FR2728476A1 - Active carbon particulate filling for respiratory filter - Google Patents

Abstract

A respiratory filter filling comprises (a) active carbon particles (I) impregnated with zinc sulphate or carbonate in amt. of 4-12, esp. 9%, expressed as wt. of Zn wrt. wt. of active carbon; and (b) active carbon particles (II) impregnated with copper oxide in amount 3-8, esp. 6% expressed as wt. of Cu wrt. wt. of active carbon, chromium oxide in amount 1-3 (pref. 2)% expressed as wt. of Cr wrt. wt. of active carbon, and opt. other impregnants (e.g. triethylene diamine and/or silver oxide). (where V = vol. (in cu.m.) of active carbon in the filter and D = air flow (in cu.m./sec.) across the filter). Also claimed is a filter contg. the above filling, pref. in the form of a layer of (I) upstream of a layer of (II) wrt. the direction of in taken air.

Description

 The invention relates to fillings for impregnated activated carbon grain filters for the protection of the respiratory tract.

It also targets filters with these fills.

 Filters are known for the protection of the respiratory tract intended for civilian use.

 These filters are standardized and their performance specifications are described in the European standard NF EN 141 of 4/91. There are four main categories of nitrates for civil use: - type A filters which protect against organic vapors.

- type B filters that protect against inorganic gases (HCN.

H2S or Cl2).

- Type E filters that protect against acid gases. in particular SO2 and - type K filters which protect against ammonia and some of its derivatives.

 Otherwise. filters for the protection of respiratory tracts intended for military use are known.

 These filters are designed to protect against combat gases.

especially against hydrocyanic acid. cyanogen chloride and organophosphorus gases.

 On the other hand, filters are not known to protect satisfactorily both against the industrial products of type A B E K and against the toxic military gases.

In order to produce such filters, one might think that it is sufficient to juxtapose an ABEK type filter intended for civilian use and a filter intended for military use. It is true that such a combination would make it possible to filter both products of the type
ABEK and military toxic gases, however the filters thus obtained would have a much too large volume to be used in a practical way. Furthermore. this volume would cause excessive pressure loss that would make breathing difficult for the user.

The invention aims to provide a filter for the protection of the respiratory tract. this filter ensuring the role of type filters
ABEK and that of military filters and yet with a small footprint.

 This is achieved, according to the invention, by filtering the inspired air with activated carbon grains (I) impregnated with a sulfate or a zinc carbonate with a degree of impregnation. expressed in mass of zinc relative to the mass of activated carbon, of between 4% and 12% and grains of activated carbon (II) impregnated with copper oxide with a degree of impregnation. expressed as a mass of copper relative to the mass of activated carbon, of between 3% and 8%. and chromium oxide with a degree of impregnation. expressed in mass of chromium relative to the mass of activated carbon, between 1% and 3% and, optionally other impregnations, the report mass between the grains of activated carbon (I) and the grains of activated carbon (II) being between 0.25 and 0.75 and the ratio V / D where V is the volume of activated carbon in the filter (in m3) and D. the air flow through the filter (in m3 per second) being greater than or equal to 0.3 seconds and less than or equal to 1 second.

 According to an advantageous embodiment of the filter filling according to the invention, the activated carbon grains (I) are impregnated with a sulphate or a zinc carbonate with a degree of impregnation, expressed as mass of zinc relative to the mass. activated carbon, between 8 and 10% and preferably close to 9%.

 According to another advantageous embodiment of the filter filling according to the invention, the activated carbon grains (II) are impregnated with copper oxide with a degree of impregnation, expressed as a mass of copper relative to the mass of the coal. active, between 5 and 7% preferably close to 6%.

 Among the possible impregnations of activated carbon grains (II). mention will be made of an impregnation with triethylenediamine, with a degree of impregnation. expressed as a mass of triethylene diamine relative to the mass of activated carbon, of between 1 and 3% and preferably close to 2% and / or a silver impregnation in the form of oxide with a degree of impregnation. expressed in silver mass relative to the mass of active carbon between 0.05 and 0.15% preferably close to 0.1%.

 According to yet another advantageous embodiment of the filter filling according to the invention, the activated carbon grains (II) are impregnated with chromium oxide with a degree of impregnation expressed as a mass of chromium relative to the mass of the coal. active, close to 2%.

 The filter filling according to the invention may consist of at least one layer of activated carbon grains (I) and at least one layer of activated carbon grains (II), or a mixture of these grains.

 Preferably, the activated carbon grains have a particle size of between 8 and 30 mesh, and more preferably between 12 and 20 mesh.

 The filter fill may be introduced into a cartridge or other medium to form a nitre. Figure 1 shows. by way of illustration given solely by way of example, a block diagram of a filter. In this figure. the filter filling is constituted by a layer of activated carbon (I) and an active carbon layer (II) introduced between a metal grid (1) and a synthetic material grid (2).

 The invention is suitable for all filters comprising an active carbon-based filler.

 According to an advantageous embodiment of the filter according to the invention, it comprises a filling consisting of a layer of activated carbon grains (I) and a layer of activated carbon grains (II). the layer (I) being located upstream of the layer (II) with respect to the direction of inspired air.

 The invention can be better understood with the aid of the following nonlimiting example and which constitutes an advantageous embodiment of the filter according to the invention.

EXAMPLE
A filter filling according to the invention is carried out consisting of a layer of activated carbon grains (I) and a layer of activated carbon grains (II).

 The layer of activated carbon grains (I) consists of 100 g. activated carbon impregnated with zinc sulphate. with a degree of impregnation of 9%, expressed in mass of zinc relative to the mass of activated carbon.

 The layer of activated carbon grains (11) is constituted by 150 g. of activated carbon impregnated with the following substances: - copper oxide, with an impregnation rate of 6%, expressed as a mass of copper relative to the mass of the activated carbon, - chromium oxide, with a degree of impregnation of 2 %, expressed as a mass of chromium relative to the mass of activated carbon, - silver oxide, with a degree of impregnation of 0.1%, expressed as a mass of silver relative to the mass of activated carbon, triethylene diamine, with an impregnation rate of 2%, expressed as a mass of triethylene diamine relative to the active charcoal layer.

 The mass ratio between the activated carbon grain layer (I) and the active carbon grain layer (II) is 0.66; the activated carbon grains have a particle size of 12 × 20 mesh.

 A filter according to the invention comprising this filling is produced.

This nitre is used with a gas flow rate of 30 1 / min (standards
NF EN 141 filters for gas masks), which corresponds to a V / D ratio of 0.8 seconds.

The following tables 1 and 2 show the performance of this filter:
Table 1: EFFICIENCY TO GAS FOLLOWING STANDARD EN 141
Duration of effectiveness (minutes)

<tb> Toxic <SEP> Concentration <SEP> Requirements <SEP> of <SEP> Values
<tb><SEP> upstream <SEP> the <SEP> standard <SEP> obtained <SEP> min.
<Tb>

CCI4 <SEP> 0.5% <SEP> 40 <SEP>#<SEP> 70 <SEP>
<tb> H2S <SEP> 0.5% <SEP> 40 <SEP>><SEP>#<SEP> 150 <SEP>
<tb> HCN <SEP> 0.5 <SEP>% <SEP> 25 <SEP>#<SEP> 40 <SEP>
<tb> C12 <SEP> 0.5 <SEP>% <SEP> 20 <SEP>#<SEP><SEP> 50
<tb> SO2 <SEP> 0.5 <SEP>% <SEP> 20 <SEP>#<SEP> 30 <SEP>
<tb> 3 <SEP>
<tb><SEP> 0.5% <SEP> 40 <SEP>#<SEP> 45 <SEP>
<Tb>
Table 2: EFFECTIVENESS TO MILITARY TOXICS
Duration Co. Efficiency (minutes)

Toxic <SEP> Concentration <SEP> Requirements <SEP> of <SEP><SEP> Values
<tb><SEP> upstream <SEP> standard <SEP> obtained <SEP> min.
<Tb>

HCN <SEP> 2g / m3 <SEP> 60 <SEP>#<SEP> 200 <SEP>
<tb> CNCl <SEP> 2 <SEP> g <SEP> / <SEP> m3 <SEP> 60 <SEP>#<SEP> 200 <SEP>
<tb> Chloropicrin <SEP> 5 <SEP> g <SEP> / <SEP> m3 <SEP> 25 <SEP>#<SEP> 200
<Tb>
It is observed that the filter according to the invention meets, for all gases, the requirements of standard NF EN 141 and that its duration of effectiveness is significantly higher for all gases, than that required by this standard.

Claims (11)

1. Filling for filter for respiratory protection. comprising impregnated activated carbon grains, characterized in that it comprises grains of activated carbon (I) impregnated with a sulphate or a zinc carbonate with a degree of impregnation, expressed as a mass of zinc with respect to the mass of activated carbon, between 4% and 12% and activated carbon (II) grains impregnated with copper oxide with a degree of impregnation. expressed as a mass of copper relative to the mass of activated carbon, of between 3% and 8%, and of chromium oxide with a degree of impregnation, expressed as a mass of chromium relative to the mass of activated carbon, included between 1% and 3% and possibly other impregnations. the mass ratio between the active carbon grains (I) and the activated carbon grains (II) being between 0.25 and 0.75 and the VID ratio where V is the volume of activated carbon in the filter (in m3 and D. the airflow through the filter (in m3 per second) being greater than or equal to 0.3 seconds and less than or equal to 1 second. 2. Filling filter according to claim 1, characterized in that the grains of activated carbon (I) are impregnated with a sulfate or a zinc carbonate with a degree of impregnation. expressed in mass of zinc relative to the mass of activated carbon, of between 8 and 10 6 and preferably close to 9%. 3. Filling for filter according to any one of the preceding claims. characterized in that the grains of activated carbon (II) are impregnated with copper oxide with a degree of impregnation. expressed in mass of copper relative to the mass of activated carbon, of between 5 and 7% and preferably close to 6%. 4. Filling for filter according to any one of the preceding claims. characterized in that the other impregnations of the activated carbon grains (II) are an impregnation with triethylenediamine with a degree of impregnation. expressed as a mass of triethylene diamine relative to the mass of activated carbon, of between 1 and 3% and preferably close to 2% and / or a silver impregnation in the form of oxide with a degree of impregnation. expressed in silver mass relative to the mass of activated carbon, between 0.05 and 0.15% and preferably close to 0.1%. 5. Filling for filter according to any one of the preceding claims, characterized in that the activated carbon grains (11) are impregnated with chromium oxide with a degree of impregnation, expressed as mass of chromium relative to the mass. activated carbon close to 2%. 6. Filling filter according to any one of the preceding claims, characterized in that it consists of at least one layer of activated carbon grains (I) and at least one layer of activated carbon grains (II). 7. Filling filter according to any one of the preceding claims, characterized in that it consists of a mixture of activated carbon grains (I) and grains of activated carbon (II). 8. Filling filter according to any one of the preceding claims, characterized in that the grains of activated carbon have a particle size of between 8 and 30 mesh and preferably. between 12 and 20 mesh. Filter filling according to one of the preceding claims. characterized in that it comprises a layer of activated carbon grains (I) impregnated with zinc sulphate with a degree of impregnation of between 8 and 10% and preferably of 9%, expressed by mass of zinc relative to the mass of activated carbon, and a layer of activated carbon grains (II) impregnated with copper oxide with a degree of impregnation of between 5 and 7% and preferably 6%, expressed as mass of copper relative to the mass of activated carbon, and of chromium oxide with an impregnation rate of between 1 and 3% and preferably 2%, expressed as chromium mass relative to the mass of activated carbon, of silver oxide with a degree of impregnation of between 0.05 and 0.15% and preferably of 0.1%, expressed as a mass of silver relative to the mass of activated carbon, and of triethylenediamine with a degree of impregnation between 1 and 3% and preferably 2%, expressed as mass of triethylene diamine relative to the mass activated carbon, the mass ratio between the activated carbon grains (I) and the activated carbon grains (II) being 0.66 and the VI D ratio being 0.8 seconds, the particle size of the active carbon grains being 12 x 20 mesh. 10. Filter comprising a filling for filter, characterized in that this filling is one of those determined by any one of the preceding claims. 11. Filter according to claim 10, characterized in that the filling consists of a layer of activated carbon grains (I) and a layer of activated carbon grains (II). the layer (I) being located upstream of the layer (II) relative to the direction of the inspired air.