RU29471U1 - SORBING FILTER FOR EASY RESPIRATOR - Google Patents

Description

SORBING FILTER FOR EASY RESPIRATOR

The utility model relates to the field of personal respiratory protection against gases and vapors in the air and can mainly be used in filters of light respirators.

Known used in light respirators filter materials from fibrous polymeric materials of various chemical compositions according to the patents of the Russian Federation No. 2014855, 1994, No. 2023454,1994, No. 2042394, 1995, No. 2049525,1996 and No. 2135263, 1999, as well as from the literature (Kaminsky S .L., Basmanov P.I. Personal Protective Equipment. - M .: Military Publishing House, 1988, p. 4345. Petal (Light Respirators) / Petryanov I.V. et al. - M .: Nauka, 1984, p. 60 ) These filtering materials perform effective aerosol filtering, but do not provide respiratory protection from vapors and gases, because they do not have sorption properties.

MPK7A62V23 / 02, A62V7 / 10

Known from the literature (Petal (Light respirators) / Petryanov I.V. et al. - M .: Nauka, 1984, pp. 194-195) and according to the patent of the Russian Federation No. 2068282, 1996 sorbing materials from porous polyacrylonitrile fibers, inside of which Powdered sorbent, for example, activated carbon. Such sorbent materials provide effective protection of the respiratory system from organic gases, for example, hexachlorobutadiene, but are ineffective in protecting against inorganic gases and vapors due to the low sorbing properties of activated carbon in relation to these substances. Moreover, the list of harmful gases and vapors that these sorbent materials provide protection against is very limited, since there are currently no methods for introducing other sorbents other than activated carbon, primarily water-soluble, into the fibers of this structure. In addition, the complexity of the technology of introducing activated carbon into porous fibers leads to the high cost of these sorbent materials.

From the literature (Petal (Light respirators) / Petryanov I.V. et al. - M .: Nauka, 1984, p. 188, Fig. 10.2) a sorption filter of the sorption-filtering light respirator of the type Petal-G is known, which is made in the form a layer of fibrous polymer filtering material of the FPP-70-0.3 type, filled with powdered activated carbon, impregnated with iodine as a chemisorbent, and provides effective protection of the respiratory system from mercury vapor and organic substances. However, due to the types of sorbents used, this sorbent filter does not protect the respiratory system from

inorganic gases. In addition, the layer of fibrous filtering material of the FPP-70-0.3 type used in its construction consists of fibers with a diameter of about 7 μm and has a sufficiently high resistance to air flow equal to 3 Pa at an air flow rate of 1 cm / s. This does not allow the filling of this known filter with sorbents, carried out by blowing air through it with dusty sorbents to a sorbent content corresponding to the surface density of the sorbent (sorbent mass per filter area) of more than 4 mg / cm2. This circumstance significantly limits the sorption capacity and time of protective action of the specified sorbent filter.

The closest in design and protective properties to the proposed sorbent filter for a light respirator should be considered the sorption filter of the sorption-filtering lung respirator type Lepestok-A (Lepestok (Light respirators) / Petryanov I.V. et al. - M .: Nauka, 1984, p. 194), which is made in the form of a layer of fibrous polymer filtering material of the FPP-70-0.3 type, filled with powdered activated carbon, and is intended for sufficiently effective protection of the respiratory system from a number of organic solvents and other things in, for example, xylene, epichlorohydrin hexachlorane, toluene and hexachlorobutadiene. For example, with a surface density of the sorbent of about 6 mg / cm2, an air flow rate through the filter of 6 cm / s, a concentration of hexachlorobutadiene of 0.4 mg / m3 corresponding to 40 maximum permissible concentrations, and a relative humidity of 50%, such a sorption filter provides

the slip rate of these toxic vapors is not more than 1% and the protective action time is not less than 8 hours.

However, activated carbon used in this sorbent filter as an adsorbent provides it with a protective effect, as a rule, only against organic toxic gases and vapors, but does not allow the use of such a sorption filter in respirators to protect it from acidic and basic gases and inorganic vapors, which significantly reduces its functionality and therefore the scope.

Since the design of the sorbent filter selected for the prototype uses a layer of fibrous filter material such as FPP-70-0.3 with a sufficiently high resistance to air flow equal to 3 Pa at an air flow rate of 1 cm / s, modern technologies for filling a layer of fibrous filter material with a sorbent performed by blowing air through it with pulverized activated carbon, it is not possible to obtain a similar sorption filter with a surface density of the sorbent of more than 6-8 mg / cm2. This is due to the fact that, on the one hand, according to the law of filtration, sorbent particles are deposited on the fibers and are located in the fibrous layer of the filter material so that their concentration decreases exponentially with increasing depth of their penetration into the layer, and the steepness of this dependence increases with increasing airflow resistance. On the other hand, with the indicated resistance to the air flow of this filter material, the particles of the sorbent are fretted on the surface of the filter material, which is external to the surface of the filter material moving with the blowing of the dust-air mixture, which

prevents further filling it with a sorbent. This does not allow to obtain a sufficiently extended layer of sorbent in the volume of the filter material, limits the amount of introduced sorbent and therefore reduces the sorption capacity, and also limits the time of the protective action of the specified sorbent filter.

The disadvantages of the sorbent filter selected for the prototype are limited sorption capacity and time of protective action, as well as insufficiently wide functionality limited by the ability to protect only from organic gases and vapors.

The objectives of the proposed utility model are to increase the sorption capacity and time of the protective effect of the proposed sorbent filter for a light respirator, as well as expanding its functionality associated with the protection of the respiratory system, in addition, from inorganic gases.

The goals are achieved, according to the utility model, in that the proposed sorbent filter for a light respirator, containing, in accordance with the prototype, a layer of fibrous polymer filter material and filling it with powdered activated carbon as an sorbent of organic gases and vapors, differs from the prototype in that the layer of fibrous polymer filter material is made with an air flow resistance of from 0.1 to 2.8 Pa and is equipped with a powdery sorbent of inorganic gases filling it and vapors. At the same time, soda, citric acid or ion exchanger were used as the sorbent of inorganic gases and vapors.

The implementation of the layer of fibrous polymer filter material with an air flow resistance of from 0.1 to 2.8 Pa, that is, having a significantly lower value compared to the known filter, contributes to a deeper penetration of powdered sorbents into the layer of filter material, which allows to obtain a more extended thickness a layer of sorbents in the volume of the filter material and therefore increases the number of introduced sorbents. With the same technology of filling the layer of fiber-polymer filtering material

with powdered sorbents, this makes it possible to increase the surface density of sorbents to 9-16 mg / cm2 and, thereby, increase the sorption capacity and time of protective action under the same conditions up to 10-16 hours.

The supply of a layer of fibrous polymeric filter material filling it with a powdered sorbent of inorganic gases and vapors provides a significant expansion of the functionality of the proposed sorbent filter for a light respirator due to giving it the ability to protect respiratory organs not only from organic gases and vapors, provided by the presence of activated carbon as an sorbent, but also additionally from inorganic gases and vapors. So, for example, soda serves as a sorbent of acid gases, primarily hydrogen fluoride and hydrogen chloride. Citric acid is an effective sorbent of basic gases, primarily ammonia. Ionite can be used as a sorbent of ammonia and hydrogen sulfide.

sorbent filter for a light respirator of the listed distinguishing features.

In FIG. 1 shows the appearance of the proposed sorbent filter for a light respirator, where 1 is a fibrous polymer filter material and 2 is a sorbent.

In FIG. 2 shows a section through the filter element of a light respirator with the proposed sorbent filter, where 3 sorbent filter, 4 - the first anti-aerosol filter material, 5 - the second anti-aerosol filter material, 6 non-woven filter material and 7 - gauze (or non-woven material).

The proposed sorbent filter 3 for a light respirator contains a fibrous polymer filter material 1 (see Fig. 1), for example, in the form of a circle, 1-5 mm thick with an air flow resistance of 0.1-2.8 Pa, made, for example, from polypropylene, lavsan, polyester or perchlorovinyl, and filled with powdered sorbents of 2 organic and inorganic gases and vapors with a surface density of sorbents in the range of 9-16 mg / cm2.

The specified fibrous polymer filter material 1 can be obtained by one of the known methods, for example, in accordance with the patent of the Russian Federation No. 2060036, 1996, by passing a solution or melt of this polymer through a capillary in a strong electrostatic field and precipitating the resulting fiber with an air stream made in the form drum electrode. In this case, the choice of parameters that implements this method of installation and the conditions of the process provide fibrous polymer

filter material 1 of the required thickness and resistance to air flow of 0.1-2.8 Pa.

The fibrous polymer filter material 1 is cut into blanks, for example, in the form of a circle with a diameter of 180-200 mm (see Fig. 1). Then, the preform of the fibrous polymer filter material 1 is filled with powdery sorbents 2 until the surface density of the sorbents is in the range of 9-16 mg / cm2 in accordance with one of the known methods, for example, by passing through a preform a flow of a mixture of powdered sorbents with air, as provided by the method according to the patent of the Russian Federation No. 2053820, 1996. Moreover, the diameter of the spot spraying of the sorbents 2 on the workpiece may be 170-200 mm As a sorbent 2 organic gases and vapors use powdered activated carbon with a particle size of 3-5 microns. As a sorbent of 2 acid gases, primarily hydrogen fluoride and hydrogen chloride, powdered soda with a particle size of 5-8 μm is used. As ammonia sorbents 2, powdered citric acid or ion exchanger with a particle size of 3-5 microns is used, the latter being also used as a hydrogen sulfide sorbent. Sorbents 2 are sprayed alternately to obtain their distribution over the thickness of the fibrous polymer filter material 1 in layers, or simultaneously after preliminary mixing of the sorbents 2 in a powder state.

As part of the filtering elements of light respirators, the proposed sorbent filter 3 is used in conjunction with materials that filter aerosols and dust (see Fig. 2). In this case, the sorption filter 3 from the side facing

applying the respirator to the face of the user, they cover with a high-performance first anti-aerosol filter material 4, for example, type FP (Petryanov’s filter), including on a gauze substrate with the filter side facing the sorbent filter 3. The first anti-aerosol filter material 4 is covered with gauze 7 (or nonwoven material), which, when using a respirator, comes into contact with the user's face, being a hydrophilic material, absorbs moisture, acts as a hygienic layer and prevents allergic Exposure to the user to sorbents 2 and the filter material of the respirator. Outside in relation to the face of the user, the sorbent filter 3 is coated with a second anti-aerosol filter material 5, for example, of the FP type, including on a gauze substrate, with the filter side facing out. Outside with respect to the face of the user, the second aerosol filter material 5 is coated with a non-woven filter material 6, which performs the function of a coarse dust filter. A blank in the form of layers of filtering materials and a sorbent filter 3 is fastened in one of the known ways, for example, by making a thin needle and cotton thread (Petal (Light respirators) / Petryanov I.V. et al., Moscow: Nauka) , 1984, p. 77, Fig. 4.11, a) or by the method of thermal bonding, as this allows to perform a known installation for the manufacture of respirators according to the patent of the Russian Federation No. 2106161,1998.

Resistance to the air flow of the manufactured respirator does not exceed 60 Pa.

When using a lightweight respirator with the proposed sorbent filter 3, the user-inhaled air stream passes sequentially (see FIG. 2) through the non-woven filter material 6, which traps large particles of dust and aerosols, through the second anti-aerosol filter material 5, which traps dust and aerosols, through the proposed sorbent filter 3, which adsorbs organic gases and vapors with activated carbon and various inorganic gases and vapors with sorbent 2 inorganic gases and vapors (depending on as used therein sorbent inorganic gases and vapors), and retaining dust particles and aerosols, and then through the first particle filter material 4 that performs final filtration of aerosols, and finally through cheesecloth 7 (or nonwoven) is applied to the organs of the user breathing.

The effectiveness of the protective effect of the proposed sorbent filter in the composition of light sorption-filtering respirators is illustrated by the following examples.

Example 1

A sorbent filter in the form of a 1 mm thick layer of fibrous perchlorovinyl with an air flow resistance of 2.8 Pa, containing powdered activated carbon of the OAA grade with a particle size of about 3 μm and powdered soda ash with a particle size of about 5 μm and having a surface density of these sorbents, respectively 4 and 8 mg / cm2, in the filter element of a light respirator, for example, the Alin type, developed by the applicant, provides a protective action time of 10 hours with respect to hexachlorobutadiene and f hydrogen chloride at a coefficient

a slip of not more than 1% and their concentration in ambient air, respectively, 0.4 mg / m3 and 2.0 mg / m3.

Example 2

A sorbent filter in the form of a layer 3 mm thick of fibrous polypropylene with an air flow resistance of 0.7 Pa, containing powdered activated carbon of the OAA grade with a particle size of about 3 μm and powdered citric acid with a particle size of about 4 μm and having a surface density of these sorbents, respectively 5 and 8 mg / cm2, as part of the filter element of a light respirator, for example, of the Alin type, provides a protective action time of 12 hours with respect to hexachlorobutadiene and ammonia with a leakage coefficient not olee 1% and their concentration in the ambient air, respectively, 0.4 mg / m 3 and 100.0 mg / m3.

Example 3

A sorbing filter in the form of a layer of a thickness of 5 mm made of fibrous polyester with an air flow resistance of 0.3 Pa, containing powdered activated carbon of the OAA grade with a particle size of about 3 μm and a powdered ion exchanger of the KU-23 brand in copper form with a particle size of about 4 μm and having the surface density of these sorbents is 8 and 8 mg / cm2, respectively, as part of the filter element of a light respirator, for example, of the Alin type, provides a protective action time of 16 hours with respect to hexachlorobutadiene and ammonia at a coefficient of lope no more than 1% and their concentration in ambient air, respectively, 0.4 mg / m3 and 100.0 mg / m3.

sorbent filter for a light respirator, as well as the expansion of its functionality associated with the protection of the respiratory system, in addition, from inorganic gases.

USEFUL MODEL FORMULA

1. A sorbent filter for a light respirator containing a layer of fibrous polymer filter material and a powdered activated carbon filling it as a sorbent of organic gases and vapors, characterized in that the layer of fibrous polymer filter material is made with an air flow resistance from OD to 2.8 Pa and equipped with a powdery sorbent of inorganic gases and vapors filling it.

2. The filter according to claim 1, characterized in that soda is used as the sorbent of inorganic gases and vapors.

3. The filter according to claim 1, characterized in that citric acid is used as the sorbent of inorganic gases and vapors.

4. The filter according to claim 1, characterized in that an ion exchanger is used as a sorbent of inorganic gases and vapors.

SORBING FILTER FOR EASY RESPIRATOR

Claims (4)

1. The sorbent filter for a light respirator containing a layer of fibrous polymer filter material and filling it with powdered activated carbon as an sorbent of organic gases and vapors, characterized in that the layer of fibrous polymer filter material is made with an air flow resistance of from 0.1 to 2.8 Pa and is equipped with a powdery sorbent of inorganic gases and vapors filling it. 2. The filter according to claim 1, characterized in that soda is used as the sorbent of inorganic gases and vapors. 3. The filter according to claim 1, characterized in that citric acid is used as the sorbent of inorganic gases and vapors. 4. The filter according to claim 1, characterized in that an ion exchanger is used as the sorbent of inorganic gases and vapors.