EP1677636A1 - Breathable protective glove with abc protection - Google Patents

Abstract

A breathable protective glove (1) is disclosed, having a protective function against chemical toxins, in particular, chemical weapons, with a multi-layer composite construction (2), comprising, in particular, a planar support layer (3) and a barrier layer (4), provided on the support layer (3), facing the hand in the wearing position, which hinders the passage of chemical toxins, or at least delays the same, which includes an adsorption layer (5), made from an adsorption material which absorbs chemical toxins, in particular, made from activated charcoal. The barrier layer (4) comprises an at least essentially water- and air-tight membrane (6), in addition to the adsorption layer (5), which permits the passage of water vapour and which retards the passage of chemical toxins, or which is essentially impermeable to chemical toxins and said membrane (6) is arranged between the support layer (3) and the adsorption layer (5). The protective glove (1) is comfortable to wear and has good tactile properties whilst also showing excellent protection against chemical toxins.

Description

 Breathable protective glove with ABC protection

The present invention relates to a breathable protective glove with a protective function against chemical poisons, in particular chemical warfare agents, according to the preamble of claim 1, in particular for military use or for ABC use.

There are a number of substances that are absorbed by the skin and cause serious physical damage. Examples include the blistering mustard (yellow cross) and the nerve poison sarin. People who can come into contact with such poisons must wear suitable protective equipment or be protected against these poisons by suitable protective materials.

Appropriate protective suits are available to protect the body, particularly the extremities and trunk. In order to protect the head, in particular the face, and the respiratory tract, gas masks (ABC protective masks) are generally worn, possibly together with a hood.

Furthermore, care must also be taken to ensure that the hands are also adequately protected against such poisons, in particular by wearing protective gloves. In particular, such a protective glove must be suitable for military or ABC use.

For this purpose, according to the state of the art, airtight and waterproof rubber gloves, in particular based on butyl rubber, are used for military or ABC use, which are impervious to chemical poisons, in particular chemical warfare agents. The disadvantage of these protective gloves is the lack of breathability and consequently only low wearing comfort, which is a hindrance, especially for longer uses.

US 6 301 715 B1, which goes back to the applicant itself, and WO 01/82728 AI and DE 201 21 518 Ul, which belong to the same patent family, describe a glove for pilots with increased tactility and protection against chemical poisons, which consists of a breathable outer material such as B. leather or a textile material, and can be equipped with an activated carbon-based adsorption layer for the adsorption of chemical warfare agents. Because of the activated carbon-based adsorption layer, this glove offers an excellent protective function against chemical poisons, in particular warfare agents, but the wearing time of this glove is limited in military or ABC use due to the limited adsorption capacity of the activated carbon. Furthermore, this glove cannot easily be decontaminated or regenerated.

It is therefore the object of the present invention to provide a protective glove, in particular a breathable protective glove, with a protective function against chemical poisons, in particular chemical warfare agents, which is particularly suitable for military or ABC use and the disadvantages of the prior art described above Technology at least partially avoided.

A further object of the present invention is to further develop the glove described in US Pat. No. 6,301,715 B1 and in the two aforementioned parallel patent applications WO 01/82728 AI and DE 201 21 518 Ul.

To solve the problem described above, the present invention proposes a protective glove, in particular a breathable protective glove (eg military protective glove or NBC protective glove) according to claim 1. Further advantageous embodiments of the protective glove according to the invention are the subject of the subordinate and additional claims.

The basic idea of the present invention is to provide a breathable protective glove with a multi-layer structure with an in particular flat outer layer on the outside and a barrier layer assigned to the layer that prevents or at least retards the passage of chemical toxins, which comprises an adsorption layer based on a chemical adsorbing adsorbent material (e.g. based on activated carbon), thereby with an increased or improved protective function against chemical poisons, in particular chemical warfare agents, to equip the barrier layer in addition to the adsorption layer with an at least substantially water and air impermeable, but water vapor permeable, retarding the passage of chemical poisons or at least substantially impermeable to chemical poisons, which membrane is arranged between the carrier layer and the adsorption layer.

The aforementioned membrane, which is arranged between the support layer and the adsorption layer, has the effect that chemical poisons, such as, for example, penetrated through the outside support layer. B. chemical warfare agents, do not reach the adsorption layer or at least for the most part do not even reach it, so that the adsorption capacity of the adsorption layer remains virtually inexhaustible. By equipping the protective glove according to the invention with a special breathable membrane which delays the passage of chemical poisons or is at least essentially impermeable to chemical poisons, good decontamination and regenerability of the protective glove according to the invention is achieved at the same time.

Further advantages, properties, aspects and features of the present invention result from the following description of a preferred exemplary embodiment shown in the drawings. It shows:

1 shows a schematic illustration of a breathable protective glove according to a preferred exemplary embodiment of the invention; 2A shows a schematic sectional illustration through the layer structure of a breathable protective glove according to a preferred exemplary embodiment of the invention in accordance with an embodiment in which the adsorption layer is attached to the membrane by means of discontinuous adhesive application; 2B is a schematic sectional view through the layer structure of a breathable protective glove according to a preferred embodiment of the invention according to an alternative embodiment, in which the adsorption layer is attached to the membrane by means of continuous adhesive application.

1 shows a breathable protective glove 1 according to the invention with a protective function against chemical poisons, in particular against chemical warfare agents. The protective glove 1 according to the invention has a multilayered layer structure 2 with an in particular flat, outside carrier layer 3 and an inside layer (ie facing the hand when the hand is in the wearer position), which prevents or at least retards the passage of chemical poisons, which has a Adsorption layer 5 based on a chemical adsorbing adsorbent material, in particular based on activated carbon. In addition to the adsorption layer 5, the barrier layer 4 has an at least substantially water and air impermeable, but water vapor permeable (ie breathable) membrane which delays the passage of chemical poisons or is at least substantially impermeable to chemical poisons, which membrane 6 is located between the carrier layer 3 and the adsorption layer 5 is arranged. According to the invention, the barrier layer 4 thus comprises both an adsorption layer 5 and a membrane 6 with the aforementioned properties. The combination of adsorption layer 5 on the one hand and membrane 6 on the other hand, in accordance with the layer structure 2 according to the invention, ensures efficient protection against chemical poisons, in particular chemical warfare agents, while at the same time being very comfortable to wear, in particular breathability.

As can be seen from FIGS. 1 and 2A and 2B, the arrangement according to the invention of the membrane 6 between the carrier layer 3 and the adsorption layer 5 ensures that poisons which have penetrated through the outer carrier layer 3 of the protective glove 1 are already retained by the membrane 6 and consequently not reach the adsorption layer 5 at all or at most in extremely small quantities; In this way, on the one hand, the adsorption capacity of the adsorption layer is almost never exhausted, and on the other hand, the presence of the membrane 6 provides additional protection for the wearer of the protective glove 1, so that a protective glove 1 with a double protective function against chemical poisons results (namely on the one hand by the blocking effect of Membrane 6 and on the other hand by the adsorption effect of the adsorption layer 5). The presence of the special membrane 6 also ensures that the protective glove 1 can be decontaminated and regenerated; because poisons which may have penetrated through the outer layer 3 can be removed again from the membrane 6 by appropriate treatment methods (for example by flushing them down), for example using suitable decontamination solutions which are well known to the person skilled in the art for these purposes.

As can be seen from FIGS. 1 and 2A and 2B, the membrane 6 or the barrier layer 4 is connected directly or indirectly to the carrier layer 3 on its side facing away from the hand when it is worn. In contrast, the side of the membrane 6 facing the hand or facing away from the carrier layer 3 (that is to say the inside) is acted upon by the adsorption layer 5; in general, the adsorption layer 5 is attached to the membrane 6 by means of adhesive 7. As FIGS. 2A and 2B show, the adhesive application 7 can in principle be carried out discontinuously (FIG. 2A) or continuously or over the entire surface (FIG. 2B). 2A, however, is preferred, since this increases the wearing comfort of the protective glove 1 according to the invention, in particular prevents additional rigidity of the membrane 6, as can be the case in the case of a full-surface or continuous application of adhesive. Nevertheless, it is fundamentally possible to provide a full-surface or continuous application of adhesive 7 for the purpose of fastening the adsorption layer 5 to the membrane 6; in this case, however, care should be taken to ensure that the adhesive 7 has breathable properties, in particular is permeable to water vapor, in order to ensure the necessary wearing comfort. Furthermore, it can be provided that an additional, preferably flat carrier layer 8 is arranged between the membrane 6 and the carrier layer 3. In this embodiment, the membrane 6 is only indirectly connected to the carrier layer 3, specifically via the additional carrier layer 8. The additional carrier layer 8 serves in particular to stabilize and / or support the membrane 6, both when processing the membrane 6, in particular when applied with adhesive 7 and the Adsoφ- tion layer 5, as well as in use or when wearing the protective glove 1. The additional backing layer 8, the particular wear resistance, such. B. the tensile strength, the membrane 6 can be increased. For this purpose, the membrane 6 can be laminated or laminated onto the additional carrier layer, in particular by means of an adhesive (not shown in the drawings), which is advantageously applied in a punctiform manner, because this prevents excessive rigidity of the membrane 6 and in this way the Comfort is increased. The additional carrier layer 8, which is arranged between the membrane 6 and the outer carrier layer 3, can then be connected to the carrier layer 3, usually by means of an adhesive which is preferably applied discontinuously, in particular in a punctiform manner. Suitable materials for the additional carrier layer 8 are, for example, textile materials, in particular textile fabrics, such as. B. fabrics, knitted fabrics, knitted fabrics, scrims or textile composites (z. B. nonwovens), which are preferably air-permeable. The additional carrier layer 8 advantageously has a lower basis weight than the carrier layer 3. In general, the basis weight of the additional carrier layer 8 is less than 60 g / m ² , in particular less than 50 g / m, preferably less than 40 g / m; this contributes to increased wearing comfort, because in this way the flexibility of the layer structure 2 as a whole is essentially not impaired and good wearing comfort is achieved.

As described above, the membrane 6 has an adsorption layer 5 applied to it on the inside (ie on the side facing the hand in the wearing state). The adsorption layer 5, in turn, can be provided with a cover layer 9 on its side facing the hand in the wearing state, that is to say, the membrane 6, which is advantageously attached to the adsorption layer 5; For attaching the cover layer 9 to the adsorption layer 5, for example, adhesives are suitable, which are preferably applied discontinuously, in particular in a punctiform manner, to the cover layer 9 for this purpose, or so-called hot-melt adhesive fabrics (“hot-melt adhesive webs”), which lie between the cover layer 9 and the adsorption layer 5 to be ordered. Air-permeable textile materials, in particular textile fabrics, such as woven fabrics, knitted fabrics, knitted fabrics, scrims or textile composites (e.g. nonwovens, especially polyamide / polyester fleece or PA / PES fleece). The cover material 9 is advantageously designed to be abrasion-resistant or consists of an abrasion-resistant textile material. The covering material 9 advantageously has a weight per unit area of 5 to 150 g / m, in particular 10 to 125 g / m, preferably 40 to 100 g / m. The presence of the covering material or the covering layer 9 has the particular advantage that direct contact of the skin or the hand with the adsorption layer 5 is avoided when the protective glove 1 is worn; this causes on the one hand that the Adsoφtionsschicht 5 is not contaminated by skin perspiration, and on the other hand a higher wearing comfort is achieved because the cover layer 9 takes on the function of a textile inner glove within the scope of the layer structure 2 according to the invention, which causes a comfortable fit. On the other hand, the cover layer 9 prevents excessive mechanical stress on the adsorption material of the adsorption layer.

As described above, the membrane 6 can be connected to the outside (i.e. on the side facing away from the hand when it is worn), depending on the configuration of the layer structure 2 according to the invention, either with the backing layer 3 or with the additional backing layer 8, for example glued. Advantageously, the adhesive is only discontinuous, in particular punctiform, in particular in the form of a punctiform grid or pattern, the adhesive only at most 30%, in particular only at most 25%, preferably only at most 20%, particularly preferably only at most 10% of those in the wearing state of the Side of the membrane 6 facing away from the hand.

On the inside (ie on the side facing the hand when it is in the worn state), the adsorption layer 5 is applied to the membrane 6, in particular by means of an adhesive 7; The application of the adhesive 7, as previously described, advantageously takes place discontinuously, in particular only in a punctiform manner, usually in the form of a punctiform grid, with at least 50%, in particular at least 60%, preferably at least 70%, particularly preferably at least, in order to achieve a high adsorption performance 75%, very particularly preferably at least 80%, of the side of the membrane 6 which faces the hand when it is in the wearing state, that is to say which faces away from the carrier layer 3, is covered or acted upon by the adsorption material of the adsorption layer 5 can be; the adhesive application 7 is accordingly to be provided over these surface areas of the membrane 6. In the event that a sheet (fabric, knitted fabric, scrim, fleece, etc.) made of activated carbon fibers is used as the adsorption material of the adsorption layer 5, the side of the membrane 6 which is turned towards the hand, that is to say away from the carrier layer 3, can be completely, ie closed, when the hand is in the worn state 100%, be covered or acted upon with the adsorption material of the adsorption layer 5; the activated carbon fiber structure can, for example, be fixed to the membrane 6 by only punctiform adhesive application.

In general, the individual layers 3, 4, 5, 6, 8 and 9 of the layer structure 2 are each connected to one another; this is done using methods known per se for these purposes (e.g. by gluing, welding, sewing, stapling, etc.). Advantageously, the connection or fixing of the individual layers 3, 4, 5, 6, 8 and 9 of the layer structure 2 takes place seamlessly with one another, preferably without damaging the individual layers 3, 4, 5, 6, 8 and 9 (e.g. by gluing, welding, etc.). In the event that layers 3, 4, 5, 6, 8 and 9 are - at least partially - sewn or the like, it is advisable to seal the seams (e.g. with a so-called seam sealing tape). In particular, the individual layers 3, 4, 5, 6, 8 and 9 of the layer structure 2 form a coherent composite.

The individual layers 3, 4, 5, 6, 8 and 9 or the layer structure 2 can or can extend over the entire hand including the wrist and part of the lower forearm (FIG. 1). According to this embodiment, the individual layers 3, 4, 5, 6, 8 and 9 or the layer structure 2 form a coherent glove in the form of a hand with five fingers and a shaft which extends over the knuckle of the hand.

The protective glove 1 is advantageously designed as a finger glove, ie it has the shape of a hand with five fingers; This not only increases comfort, but also makes it easier to use for military or ABC purposes. The fact that the glove 1 according to the invention advantageously extends over the knuckle (ie has a glove shaft) enables a sealing connection with a an ABC protective suit worn at the same time; For this purpose, the glove and / or the ABC protective suit can be equipped with appropriate sealing elements (e.g. zippers, Velcro elements, sealing lips, etc.) in order to seal or seal the transition from protective glove 1 and ABC protective suit to one another connect.

In particular, the individual layers 3, 4, 8 and 9 each form the shape of a glove with five fingers: the cover layer 9 forms an inner glove, so to speak, while the carrier layer 3 forms an outer glove, so to speak. The barrier layer 4 with the inside adsorption layer 5 and outside membrane 6 forms together with the additional carrier layer 8 a core glove located between the inner glove and the outer glove, all three glove parts - outer, inner and core glove - being connected to one another and together the protective glove according to the invention 1 form.

With regard to the material of the backing layer 3, which generally forms the outer layer of the protective glove 1, any, in particular breathable, materials can be used here, such as are generally used for gloves. Examples of this are textile materials, preferably air-permeable textile materials, in particular in the form of textile fabrics, such as. B. fabrics, knitted fabrics, knitted fabrics, scrims or textile composites. For example, the textile composite can be a nonwoven. Alternatively, the carrier layer 3 can also be formed as a leather material. It is advantageous to seamlessly form the outer glove or the backing layer 3 in the area of the fingertips. For further details in this regard, reference can be made to the aforementioned documents US 6 301 715 B1 or WO 01/82728 AI and DE 201 21 518 U1, the respective disclosure content of which is hereby fully incorporated by reference.

In order to prevent or make it more difficult for chemical poisons (for example concentrated drops of warfare agents) to penetrate, it is advisable to oleophobicize and / or hydrophobize the material of the outer carrier layer 3, in particular by means of a special impregnation. The material of the backing layer 3 or of the outer glove generally has a weight per unit area of 50 to 300 g / m ² , in particular 75 to 250 g / m, preferably 75 to 175 g / m. In particular, the backing layer 3 is designed as an air-permeable, 75 to 250 g / m ² , preferably 75 to 175 g / m ² heavy textile fabric which can be made oleophobic and / or hydrophobic.

As far as the membrane 6 is concerned, this is generally a continuous, in particular closed or at most microporous membrane. The thickness of the membrane 6 is generally 1 to 500 μm, in particular 1 to 250 μm, preferably 1 to 100 μm, preferably 1 to 50 μm, particularly preferably from 2.5 to 30 μm, very particularly preferably 5 to 25 μm. To increase the wearing comfort, in particular the breathability, the membrane 6 has a high water vapor permeability of at least 12.5 1 / m per 24 h, in particular at least 17.5 1 / m ² per 24, at 25 ° C. and with a thickness of 50 μm h, preferably at least 20 l / m ² per 24 h or more, to (measured according to the "inverted cup method" or "inverted cup method" according to ASTM E 96 and at 25 ° C.) (For further details on measuring the Water vapor transmission [WVT] see also McCullough et al. "A comparison of standard methods for measuring water vapor permeability of fabrics" in Meas. Sci. Technol. [Measurements Science and Technology] 14, 1402-1408, August 2003). This ensures a particularly high level of comfort. Due to the large number of layers 3, 4, 5, 6, 8 and 9 of the layer structure 2, the water vapor permeability of the protective glove 1 overall is slightly lower than that of the membrane 6 alone; the water vapor permeability of the protective glove 1 overall is nevertheless very high and is at least 10 1 / m ² per 24 h, in particular at least 15 1 / m ² per 24 h, preferably at least 20 1 / m ² per 24 h, with a thickness of the membrane 6 of 50 μm (at 25 ° C).

For reasons of breathability, the membrane 6 should have a low water vapor resistance R _et under stationary conditions - measured according to DIN EN 31 092: 1993 from February 1994 ("Textiles - Physiological effects, measurement of the heat and water vapor resistance under stationary conditions [sweating guarded-hotplate test] ") or according to the same international standard ISO 11 092 - at 35 ° C of at most 30 (m • Pascal) / watt, in particular at most 25 (m • Pascal) / watt, preferably at most 20 (m ² • Pascal) / watt, with one Have thickness of the membrane 6 of 50 microns. Due to the large number of layers 3, 4, 5, 6, 8 and 9 of the layer structure 2, the water vapor resistance R _{et of} the protective glove 1 as a whole is slightly higher compared to the membrane 6 alone; In general, the water vapor resistance R _{et of} the glove 1 is a total of at most 30 (m • Pascal) / watt, in particular at most 25 (m • Pascal) / watt, preferably at most 20 (m • Pascal) / watt, with a thickness the membrane 6 of 50 microns.

The membrane 6 should otherwise be only slightly water-absorbent or swellable; a slight water absorption or swelling capacity increases comfort. In particular, the swellability or the water absorption capacity of the membrane 6 should be at most 35%, in particular at most 25%, preferably at most 20%, based on the weight of the membrane 6. In addition, the membrane 6 should be at least essentially impermeable to liquids, in particular water, and / or aerosols, or at least delay their passage. In order to achieve a slight swellability, the membrane 6 should have no or essentially no strongly hydrophilic groups, in particular no hydroxyl groups. For the purpose of slight swelling, however, the membrane 6 can have weakly hydrophilic groups, for example polyether groups.

The membrane 6 can consist of or comprise a plastic or a polymer material. Such a plastic or such a polymer can suitably z. B. be selected from the group of polyurethanes, polyether amides, polyester amides, polytetrafluoroethylene and / or cellulose-based polymers and derivatives of the aforementioned compounds. For example, the membrane 6 can be obtained as a reaction product from the reaction of an isocyanate, in particular a masked or blocked isocyanate, with an isocyanate-reactive crosslinker. For example, the membrane 6 can be a polyurethane-based membrane. Likewise, the membrane 6 can also be an expanded, optionally microporous membrane based on polytetrafluoroethylene. According to a special embodiment, the membrane 6 which may be present can be designed as a multilayer membrane laminate or as a multilayer membrane composite. This membrane laminate or membrane composite can consist of at least two, preferably at least three interconnected membrane layers or layers. For example, this membrane laminate or membrane composite can comprise a core layer based on a cellulose-based polymer and two outer layers connected to the core layer, in particular based on a polyurethane, a polyether amide and / or a polyester amide. The core layer can be based on a cellulose-based polymer as a 1 to 100 μm, in particular 5 to 50 μm, preferably 10 to 20 μm thick membrane and the two outer layers connected to the core layer can each be 1 to 100 μm, in particular 5 to 50 microns, preferably 5 to 10 microns thick membrane. This particular embodiment of the membrane 6 makes it possible to combine different membrane materials with different properties, in particular different water vapor permeability and / or barrier effects against chemical poisons, and thus to optimize the properties of the membrane 6. For example, cellulose and cellulose derivatives are excellent barrier materials, especially against chemical pollutants or toxins, such as. B. warfare agents (lost etc.), and are not attacked or dissolved by these poisons; on the other hand, polyurethane-based materials prevent migration or diffusion of the plasticizers that may be present in the cellulose layer and also dampen the crackling caused by the cellulose when it is worn. It is therefore preferred according to this particular embodiment that in the case of a membrane laminate or composite, the core layer is formed on the basis of a cellulose-based polymer, while the two outer layers of the membrane 6 are formed by polyurethane layers.

As described above, the membrane 6 can be increased in particular in order to increase the stability or wear resistance, in particular the tensile strength, of the membrane 6 in the manufacturing process (for example when printing the membrane 6 with hot adhesive 7) as well as when wearing it on an additional Carrier layer 8 applied or laminated. In this regard, reference can be made to the above statements.

To increase wearing comfort on the one hand and to achieve good wear resistance on the other hand, it is advantageous if the membrane 6 has a certain elasticity. In particular, it is advantageous if the membrane 6 can be stretched or stretched at least 10%, in particular at least 20%, preferably at least 30% or more, in at least one direction (based on the membrane 6). The layer structure 2 as a whole should also have a certain elasticity for the aforementioned purposes, in addition to good flexibility; compared to the membrane 6, however, the elasticity of the layer structure 2 as a whole is somewhat lower, and in general the layer structure 2 is at least 5%, preferably at least 10%, very particularly preferably at least 15% or more, at least in total stretchable or stretchable in one direction.

According to a special embodiment, not shown in the figures, the membrane 6 can simultaneously represent the adhesive layer 7 for fastening the adsorption layer 5. In this case, the membrane 6 must be self-adhesive, in particular heat-adhesive. According to this particular embodiment, there is a saving in weight since an additional adhesive layer 7 can be dispensed with entirely.

The construction or conception of the protective glove 1 according to the invention is generally carried out in such a way that the membrane 6 of the protective glove 1 consists of two pieces of material which are connected to one another, preferably sealingly connected to one another, in particular glued and / or welded to one another. Both pieces of material each have the shape of a hand with five fingers, one of the two pieces of material for covering the front of the hand (inside of the hand) and the other piece of material for covering the back of the hand (back of the hand) and the two pieces of material only along their respective outer ends Contours, in particular along the outline of the hand, are connected to one another, preferably connected to one another in a sealing manner, in particular glued and / or welded to one another. As far as the adsorption layer 5 of the protective glove 1 according to the invention is concerned, it is generally discontinuous, ie the adsorption layer 5 generally comprises discrete adsorption particles (e.g. based on activated carbon) which adsorb chemical poisons, for example by means of an adhesive 7 on the Membrane 6 can be fixed. The adsorption material of the adsorption layer 5 is in particular an adsorption material containing or consisting of activated carbon, for example a material based on activated carbon in the form of activated carbon particles and / or activated carbon fibers.

Because if activated carbon-containing materials are used as the adsorption material for the formation of the adsorption layer 5, the already existing high level of wearing comfort can be increased even further, because the activated carbon serves as an intermediate moisture or water reservoir (e.g. for sweat) and moisture or Can "buffer" water, so to speak. When using, for example, activated carbon beads as Adsoφtionsmaterial for the Adsoφtionsschicht 5 conditions of up to about 250 g / m ² or more are common, so that, for. B. in the event of a sweat, about 40 g / m ^{2 of} moisture can be stored, which in the case of a breathable carrier or outer layer 3 can then be released to the environment again.

According to an embodiment of the present invention, the adsorption layer 5 comprises discrete activated carbon particles, preferably in the form of granules ("granular carbon") or ("spherical carbon"). In this case, the average diameter of the activated carbon particles is less than 1.0 mm, in particular less than 0.5 mm, preferably less than 0.4 mm, preferably less than 0.35 mm; however, the average diameter of the activated carbon particles is at least 0.1 mm. In this embodiment, the activated carbon particles are generally present in an amount of 5 to 500 g / m ² , preferably 20 to 300 g / m ² , preferably 25 to 250 g / m ² , particularly preferably 50 to 120 g / m ² Membrane 6 applied. Suitable activated carbon particles have inner surfaces (BET) of at least 800 m ² / g, in particular of at least 900 m ² / g, preferably of at least 1,000 m ² / g, preferably in the range from 800 to 1,500 m ² / g. Granular coal, especially spherical coal, has the decisive advantage that it is extremely abrasion-resistant and very hard, which in relation on the wear properties is of great importance. Preferably, the bursting pressure for a single activated carbon particle, in particular activated carbon granules or spheres, is generally at least about 5 newtons, in particular at least about 10 newtons, and can reach up to about 20 newtons.

According to an alternative embodiment, the adsorption layer 5 can comprise activated carbon fibers, in particular in the form of activated carbon fiber surfaces, as the adsorption material. Such activated carbon fiber fabrics can have, for example, a basis weight of 20 to 200 g / m ² , in particular 30 to 150 g / m ² , preferably 15 to 120 g / m ² . These activated carbon fiber fabrics can be, for example, activated carbon fiber fabrics, knitted fabrics, scrims or composite materials (eg based on carbonized and activated cellulose and / or carbonized and activated acrylonitriles).

Likewise, it is also possible to combine 5 activated carbon particles and activated carbon fibers with one another as the adsorption material of the adsorption layer. Activated carbon particles have the advantage of a higher adsorption capacity, while activated carbon fibers have better adsorption kinetics.

To increase the adsorption efficiency or adsorption performance, there is also the possibility of impregnating the adsorption material of the adsorption layer 5, in particular the activated carbon particles and / or the activated carbon fibers, with at least one catalyst. Suitable catalysts according to the invention are, for example, enzymes and / or metal ions, preferably copper, silver, cadmium, platinum, palladium, zinc and / or mercury ions. The amount of catalyst can vary within wide limits; in general it is 0.05 to 12% by weight, preferably 1 to 10% by weight, particularly preferably 2 to 8% by weight, based on the weight of the adsorption layer 5.

For an efficient adsorption performance, it is preferred if at least 50%, in particular at least 60%, preferably at least 70%, of the adsorption layer 5 or the adsorption material of the adsorption layer 5 are freely accessible for the poisons or warfare agents to be adsorbed, ie not with adhesive 7 are covered. This happens because the crowd and the type, in particular the viscosity, of the adhesive 7 are designed such that the adsorption material of the adsorption layer 5 is not completely pressed or sunk into the adhesive 7.

A typical protective glove 1 according to the present invention can consist, for example, of the following layers: The carrier layer 3 (“outer glove”) can consist, for example, of a robust and possibly flame-retardant type of fiber, preferably in a seamless circular knitted form. The cover layer 9 (“inner glove”) can consist of materials that are comfortable to wear on the skin (Co, Rayon, PA, PES, m-aramid), optionally in a flame-resistant version, preferably in a seamless, circular-knitted version. The barrier layer 4, which is arranged between the inner glove and the outer glove, can contain activated carbon balls and / or fibers in addition to the membrane 6 to form the adsorption layer 5 for the purposes of the adsorption of the pollutants.

The protective glove 1 according to the invention offers efficient protection against chemical poisons, in particular chemical warfare agents, while at the same time being extremely comfortable, in particular having good breathability. The decisive advantage of the protective glove 1 according to the present invention is that the protective function against chemical poisons is integrated into the protective glove 1 itself and that no additional equipment is required. This not only saves considerable weight and increases comfort, it also opens up the possibility of an efficient sealing connection of the transition to an ABC protective suit, so that chemical poisons, e.g. B. warfare agents, the transition from protective gloves / protective suit can not or not easily pass. On the basis of these properties, the protective glove 1 according to the invention is particularly suitable for military or ABC use (for example in the form of a military protective glove or ABC protective glove). As a result of the high efficiency of the protective function of the adsorption layer 5, which is increased by the use of the membrane 6 according to the invention, it is also possible to use breathable outer glove materials, e.g. B. leather or textiles, so that the wearing comfort can be increased in this way without the wearer of the protective glove 1 being exposed to an increased risk from the use of a breathable outer glove material.

Due to the high flexibility or good flexibility of the individual layers 3, 4, 5, 6, 8 and 9 or the layer structure 2 overall, not only is good wearing comfort achieved, but also good wear resistance of the protective glove 1 according to the invention at the same time good tactility.

The inventive design of the protective glove 1 according to the present invention achieves an excellent barrier effect against chemical warfare agents. The barrier effect of the protective glove 1 or the membrane 6 against chemical warfare agents, in particular bis- [2-chloroethyl] sulfide (also known synonymously as mustard gas, mustard or yellow cross), measured according to CRDEC-SP-84010, method 2.2, is at most 4 μg / cm per 24 h, in particular at most 3.5 μg / cm per 24 h, preferably at most 3.0 μg / cm ² per 24 h, particularly preferably at most 2.5 μg / cm per 24 h, with a thickness of Membrane 6 of 50 microns.

The protective glove 1 according to the invention can be produced in a manner known per se. This is well known to those skilled in the manufacture of gloves.

For example, the manufacture of a glove according to the invention can be carried out as follows: an approximately 50 to 100 μm thick membrane 6 is laminated or laminated onto a carrier layer 8, which serves to reinforce and stabilize the membrane, by means of a punctiform adhesive. Subsequently, the membrane 6, which can be a polyurethane membrane, for example, is printed on the side facing away from the carrier layer 8 with a water vapor-permeable adhesive 7 in the form of a dot-shaped grid, on which the activated carbon beads 7 then form while the adhesive is still adhesive Adsoφtionsschicht 5 are applied. Then the adhesive 7 is optionally dried and / or cured. Then two pieces of material of the material thus obtained are in the form of a hand cut out with five fingers and glued or welded along the contours of the hand - each with the membranes 6 to the inside - so that a barrier layer 4 according to the invention results in the form of a membrane glove loaded with activated carbon. The inside of the adsorption layer 5 is covered with a covering material 9 in the form of an inner glove, for example by gluing with a hot-melt adhesive web; This can be done, for example, by putting the inner glove over a metal mandrel in the shape of a hand with five fingers, then z. B. is applied with the hot-melt adhesive web and then the membrane glove previously made is put on. The base layer 8 is then connected on the outside to a backing layer 3 in the form of an outer glove (e.g. by means of the technique described above), so that ultimately a protective glove 1 according to the invention with a covering layer 9 as inner glove, an outer backing layer 3 as outer glove and one between the inner and outer gloves arranged barrier layer 4 of adsorption layer 5 and membrane 6, which together with the additional stabilizing layer 8 for membrane 6 forms a core or middle glove, so to speak, the individual layers 3, 4 and 9 being connected to one another are.

According to a typical embodiment, a three-layer protective glove 1 according to the present invention can be composed as follows: 1. The backing layer 3 (“outer glove”) can consist, for example, of a robust and possibly flame-retardant type of fiber, preferably in a seamless circular knitted form. 2. The cover layer 9 ("inner glove") can consist of materials that are comfortable to wear on the skin (Co, Rayon, PA, PES, m-aramid), optionally in a flame-resistant version, preferably in a seamless, circular knitted version. 3. The barrier layer 4 (“functional layer”), which is arranged between the inner and outer gloves, can contain activated carbon balls and / or fibers in addition to the membrane 6 to form the adsorption layer 5 for the purpose of adsorbing the pollutants, and in different alternative configurations, as described below: a) Activated activated carbon spheres are applied to a breathable membrane layer 6 (e.g. made of PU, PES, PA, PTFE, cellulose, etc.). The layer can be produced and the beads applied by dipping or by customary coating and coating processes. If a coated film is produced as an intermediate step, it is brought into a two-dimensional or three-dimensional hand shape by suitable methods (e.g. gluing, sewing, welding, etc.). The functional layer can be reinforced in the coating or also on the side opposite the activated carbon beads by means of a mesh or knitted fabric made of thermoplastic fibers. b) The functional layer consists of a glove-shaped knitted fabric made of activated carbon fibers, produced by carbonizing a corresponding glove made of rayon or polyacrylonitrile fibers and subsequent activation or knitted from the activated carbon fibers produced in the corresponding way. c) Instead of the carbon spheres or in addition to them, activated carbon flock fibers can also be applied to the breathable membrane layer according to a) by conventional flocking techniques. d) The carbon balls and / or fibers are applied to a seamless or sewn inner glove according to 2.). e) A seamless or welded membrane glove (e.g. loose or adhesive) can be placed over the functional layers according to b) or d) as a liquid barrier.

The individual layers mentioned above (inner glove, functional layer and outer glove) are - according to the structure - put together and z. B. connected by a seam. In addition, if necessary, the layers can also be fixed on the upper sides of the fingers and on the back of the hand by means of adhesives (such as, for example, by hot melt adhesive, for example with thermal activation of the adhesive), double-sided adhesive tape strips or Velcro fasteners or the like. Further refinements, modifications and variations of the present invention are readily recognizable and realizable for the person skilled in the art on reading the description, without thereby leaving the scope of the present invention.

Claims

claims:

1. Breathable protective glove (1) with a protective function against chemical poisons, in particular chemical warfare agents, with a multilayered layer structure (2), which has an in particular flat backing layer (3) and one that is assigned to the backing layer (3) and faces the hand when it is worn Passage of chemical poisons preventing or at least delaying barrier layer (4), which comprises an adsorption layer (5) based on an adsorption material adsorbing chemical poisons, in particular based on activated carbon, characterized in that - the barrier layer (4) in addition to the adsorption layer ( 5) has an at least essentially water and air impermeable but water vapor permeable membrane which delays the passage of chemical poisons or is at least substantially impermeable to chemical poisons and - that the membrane (6) between the carrier layer (3) and the adsorption layer ( 5) arranged is.

2. Protective glove according to Anspmch 1, characterized in that the membrane (6) is directly or indirectly connected to the carrier layer (3) on its side facing away from the hand when it is worn and / or in that the membrane (6) is in its worn state the hand facing, the side facing away from the carrier layer (3) is acted upon by the adsorption layer (5), in particular wherein the adsorption layer (5) can be attached to the membrane (6) by means of adhesive (7).

3. Protective glove according to one or more of the preceding claims, characterized in that an additional, preferably flat carrier layer (8) is arranged between the membrane (6) and the carrier layer (3), in particular wherein the additional carrier layer (8) for Stabilizing and / or supporting the membrane (6) and / or in particular wherein the additional carrier layer (8) is a preferably air-permeable textile material, in particular a textile fabric, such as a woven fabric, knitted fabric, knitted fabric, scrim or textile. tilverbundstoff, is formed and / or in particular wherein the additional carrier layer (8) has a lower basis weight than the carrier layer (3) and / or in particular wherein the additional carrier layer (8) has a basis weight of less than 60 g / m ² , in particular 9 9 of less than 50 g / m, preferably less than 40 g / m, and / or in particular wherein the membrane (6) is laminated or laminated onto the additional carrier layer (8), in particular by means of an adhesive, preferably applied in a punctiform manner, and / or in particular wherein the additional backing layer (8) is connected to the backing layer (3), in particular by means of an adhesive which is preferably applied in a punctiform manner.

4. Protective glove according to one or more of the preceding claims, characterized in that a covering layer (9) is applied to the side of the adsorption layer (5) facing away from the membrane (6) when the hand is in the wearing state, in particular wherein the covering layer (9) is attached to the adsorption layer (5), in particular by means of an adhesive which is preferably applied discontinuously, preferably punctiformly, to the cover layer (9), or by means of a hot-melt adhesive fabric ("hot-melt adhesive web"), and / or in particular wherein the cover layer (9) a preferably air-permeable textile material, in particular a textile fabric, preferably a woven fabric, knitted fabric, knitted fabric, scrim or textile composite, such as a nonwoven, in particular a polyamide / polyester nonwoven (PA / PES nonwoven), and / or in particular wherein the Cover layer (9) is designed to be abrasion-resistant and in particular consists of an abrasion-resistant textile material and / or in particular in particular wherein the cover layer (9) 9 9 has a weight per unit area of 5 to 150 g / m, in particular 10 to 125 g / m, preferably 40 to 100 g / m ² .

5. Protective glove according to one or more of the preceding claims, characterized in that the membrane (6) with the backing layer (3) or with the additional backing layer (8) is glued, in particular wherein the gluing is only punctiform, in particular in the form of a punctiform grid, takes place, in particular wherein the adhesive only at most 30%, in particular only at most 25%, preferably only at most 20%, particularly preferably only at most 10% of the side of the membrane (6) facing away from the hand when worn, and / or that adsorption layer (5) is applied to the membrane (6) by means of an adhesive (7), in particular where the gluing is only punctiform, in particular in the form of a punctiform grid, and / or in particular wherein at least 50%, in particular at least 60%, preferably at least 70%, particularly preferably at least 75%, very particularly preferably at least 80% of those facing the hand when it is worn , the support layer (3) facing away from the membrane (6) with the adsorption material of the adsorption layer (5) is applied.

6. Protective glove according to one or more of the preceding claims, characterized in that the individual layers (3, 4, 5, 6, 8, 9) of the layer structure (2) are each connected to one another and / or that the individual layers (3, 4, 5, 6, 8, 9) of the layer structure (2) form a composite.

7. Protective glove according to one or more of the preceding claims, characterized in that the protective glove (1) is designed as a finger glove and / or that the protective glove (1) has the shape of a hand with five fingers.

8. Protective glove according to one or more of the preceding claims, characterized in that the carrier layer (3) is designed as a textile material, preferably an air-permeable textile material, in particular a flat textile structure, in particular where the textile material is a woven, knitted fabric, Knitted fabrics, scrims or textile composites can be, in particular wherein the textile composite can be a nonwoven, and / or that the carrier layer (3) is designed as a leather material.

9. Protective glove according to one or more of the preceding claims, characterized in that the backing layer (3) is oleophobic and / or hydrophobized, in particular by special impregnation, and / or that the material of the backing layer (3) has a weight per unit area of 50 to 300 g / m ² , in particular 75 to 250 g / m ² , preferably se 75 to 175 g / m ² , and or that the carrier layer (3) as an air-permeable, 75 to 250 g / m ² , preferably 75 to 175 g / m ² heavy textile fabric, which are equipped with oleophobic and / or hydrophobic can, is trained.

10. Protective glove according to one or more of the preceding claims, characterized in that the membrane (6) is a continuous, in particular closed or at most microporous membrane and / or that the thickness of the membrane (6) 1 to 500 microns, in particular 1 to 250 μm, preferably 1 to 100 μm, preferably 1 to 50 μm, particularly preferably from 2.5 to 30 μm, very particularly preferably from 5 to 25 μm, and or that the membrane (6) at 25 ° C. and with a thickness of 50 μm has a water vapor permeability of at least 12.5 1 / m ² per 24 h, in particular at least 17.5 1 / m ² per 24 h, preferably at least 20 1 / m ² per 24 h or more, and / or that the protective glove (1) at 25 ° C. and with a thickness of the membrane (6) of 50 μm has a water vapor permeability of at least 9 10 1 / m per 24 h, in particular at least 15 1 / m per 24 h, preferably at least 20 1 / m per 24 h.

11. Protective glove according to one or more of the preceding claims, characterized in that the membrane (6) has a water vapor resistance R _et under stationary conditions, measured according to DIN EN 31 092: 1993 (February 1994) and international standard ISO 11 092, at 35 ° C of at most 25 (m ² • Pascal) / watt, in particular at most 20 (m • Pascal) / watt, preferably at most 13 (m • Pascal) / watt, with a thickness of 50 μm and / or that the protective glove (1) has a water vapor resistance R _et under stationary conditions, measured according to DIN EN 31 092: 1993 (Febmar 1994) and international standard ISO 11 092, at 35 ° C of at most 30 (m ² • Pascal) / Watt, in particular at most 25 (m ² • Pascal) / watt, preferably at most 20 (m • Pascal) / watt, with a thickness of the membrane (6) of 50 μm.

12. Protective glove according to one or more of the preceding claims, characterized in that the membrane (6) is at most only slightly swellable and / or water-absorbent, in particular wherein the swellability and / or the water absorption capacity of the membrane (6) is at most 35%, in particular at most 25%, preferably at most 20%, based on the weight of the membrane (6), and / or that the membrane (6) with respect to liquids, in particular water, and or is at least essentially impermeable to aerosols or at least delays their passage.

13. Protective glove according to one or more of the preceding claims, characterized in that the membrane (6) has no or essentially no strongly hydrophilic groups, in particular no hydroxyl groups, and / or that the membrane (6) has weakly hydrophilic groups, in particular polyether groups, having.

14. Protective glove according to one or more of the preceding claims, characterized in that the membrane (6) comprises and / or consists of a plastic and / or a polymer, in particular wherein the plastic and or the polymer consists of the group of polyurethanes, Polyether amides, polyester amides, polytetrafluoroethylenes and / or polymers based on cellulose and / or derivatives of the aforementioned compounds can be selected.

15. Protective glove according to one or more of the preceding claims, characterized in that the membrane (6) is obtained as a reaction product from the reaction of an isocyanate, in particular a masked or blocked isocyanate, with an isocyanate-reactive crosslinker.

16. Protective glove according to one or more of the preceding claims, characterized in that the membrane (6) is a polyurethane-based membrane and / or that the membrane (6) is an expanded, optionally microporous membrane based on polytetrafluoroethylene.

17. Protective glove according to one or more of the preceding claims, characterized in that the membrane (6) is designed as a multilayer membrane laminate and / or as a multilayer membrane composite, in particular wherein the membrane laminate and / or the membrane composite consists of at least two, preferably at least three interconnected layers or layers.

18. Protective glove according to Anspmch 17, characterized in that the membrane laminate or the membrane composite comprises, in particular, a core layer based on a cellulose-based polymer and two outer layers bonded to the core layer, in particular based on a polyurethane, a polyether amide and / or a polyester amide wherein the core layer based on a polymer based on cellulose can be formed as a 1 to 100 μm, in particular 5 to 50 μm, preferably 10 to 20 μm thick membrane and / or in particular wherein the two outer layers connected to the core layer each as 1 to 100 μm, in particular 5 to 50 μm, preferably 5 to 10 μm thick membrane can be formed.

19. Protective glove according to Anspmch 17, characterized in that the membrane laminate or the membrane composite comprises a core layer based on a polymer based on a polyurethane and two outer layers connected to the core layer based on a polyurethane.

20. Protective glove according to one or more of the preceding claims, characterized in that the membrane (6) consists of two interconnected, preferably sealingly interconnected, in particular glued and / or welded pieces of material, in particular wherein the two pieces of material each have the shape of a hand with five fingers, whereby one of the two pieces of material is intended to cover a front of the hand (inside of the hand) and the other piece of material is intended to cover a back of the hand (back of the hand) and the two pieces of material are connected to one another only along their respective outer contours, in particular along the outline of the hand, preferably are sealed together, in particular glued and / or welded together.

21. Protective glove according to one or more of the preceding claims, characterized in that the membrane (6) is self-adhesive, in particular heat-adhesive, and / or that the membrane (6) also serves as an adhesive layer (7) for attaching the adsorption layer (5).

22. Protective glove according to one or more of the preceding claims, characterized in that the adsorption layer (5) is discontinuous and / or in that the adsorption layer (5) comprises discrete adsorption particles, particularly those based on activated carbon, which adsorb chemical poisons and / or that the adsorption material of the adsorption layer (5) is an adsorbent material containing or consisting of activated carbon and / or that the adsorption material of the adsorption layer (5) is a material based on activated carbon, in particular in the form of activated carbon particles and / or activated carbon fibers.

23. Protective glove according to one or more of the preceding claims, characterized in that the adsorption layer (5) comprises discrete activated carbon particles, preferably in the form of granules ("granular carbon") or spherical shape ("spherical carbon"), in particular wherein the average diameter of the activated carbon particles is <1 .0 mm, in particular <0.5 mm, preferably <0.4 mm, preferably <0.35 mm, particularly preferably <0.3 mm, and / or the average diameter of the activated carbon particles is at least 0.1 mm and / or in particular wherein the activated carbon particles in an amount of 5 to 500 g / m, in particular 10 to 9 9 9 400 g / m, preferably 20 to 300 g / m, preferably 25 to 250 g / m, particularly preferably 50 to 150 g / m, very particularly preferably 50 to 120 g / m, are applied to the membrane (6) and / or in particular where the activated carbon particles have an inner surface area (BET) of at least 9 9 at least 800 m / g, in particular of at least 900 m / g, preferably at least 1,000 m ² / g, preferably in the range from 800 to 1,500 m ² / g, and / or in particular where the activated carbon particles have a bursting pressure per individual activated carbon particle, in particular activated carbon granules or spheres, of at least 5 newtons, in particular at least 10 newtons, and / or from to to have 20 Newtons.

24. Protective glove according to one or more of the preceding claims, characterized in that the adsorption layer (5) activated carbon fibers, in particular in the form of an activated carbon sheet, um- summarizes, in particular wherein the activated carbon sheet has a weight of 20 to 200 g / m, in particular 30 to 150 g / m, preferably 50 to 120 g / m, and / or in particular wherein the activated carbon sheet has an activated carbon fabric, Knitted fabric, scrim or composite, in particular based on carbonized and activated cellulose and / or a carbonized and activated acrylonitrile.

25. Protective glove according to one or more of the preceding claims, characterized in that the adsorption layer (5) is also impregnated with at least one catalyst, in particular with enzymes and / or metal ions, preferably copper, silver, cadmium, as catalyst, Platinum, palladium, zinc and / or mercury ions are used and / or the amount of catalyst 0.05 to 12% by weight, preferably 1 to 10% by weight, particularly preferably 2 to 8% by weight , based on the weight of the adsorption layer (5).

26. Protective glove according to one or more of the preceding claims, characterized in that the adsorption layer (5) is freely accessible to at least 50%, in particular to at least 60%, preferably to at least 70%, for the poisons and warfare agents to be adsorbed.

27. Protective glove according to one or more of the preceding claims, characterized in that the protective glove (1) and / or the membrane (6) has a barrier effect against chemical warfare agents, in particular bis [2-chloroethyl] sulfide (mustard gas, mustard, yellow cross), measured according to CRDEC-SP-84010, method 2.2, of at most 9 9 4 μg / cm per 24 h, in particular at most 3.5 μg / cm per 24 h, preferably at most 3.0 μg / cm ² per 24 h, particularly preferred has a maximum of 2.5 μg / cm ² per 24 h, with a thickness of the membrane (6) of 50 μm.

28. Breathable protective glove (1) with a protective function against chemical poisons, in particular chemical warfare agents, with a multilayered layer structure (2), which has an especially flat backing layer (3) and one that is assigned to the backing layer (3) and faces the hand when it is worn Prevents chemical poisons from demde or at least delaying barrier layer (4), which has at least one adsorption layer (5) based on a chemical adsorbing adsorption material, in particular based on activated carbon, and at least one arranged between the carrier layer (3) and the adsorption layer (5) comprises essentially water and air impermeable but water vapor permeable, retarding the passage of chemical poisons or at least substantially impermeable to chemical poisons, the protective glove (1) and / or the membrane (6) having a barrier effect against chemical warfare agents , in particular bis [2-chloroethyl] sulfide, of at most 4 μg / cm per 24 h with a thickness of the membrane (6) of 50 μm.

29. Breathable protective glove (1) with a protective function against chemical poisons, in particular chemical warfare agents, with a multilayered layer structure (2), which has an in particular flat backing layer (3) and one which is assigned to the backing layer (3) and faces the hand when it is worn The passage of chemical poisons to prevent or at least delay the barrier layer (4), which has an adsorption layer (5) based on an adsorption material that adsorbs chemical poisons, in particular based on activated carbon, and an interposed layer between the carrier layer (3) and the adsorption layer (5). at least substantially water and air impermeable, but water vapor permeable, retarding the passage of chemical poisons or at least substantially impermeable to chemical poisons, the protective glove (1) at 25 ° C and with a thickness of the membrane (6) of 50 μm a water vapor permeability of at least 10 1 / m per 24 h.

30. Breathable protective glove (1) with a protective function against chemical poisons, in particular chemical warfare agents, with a multilayered layer structure (2), comprising a particularly flat backing layer (3) and one that is assigned to the backing layer (3) and faces the chemical when the hand is worn Poison-preventing or at least delaying barrier layer (4), which has an adsorption layer (5) based on an adsorption material that adsorbs chemical toxins, in particular on the basis of activated carbon, and an intermediate layer the carrier layer (3) and the adsorption layer (5) arranged, at least substantially water and air impermeable, but water vapor permeable, retarding the passage of chemical poisons or at least substantially impermeable to chemical poisons, the protective glove (1) comprising one Water vapor resistance R _et under stationary conditions at 35 ° C of at most 30 (m ² • Pascal) / watt with a thickness of the membrane (6) of 50 μm.