RU2129453C1 - Gas mask filter - Google Patents

Abstract

FIELD: cleaning air in working zone from vapors of toxic agents. SUBSTANCE: gas mask filter has cylindrical housing with threaded neck for connecting the filter to mask, two-layer charge including layers of desiccant and hopcalite located in succession in way of flow of air, filtering material layer located between layer of hopcalite and threaded neck, bottom with inner threaded neck and charge fastenings. Ratio of length of hopcalite layer to length of desiccant layer ranges from 0.8 to 1.1. EFFECT: improved quality of cleaning air; increased service life; enhanced reliability. 3 dwg

Description

 The invention relates to the field of production of means for air purification, in particular, to gas mask technology, and can be used to clean the air of the working area from vapors of harmful substances.

 Known gas filter containing a cylindrical housing with a threaded neck for attaching the filter to the mask, a two-layer charge part, charge fastening elements, the bottom with the inlet (see US Pat. Germany N 3507486, class A 62 B 23/02, 02.01.87 g .).

 The disadvantages of the known gas filter is that the two-layer charge part is made of hopcalite and a Pt-group catalyst, which, firstly, drastically narrows the use of the filter, because Pt group catalysts are poisoned even with insignificant concentrations of sulfur compounds and nitrogen oxides, and therefore it is preferable to purify the air from these catalysts only from carbon monoxide; secondly, it reduces the time of effective work of the gas filter even for carbon monoxide in conditions of high humidity; and thirdly, the use of Pt group catalysts as part of the filter mixture dramatically increases the cost of gas filters.

 The closest to the proposed technical essence and the achieved result is a gas filter containing a cylindrical body with a threaded neck for attaching the filter to the mask, a two-layer charge part consisting of a desiccant and a catalyst, a layer of filter material, charge fastening elements, the bottom with an inlet ( see Pat. Germany N 2316278, class A 62 B 19/00, 07/13/78).

 The disadvantage of this device is that the non-standard ratio between the lengths of the layers of the desiccant and the catalyst significantly limits the possibility of its use in air purification of the working area, because the gas filter is designed to purify air only from carbon monoxide. A layer of filter material is located in front of the desiccant layer and allows air purification only from aerosols coming from the surrounding atmosphere to the filter.

 At the same time, the lack of effective cleaning of highly toxic catalyst dust blown out during operation of the filter significantly reduces the operating time of the gas filter, and the absence of a threaded neck at the bottom does not allow the attachment of additional devices that expand its field of application, for example, filter-absorbing boxes of various brands to provide universal protection in extreme situations.

 The aim of the invention is to improve the quality of air purification, increase the service life, giving the gas filter universal protective properties and increase the reliability in its operation.

 This goal is achieved by the fact that in the gas mask filter containing a cylindrical body with a threaded neck for attaching the filter to the mask, a two-layer charge part, consisting of layers of desiccant and catalyst arranged in series along the air flow, a layer of filter material, fastening elements of the charge, the bottom with the inlet, the catalyst is made in the form of hopcalite, while the length of the hopcalite layer refers to the length of the desiccant layer as 1: 0.8-1.1, the layer of filter material is located between the hopka layer litas and a threaded neck, and the bottom is made with an internal threaded neck.

 The difference between the proposed device and the known one is that the catalyst is made in the form of hopcalite, while the length of the hopcalite layer refers to the bottom of the desiccant layer as 1: 0.8: 1.1, the layer of filter material is located between the hopcalite layer and the threaded neck, and the bottom is made with an internal threaded neck.

 The use of a desiccant and hopcalite in the stated proportions in combination with the introduction of an additional layer of high-performance filter material and the execution of the bottom with an internal threaded neck from the scientific and technical literature is unknown to the authors.

 The use of these signs in the proposed device allows to achieve high quality air purification, the versatility of respiratory protection in extreme situations from a wide range of SDYAW, ensures the safety of the gas mask due to the complete elimination of leakage of toxic manganese compounds and makes it possible, without removing the gas mask, to attach, if necessary Accessories: e.g. high performance aerosol filters or filter-absorbing boxes of different grades, and thereby increase the reliability of protection in emergency situations, which becomes possible due to the fact that the catalyst is made in the form of hopcalite, while the length of the hopcalite layer refers to the length of the desiccant layer as 1: 0.8: 1.1, the layer of filtering material is located between the hopcalite layer and the threaded neck, and the bottom is made with an internal threaded neck.

 The invention is illustrated by drawings.

 In FIG. 1 shows a General view of the gas filter.

 The proposed gas filter includes a cylindrical housing 1 with a threaded neck 2 for attaching the filter to the mask; the two-layer charge part, consisting of a desiccant 3 and hopcalite 4, is fixed in the housing 1 using fasteners - the upper 5 mesh and the lower 6 mesh. A layer of high-performance filter material 7 is fixed to the upper 5 mesh from the threaded neck 2. To the bottom of the cylindrical the housing 1 is sealed to the bottom 8 with an internal threaded neck 9.

 Gas filter works as follows.

 Using the threaded neck 2, the gas mask is attached to the mask either through a corrugated tube or directly to the inspiration assembly. When inhaling contaminants, air through a hole in the internal threaded neck 9 of the bottom 8 enters the gas filter.

 Passing successively through a layer of desiccant 3 and hopcalite 4, fixed in a cylindrical housing 1 using a mesh of the upper 5 and mesh of the lower 6, as well as through a layer of filtering material 7, the air is cleaned and through the neck 2 enters the mask under the mask and is used for breathing.

 To improve the quality of air purification and ensure the universality of respiratory protection in extreme situations from a wide range of NDE, the layers of desiccant and hopcalite successively arranged along the air flow are made so that the length of the hopcalite layer refers to the length of the desiccant layer as 1: 0.8-1, 1.

 The results of experiments substantiating the feasibility of ejecting the ratios between the lengths of the hopcalite and desiccant layers are shown in the figures of FIG. 2 (a, b, c).

 In FIG. Figure 2 (a) shows the experimental results showing the dependence of the protective action time θ of the gas mask filter on carbon monoxide on the ratio between the lengths of the hopcalite and desiccant layers.

 The dashed line shows the requirements of GOST for filtering means of protection against carbon monoxide.

Test conditions: C _o = 6.2 mg / l; C _k = 0.02 mg / l; V = 30 l / min; t ^o = 25 ± 5 ^o C; φ = 90 ± 3%, hereinafter the following notation is used:
C _o - initial concentration of harmful impurities, mg / l;
C _k - concentration at the exit, mg / l;
V is the volumetric flow rate of the gas-air mixture, l / min;
t ^o - temperature, ^o C;
φ is the relative humidity,%.

 As follows from the experimental results, with the indicated ratios between the lengths of the hopcalite and desiccant layers, reliable protection against carbon monoxide is provided.

 In FIG. Figure 2 (b) shows the experimental results showing the dependence of the protective action time θ of the gas filter on ammonia on the ratio between the lengths of the hopcalite and desiccant layers. The dotted line shows the recommended amount of protective action time for devices of this type.

Test conditions: C _o = 5 mg / l; C _k = 0.02 mg / l; V = 30 l / min .; t ^o = 25 ± 5 ^o C; φ = 50%, the notation is the same as in the previous example.

As follows from the experimental results, when the ratio of the lengths of the desiccant and hopcalite layers l _o / l _g > 1.1, the protective time of the gas filter for ammonia decreases below the maximum permissible values, due to the decrease in the length of the hopcalite layer necessary for the catalytic decomposition of ammonia.

 In FIG. Figure 2 (c) shows the dependence of the time of the protective action θ of the gas mask filter on carbon tetrachloride vapor on the ratio between the lengths of the hopcalite and desiccant layers. The dashed line shows the recommended value of the protective action for carbon tetrachloride recommended by the European standard En143.

Test conditions: C _o = 32 mg / l; C _k = 0.66 mg / L; φ = 50% t ^o = 20 ± 5 ^o ; V = 30 l / min, the designations are the same as in the previous examples.

The experimental results show that when the ratio of the desiccant and hopcalite layer lengths l _o / l _g <0.8, the protective action time of the gas mask filter on carbon tetrachloride decreases below the maximum permissible values, due to the decrease in the length of the desiccant layer, which is activated carbon with added additives halide salts of alkali and alkaline earth metals, and which is both an effective absorber of organic vapor.

 Thus, as follows from the experimental results, the optimal from the point of view of ensuring the universality of protection is the ratio of the length of the hopcalite layer to the length of the desiccant layer as 1: 0.8-1.1.

 To ensure highly efficient cleaning of highly toxic (PDK-0.0003 mg / L) dust blown out during operation of the filter, manganese compounds, which are one of the components of hopcalite, an additional layer of filter material is placed between the layer of hopcalite and the threaded neck.

 In FIG. 3 shows the results of comparative tests for blowing dust of manganese compounds from the prototype and the proposed gas filter.

 Placing an additional layer of filtering materials (for example, FPP, FPKS, RMPK, RFM) allows you to ensure the safe operation of the filter throughout the entire resource for SDYAV.

 The execution of the bottom with an internal threaded neck allows, without removing the gas mask, to attach additional devices to the gas filter that expand its field of application, for example, highly efficient anti-aerosol filters or filtering and absorbing boxes of various brands and thereby increase the reliability of protection in emergency situations.

 The proposed gas filter due to the fact that the catalyst is made in the form of hopcalite, while the length of the hopcalite layer refers to the length of the desiccant layer as 1: 0.8: 1.1, the layer of filter material is located between the hopcalite layer and the threaded neck, and the bottom is made with an internal threaded neck, it allows to achieve high quality air purification, to provide universality of respiratory protection in extreme situations from a wide range of SDYA, ensures safety of use due to the complete exclusion of t manganese oxide compounds and makes it possible, without removing the gas mask, to attach, if necessary, additional devices and thereby increase the reliability of protection in emergency situations.

Claims (1)

 Gas filter containing a cylindrical housing with a threaded neck for attaching the filter to the mask, a two-layer charge part, consisting of layers of desiccant and catalyst arranged in series along the air flow, a layer of filter material, fastening elements of the charge, the bottom with an inlet, characterized in that the catalyst is made in the form of hopcalite, while the length of the hopcalite layer refers to the length of the desiccant layer as 1: 0.8 - 1.1, the layer of filter material is located between the hopcalite layer and the threaded g neck, and the bottom is made with an internal threaded neck.

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