabric;

- chemical protective layer - on the basis of carbon-filled paper;

- a hygienic layer - coarse calico.

Package No. 2:

- fire retardant layer - “Viniliskozha-T” fabric;

- chemical protective layer - based on mesh active carbon fabric;

- a hygienic layer - coarse calico.

Samples of the tested materials are cut according to the template and fixed in a dynamic device (see figure 1).

The dynamic device is made of stainless steel and consists of: a sampling fitting from under the FZM package (1); lower part of the body (2); clamping screws (3); sampling nozzle of influencing concentration (4); steam supply connection (5); the upper part of the body (6); of the test package FZM (8).

A laboratory unit for assessing the protective properties of packages of filtering materials for pairs of salicylic acid methyl ester (see figure 2) includes: a hygrostat (9) for humidifying the air supplied to the system to the specified values of relative humidity; a psychrometer (10) for controlling the humidity of the air flow, an evaporator with a substance (11); control valve (12) for adjusting the concentration of the vapor-air mixture; a mixer (13) to create a vapor-air mixture of a given concentration; dynamic device (14); two-way valve (15) for the selection of the effective concentration of vapor MESK; two-way valve (16) for the selection of MESC vapors for the Federal Reserve Package; a Drexel bottle with benzene (17) for sampling the affecting vapor concentration; a Drexel bottle with benzene (18) for sampling the concentration of vapors that have penetrated the FZM packet; aspirator (19).

The installation is connected to an aspirator, the temperature in the thermostat is set (26 ± 1) ° С, the concentration of MESC vapors in the vapor-air stream (0.05 ± 0.01) mg · l ^-1 , the relative humidity of the air stream (65 ± 5)%.

The volumetric speed of the air flow is created equal to the speed of the air flow penetrating through this FZM packet with an area of 22 cm at a pressure gradient of 49 Pa, according to GOST [8].

MESK vapors that penetrated the sample of the FZM package are trapped in Drexel with benzene. After a time interval of 2-5 minutes, Drexel (10) is replaced with a new one, depending on the protective properties of the FZM package. From captured Drexels in vials for an automatic sampler of a gas-liquid chromatograph, samples in a volume of 1 ml are taken to determine the concentration of MESC in the solution.

The concentration of β, β'-dichlorodiethyl sulfide and MESC in the extract is determined according to a previously constructed calibration schedule.

The results of experimental studies are presented in the table.

Table Comparative values of the criterion value of DDS to imitope Test material Critical amount of DDS mg · cm ^-2 The minimum number of MESC, penetrated for the package FZM for DZD DDS, mg · cm ^-2 Package No. 1 0.0025 0.0015 Package No. 2 0.0015

The analysis of this table shows that the number of MESC vapors, correlated with the criterion value for the VDS vapors according to the table, is 1.5 · 10 ^-3 mg · cm ^-2 , which corresponds to the number of MESC that penetrated through the FSM packets, based on the AUS, for the time of its protective action against DDS vapors.

During the protective action, the minimum value of the VZD is taken for six parallel point samples of the FSM packets.

Thus, on the basis of the results of experimental studies, the penetration of DDS and MESC vapors under dynamic conditions, it was found that to obtain the output DDS curves from the MESC output curves in the region of the VZD from the DDS in the interval 0 ... 15 minutes, the conversion factor obtained by the formula

where K is the conversion factor for the number of MESCs to the number of DDS that penetrated through the FZM packet in the time domain of its time of protective action for DDS;

Q _DDS - the criterial amount of DDS vapors that penetrated the package of FZM during the protective action, mg · cm ^-2 ;

Q _MESL - the number of MESC vapors that penetrated the FZM package during the protective action for the VDS pairs, mg · cm ^-2

Thus, the conversion factor for FMS packages based on AUS with air permeability in the range of 30 ... 80 dm · m ^-2 · s ^-1 is 1.7.

The external acting dose of DDS vapors, from which the FMS package protects, is calculated by the formula:

where [Ct _DDS ] is the external acting dose of DDS vapors, mg · l ^-1 · min;

C is the external exposure concentration of the MESC vapors, mg · l ^-1 ;

t _VZD - minimum time of protective action for pairs MESK, min;

At the end of the tests, the dynamic device is unmounted, the FZM samples are placed in the solid waste collector, the dishes and utilities are washed with acetone or ethyl alcohol.

Thus, the developed technical solution allows the use of salicylic acid methyl ester as a low-toxic simulator of β, β'-dichlorodiethyl sulfide in the comparative assessment of the protective properties of filter type SIZC based on activated carbon sorbents with air permeability in the range of 30 ... 80 dm ³ · m ^-2 · s ^-1 .

The main advantage of the proposed method is that:

instead of β, β'-dichlorodiethyl sulfide assigned to hazard class I, a low-toxic substance is used - MESC assigned to hazard class IV;

the method allows to evaluate the protective properties of the FMS packages on the basis of AUS under the most critical, dynamic conditions of the penetration of DDS vapors due to the influence of a normal wind flow;

the method allows a comparative assessment of the protective properties of not only existing, but also promising tissue samples SIZK FT based on AUS;

the method allows to reduce the time spent on a comparative assessment of the protective properties of the packages FZM, due to the most stringent conditions for the actual functioning of the SIZK FT as intended;

quantitative determination of the mass concentration of salicylic acid methyl ester penetrating the sample of material is carried out on a gas chromatograph with a flame ionization detector by the absolute calibration method with a detection sensitivity of up to 1 · 10 ^-6 mg · ml ^-1 and a relative error not exceeding 15%.

Bibliography

Claims (2)

1. A method for comparative assessment of the protective properties of packages of filtering materials for personal protective skin (SIZK) based on activated carbon-containing sorbents (ACS) under dynamic conditions when exposed to vapors of β, β'-dichlorodiethyl sulfide (DDS) by using a simulating penetrating ability of mustard gas simulator - methyl ether salicylic acid (MESC) in the air stream at a temperature of 26 ± 1 ° C, the concentration of MESC vapors in the air stream is 0.05 ± 0.01 mg / l, relative humidity 65 ± 5% and the pressure gradient across the thickness of the pack and an area of 22 cm ^2, equal to 49 Pa, followed by analytical determination of the minimum amount of permeating through the package and mESC minimum time of protective action, outer impacting dose calculation SDS vapors, which protects the protective filter bag material defined by the formula
_SDS Ct = C · t _PDM,
where Ct _DDS is the external acting concentration of the vapor of DDS, mg / l · min;
C is the external exposure concentration of MESC vapor, mg / l;
t _VZD - minimum time of protective action for pairs MESK, min. 2. The method according to claim 1, characterized in that the MESC is a low-toxic substance classified as hazard class III.

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