RU2425347C1 - Method of determining air-tightness of entire sets of personal protective equipment with simultaneous exposure to aerosol and vapour of physiologicaly active substances - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: assessment of air-tightness of sets of personal protective equipment is carried out in dynamic conditions for real performance of operations of physical actions of a person in personal protective equipment in contaminated atmosphere with simultaneous exposure to aerosol or vapour phase of imitators of physiologically active substances.

EFFECT: high sensitivity of determining coefficient of leakage of physiologically active substances into space under clothes.

Description

The invention relates to the field of research of quality indicators of materials and products of personal protective equipment (PPE).

Among the protective characteristics determined by sets of personal protective equipment, an important place is taken by the degree of tightness of the product structure when exposed to vapors and aerosols of physiologically active substances (FAS). The tightness of the design of PPE is characterized by the coefficient of suction of steam or aerosol, which is defined as the ratio of the concentration of the surfactant that has penetrated the sub-suit or under-mask space of the PPE to the external concentration.

In domestic practice, there are no methods and methods for assessing the tightness of sets of PPE as a whole from vapors and aerosols of FAWs, which make it possible to determine the quantities of FAE that have penetrated into the undersuit and under-mask space of PPE at the level of their safe concentrations.

Currently, leakproofness tests of PPE are carried out with the involvement of testers separately for skin protection and respiratory protection when exposed to steam or aerosol simulator FAV.

Tests of personal protective skin products (SIZK) are carried out according to the methods set forth in GOST B 21969-83 [1], using FAV steam imitators. However, these methods have inherent disadvantages, the main of which are:

- low sensitivity, insufficient to assess the protective properties of modern PPE using criteria equal to the maximum permissible concentrations of FAA;

- the impossibility of assessing the tightness of the PPE set as a whole. Tests of the tightness of respiratory protective equipment (RPE) are carried out according to the method GOST 12.4.157-75 "Nephelometric methods for determining the coefficient of suction of oil fog under the front part" [2]. This technique allows you to determine the coefficient of suction of the FAW simulator under the front part of the SIZOD at the level of 1.0 · 10 ^-4 %. However, due to the lack of the ability to assess the tightness of PPE sets in general, especially for samples in which respiratory protection is an integral part of the design of PPE, the GOST 12.4.157-75 method does not fully comply with modern requirements.

Foreign methods for assessing the tightness of PPE as a whole, used during testing in leading scientific centers in the USA, Canada and Europe [3, 4], are mainly based on the widespread use of mannequin systems, which, as practice [5] shows, is not always justified in the lack of compliance with the anthropometric characteristics of the dummy and testers, as well as the different nature of the intensity of the actions they simulate, which leads to a significant difference in the results obtained on testers and dummies. In addition, during the tests, FAV simulators are used only in the vapor or only in the aerosol phase without taking into account their combined effect, which is typical for the actual operating conditions of PPE.

The inventors of the present invention have developed a method for determining the tightness of sets of personal protective equipment in general, using aerosol simulators and steam FAA. At the same time, PPE tests are carried out in dynamic conditions, providing modeling of the real processes of the functioning of personal protective equipment in the atmosphere contaminated with aerosols and PAF vapors.

The difference between the present invention and the known ones is the possibility of assessing the tightness of the sets of PPE as a whole with the simultaneous exposure to simulators of aerosol and vapor FAV. In addition, it is possible to determine the coefficient of suction of the FAW aerosol at the level of 1.0 · 10 ^-4 % [2], which makes it possible to assess the protective properties of PPE according to the most stringent criteria, and it is also possible to determine specific places for leakage of PPE.

According to the inventive method, tests for assessing tightness are carried out in a special chamber with a volume of 12 m ³ , which allows the simultaneous location of two testers performing typical physical exercises. To evenly distribute aerosol and vapor simulators along the volume of FAWs, the chamber is equipped with fans and an exhaust system. The design of the chamber also includes technological openings for monitoring the actions of testers, feeding aerosol and steam into the internal volume, mounting sampling tubes to select the concentrations of aerosol and steam that are exposed to and entered into the SIZ space.

For testing, a standard oil mist (SMT) having a particle size dispersion of 0.2-0.3 μm is used as a model aerosol of FAV, which ensures its maximum penetrating ability in places of leakage in the design of PPE.

As model steam, chlorine gas is used. In preparation for the tests, fittings are mounted in the PPE sets for sampling from the under-mask and under-suit space. The number and specific mounting locations of the fittings are determined based on the design features of the PPE, but the total number of fittings should be at least seven. In this case, the sampling nozzles must be mounted in the area of the front part of the RPD, neck, chest, forearm, back, groin and lower leg, as well as in places of potentially leaky structural elements identified during visual inspection of the tested samples (articulation of components, structural connectors, etc. .).

When testing sets of SIZK made of filtering protective materials, the mounting places of the sampling fittings are pre-glued with adhesive tape. The size of the sizing is 40-50 cm ² .

The fittings are connected using PVC pipes to a common collector, to which a FAN photometer or an aspirator with indicator tubes are connected. The collector provides the possibility of sequential sampling from the suit space of the PPE through each mounted fitting.

The concentrations of SMT aerosol and gaseous chlorine acting on the PPE are created by simultaneously supplying them to the test chamber, while the values of their mass concentrations are monitored only for chlorine; for SMT, the readings of the FAM photometer microammeter are determined by passing through it an aerosol taken from the test chamber.

The control of the effecting concentration of chlorine and the readings of the microammeter of the FAN photometer are carried out at each sampling from the suit space of the PPE.

When the chlorine concentration in the test chamber reaches 10% higher than the value specified by the test conditions, testers enter the test chamber and perform a set of typical physical exercises.

After 3 minutes from the mask and sub-suit space of the PPE, put on the testers, at a speed of 1 l · min ^-1 , samples are taken sequentially on the FAN photometer and on indicator tubes.

The sampling time for the photometer through each mounted fitting is at least 1 min, while the first sample is taken for analysis from the submask space of the RPD.

After recording the readings of the FAN photometer, an aspirator is connected to the collector and, through the same fitting, a sample is taken on the TI-Cl ₂ indicator tube _{of the} RPA. 415522.505-52 with a measurement range from 5.0 · 10 ^-4 to 0.2 mg · l ^-1 and determine the concentration of chlorine that has penetrated into the under-mask and under-suit space of the kit.

Further, using the formulas (1.2), the partial coefficients of suction of the aerosol and steam into the under-mask and under-suit space of the PPE set in the area of the i-fitting are determined:

where K _{(aer) i} is the coefficient of suction in the under-mask and under-suit space of the PPE set as a whole of the aerosol FAW, determined in the area of the i-fitting,%;

I and I _air - microammeter readings when passing through the camera a photometer aerosol, taken respectively from the submask or sub-suit space of the PPE and the test chamber, μA;

D, D _air - the total optical density of the included absorbers when measuring readings I and I _air .

where K _{(steam) i} is the coefficient of suction in the under-mask and under-suit space of the PPE set as a whole, a couple of FAWs,%;

With _PP - the concentration of chlorine that penetrated into the under-mask and undersuit space in the area of the i-fitting, mg · l ^-1 ;

With _air - the concentration of chlorine in the chamber during sampling in the region of i - fitting, mg · l ^-1 .

According to the formula (3), the general coefficient of suction of an aerosol or vapor of FAW into the sub-suit space of the PPE set as a whole is determined:

where K _{(sub) air} or K _{(sub) steam} is the coefficient of suction in the under-suit space of the PPE kit as a whole of an aerosol or vapor of FAV,%;

i is the number of samples taken from the suit space of the PPE kit.

When testing sets of PPE, in which respiratory protection and skin protection are separate structural elements, when calculating the total coefficient of suction of the kit as a whole, the coefficient of suction for the front part of the RPE is not taken into account.

To establish the reliability of the proposed method were tested sets of PPE as a whole. The sets of PPE with high and medium degrees of tightness of the structure were tested. The PPE kits included respiratory and skin protection.

During the tests, the aerosol suction coefficients for the front part of the SIZOD were determined in accordance with GOST 12.4.157-75, the steam suction coefficient in the sub-suit space of the SIZK in accordance with GOST B 21969-83, as well as the aerosol and steam suction coefficients in the PPE set as a whole according to the method proposed by the authors .

The technical result obtained during the tests is shown in the table.

Table The results of determining the tightness of PPE sets in general Sampling area The coefficient of suction kit in the i-area,% Coefficient of suction of the RPE by aerosol,% (GOST 12.4.157-75) The suction coefficient of the SIZK in pairs,% (GOST B 21969-83) K _{(under) aero} K _{(sub) pairs} PPE kit with a high degree of tightness SIZOD 1,0 · 10 ^-4 Less than 5.0 · 10 ^-2 2.0 · 10 ^-4 --- Neck area 5.0 · 10 ^-4 Less than 5.0 · 10 ^-2 --- Less than 5.0 · 10 ^-1 Chest area 7.0 · 10 ^-3 Less than 5.0 · 10 ^-2 Back area 1,0 · 10 ^-3 Less than 5.0 · 10 ^-2 Forearm area 2.0 · 10 ^-4 Less than 5.0 · 10 ^-2 Groin area 3.0 · 10 ^-3 Less than 5.0 · 10 ^-2 Shin area 1,0 · 10 ^-4 Less than 5.0 · 10 ^-2 Average value for SIZK 1.7 · 10 ^-3 Less than 5.0 · 10 ^-2 PPE kit with medium tightness SIZOD 3.0 · 10 ^-2 Less than 5.0 · 10 ^-2 2.0 · 10 ^-2 --- Neck area 24.1 29.4 --- 26.0 Chest area 23.3 26,4 Back area 20.1 15.1 Forearm area 17.3 31.3 Groin area 14.1 10.5 Shin area 15.3 26.3 Average value for SIZK 19.0 25.6 Note - “---” - data not received due to lack of test procedures

The above data indicate that the inventive method allows to determine the tightness of the design of sets of PPE as a whole with the simultaneous exposure to aerosol and vapor FAW with a sensitivity exceeding existing methods.

An analysis of the data in the table also shows that the values of the coefficients of steam suction, determined by the present method and the method according to GOST B 21969-83, have almost the same value for a set of PPE with an average degree of tightness, which indicates a high convergence of the results. In addition, the assessment of the coefficient of leakage by the present method involves a significantly lower expenditure of material resources and time for the preparation of tests.

For a suit with a high degree of tightness, the aerosol suction coefficient was determined, while existing methods do not allow this.

It should be noted that the obtained data indicate the real protective properties of PPE and can be used in scientific studies on the penetration of vapor and aerosol FAV in the undersuit and under-mask space of sets of PPE.

Literature

1. GOST B 21969-83. [Text]. - Kazan: KazKhimNII, 1983 .-- 18 p.

2. GOST 12.4.157-75 Nephelometric methods for determining the coefficient of suction of oil fog under the front part. [Text]. - M.: Gosstandart of Russia, 2003. - 6 p.

3. A whole system test for assessing the protective afforded by NBC protective clothing after liquid or vapor chemical agent challenge, [Electronic resource], James Battensby, Ann E Hayhurst and Alison L Webb CB Systems, CBD Portpn Down, Salisbury, UK. Proceedings 7 ^th International Symposium on Protection against Chemical and Biological Warfare Agents, 2-6 June, 2004, Gothenburg, Sweden.

4. The Canadian Vapor Protection System Test: A Novel Methodology to Assess the Protection Capability of CB Protective Ensembles, [Electronic Resource], Duncan S, Gudgin Dickson E, Weagle G, and Tremblay-Lutter J, Proceedings 6 ^th International Symposium on Protection Against Chemical and Biological Warfare Agents, Stockholm, Sweden, May, 1998, pp 245-251.

5. HUMAN-MANNEQUIN COMPARISONS IN TESTING NBC PROTECTIVE CLOTHING; [Electronic resource], Tiny van Houwelingen ¹⁾ , Eva Gudgin Dickson ²⁾ and Julie Tremblay Lutter ³⁾ :

1) TNO Prins Maurits Laboratory, Rijswijk, The Netherlands

2) Royal Military College (RMC), Kingston, Ontario, Canada

3) Defense Research and Development Canada, Ottawa, Canada.

Claims (1)

A method for determining the tightness of sets of personal protective equipment as a whole with the simultaneous exposure to an aerosol and a pair of physiologically active substances by measuring their quantities penetrating the undersuit space, characterized in that the tightness of sets of personal protective equipment is assessed in dynamic conditions of the actual execution of physical actions of a person in means personal protection in an infected atmosphere with simultaneous exposure to the aerosol and vapor phases of fi simulators iologicheski active substances.