KR20140088045A - Face mask and method of its production - Google Patents

Abstract

The present invention relates to a face mask for removing biological and mechanical impurities from breathed and / or husked air, the face mask comprising an inner fiber layer and an outer fiber layer, wherein the inner fiber layer and the outer fiber layer contain a structurally sterilizing material An active layer of polymer nanofibers and / or a filtration layer of polymer nanofibers. Wherein the outer fiber layer and the inner fiber layer are formed of microfibers, and at least the outer fiber layer and the filter layer or the active layer of the polymer nanofibers adjacent to the outer fiber layer are hydrophobic, Are mutually interconnected by a net of joints that prevent movement and reduce the permeability of the face mask to a minimum. The inner fiber layer has a layer of adhesive for fixing to the face of the user around the face mask 1. This method of securing the face mask to the face ensures that the face mask is fully adhered to the skin along its entire circumference, preventing unfiltered air from bouncing. The present invention also relates to a method of manufacturing such a face mask.

Description

≪ Desc / Clms Page number 1 > BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a face mask,

The present invention relates to a face mask for removing biological and mechanical impurities from air that is inhaled and / or inhaled or exhaled, wherein the face mask comprises an inner fibrous layer and an outer fibrous layer, An active layer of nanofibers and / or a filtration layer of polymer nanofibers.

The present invention also relates to a method of manufacturing such a face mask.

A large number of patent documents disclose various variations of face masks designed for the removal of biological and / or mechanical impurities from the air that drinks / drinks / exhales containing at least one nanofiber layer.

The face mask disclosed in CN2640523 belongs to the simplest variants of such face masks because it comprises one filtering layer of nanofibers arranged between two fabrics. The face mask described in CN 2650790 is similar in its structure, but a layer of nanofibers is disposed between two layers of nonwoven. These face masks are all mechanical, possibly also biological impurities, especially microorganisms (bacteria, viruses, etc.), which are larger in size than the interfiber spaces in the layer of nanofibers. Smaller mechanical impurities and microorganisms penetrate the face mask.

CZ UV 16988 discloses a variant of a face mask that requires too much in manufacturing and technology. In this face mask, an active layer of nanofibers containing particles of an antimicrobial additive is disposed between two layers of a nonwoven fabric, which is composed of microorganisms caught by a layer of nanofibers and an active layer of nanofibers due to their small size It is also partially active in microorganisms passing through. The microorganisms passing through the face mask are killed or at least weakened by the action of the antimicrobial additive so that their undesirable effects after intake are completely or at least partially removed.

The face mask described in CZ297697 achieves the highest efficiency. The mask includes all of the filtration layers of the nanofibers, together with the active layer of nanofibers of the particles of the antimicrobial additive disposed between the two fibrous layers. The filtration layer of nanofibers catches biological and mechanical impurities, and the active layer of nanofibers kills or at least weakens microorganisms that are caught or pass through. The combination of the two layers of nanofibers substantially simultaneously increases the filtration efficiency of the face mask and thus catches impurities that can pass through the face mask with one layer of nanofibers. However, these face masks are the most complex and costly in terms of their production and technology.

All of the face masks known so far show a number of significant drawbacks that substantially reduce their efficiency and utility value, thus reducing the likelihood of users to use them. The most substantial drawback is the unfavorable manner of securing the face mask to the user's face, which is usually guided around the user's head or ear by a fabric with two or four stripes. In this fixed manner, in the user's arbitrary action, the separation of the face masks occurs in the face regions having a larger curvature as in the region of the nose or in the larger motion regions of the face such as near the mouth and the cheeks, The robustness of the face mask attachment is impaired, which can lead to sucking of biological and / or mechanical impurities that must be trapped by the face mask. Another disadvantage lies in the existing method for interconnecting the individual layers of the face mask. These layers are usually interconnected only around them, which may in particular cause the intermediate layer (s) of the face mask to separate from other layers during the manufacture or use of the face mask and ultimately cause folds or shifting Which in effect substantially reduces the filtration efficiency of the face mask, ultimately limiting the action efficiency of the antimicrobial additives contained in the nanofibers of the active nanofiber layer to the captured microorganisms or other biological impurities. Common textile techniques, such as sewing or stitching, are used to tie the layers, in which case the tool used usually creates holes in the face mask that pass through its full thickness, which are the biological and mechanical impurities that the face mask needs to catch Can act as a conduit for. In addition, the fiber material is guided through these openings, which can contribute to the shifting of biological impurities, especially those contained in the atmospheric humidity, by so-called wicking effects. Due to the combination of these drawbacks, the face masks of the present invention do not achieve the required efficiency.

It is an object of the present invention to propose a face mask that corrects or at least eliminates the drawbacks of the background art, and proposes a method of manufacturing the same.

The object of the present invention is achieved by a face mask for removing biological and mechanical impurities from the bodily and / or breathable air, the face mask comprising an inner fiber layer and an outer fiber layer, Between the fibrous layers, the active layer of polymeric nanofibers and / or the filtration layer of polymeric nanofibers containing sterilizing substance (s) in its structure are arranged, the principle being that the outer and inner fiber layers are in contact with the microfibers Wherein at least the filter layer or the active layer of the polymer nanofibers adjacent to the outer fiber layer and the outer fiber layer is hydrophobic and all layers of the face mask prevent mutual movement of all of the layers, By the net of joints which reduce the permeability of the Call is connected. At the same time, the inner fiber layer is around a face mask having a layer of adhesive for fixing to the user's face. In such an arrangement, the face mask achieves high filtration effectiveness and at least due to the hydrophobic nature of the outer fiber layer, the layer of nanofibers adjacent to it can be substantially permeable to atmospheric humidity as well as humidity from the user's breath No wetting, no microbial penetration, and no smaller dimensions than the interfiber space of the layer of nanofibers. The layer of adhesive on the inner fiber layer ensures adhesion of the face mask to the user ' s face around its entire outer surface, so that no separation occurs and all of the resting and exhaling air passes through the face mask.

In the most preferred embodiment of the face mask, the outer fiber layer is formed of a meltblown type nonwoven fabric, while its inner fiber layer is formed of a spunbond type or spunlaced nonwoven fabric which is fresh when contacted with the skin of the user's face, The meltblown type nonwoven fabric preferably includes a sublayer formed of a meltblown type nonwoven fabric and a sublayer formed of a spunbond type nonwoven fabric, and the subbing layer formed of a meltblown type nonwoven fabric includes a nanofiber Lt; RTI ID = 0.0 > or < / RTI > In the latter arrangement, the sub-layer formed of a spunbond type nonwoven fabric enhances the mechanical properties of the face mask and at the same time protects the sublayer formed of the meltblown nonwoven fabric against wear and other damage.

In order to achieve hydrophobic properties, the filtration layer of the nanofibers may be formed by spinning, such as, for example, polyvinylidene fluoride (PVDF), polyurethane (PUR), polyester (PES), polylactic acid (PLA), polycaprolactone And nanofibers from a spinnable hydrophobic polymer.

The active layer of nanofibers preferably comprises nanofibers from the same hydrophobic polymers and these microfibers also contain a germicidal substance (s) which kill or at least weaken microorganisms caught in the face mask in their structure. At the same time, silver is a suitable antimicrobial substance.

For sufficient interconnection of the individual layers of the face mask, which only minimizes the permeability, the individual layers of the face mask preferably have a net or abscissa density of the spot joints of 2 to 50 densities per cm < 2 & ) Interconnected by the nets of joints. In some variations, the transverse joints may be interlaced into the lattice.

According to the manufacturing method and / or requirements, the net of joints is regular or irregular and is performed only on the entire surface of the face mask or in selected sections thereof.

In order to ensure adherence to the user's face and to cover the nose as well as the mouth of the user, the face mask is in principle rectangular in shape and its upper edge covers the nose and protrudes upwards to fit the nose of the nose And the lower edge has a concave portion facing upward in order to fit the chin and neck of the user.

In addition to this, the object of the present invention is achieved by a process for producing such a face mask. Its principle is that the face masks are made from the fabric in at least two longitudinal rows arranged side by side along the fabric, and the filter layer of the polymer nanofibers and / or the polymer nano-fibers between the outer fiber layer of the face mask and the inner fiber layer of the face mask There are active layers of fibers, which contain the germicidal material (s) and are uniform in the width and length of the fabric. Before being cut, these layers of fabric are interconnected by a net of joints that prevent mutual swapping of these layers. At the beginning of the production of the face mask, the fabric is placed upwards by its inner layer. Thereafter, in a first step, successive folds are produced about the middle section of the face mask of each vertical row of face masks along the entire length of the fabric, which are then moved along the width of the fabric at the sides of the individual face masks And then adhesive is applied on the peripheral sections of future face masks, which are partially overlapped by the antiadhesive material and the heat of the side-by-side face masks is cut into the final shape.

In another variation, it is possible to partially overlap the adhesive layer with an antiadhesive material only after cutting out the face mask shape, which allows the antiadhesive material to extend over the edges of the face mask, This makes removal easier.

It is advantageous to use ultrasonic welding for the fixing of the wrinkles of the fabric which does not create any pores in the fabric which may reduce the effectiveness of the future face mask or cause any material which acts to transfer the captured microorganisms to the fabric Because they do not bring it into me.

For the purpose of impairing the permeability of the face mask to the minimum possible, the layers of the fabric are interconnected by a net of spots or transverse joints, possibly by a net of transverse joints joined together.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a view showing an embodiment of a face mask according to the present invention.

The face mask 1 for removing biological and mechanical impurities from the air to be ingested / inhaled / exhaled according to the present invention is in the example of the embodiment according to FIG. 1, which is substantially rectangular in shape, and this rectangular long face 2, 20 pass through the face of the user under the nose and chin when applied to the face mask 1 and the short face 3, 30 passes from the cheek to the user's neck in front of the ears. In the center section passing over the mouth and nose, folds 4 are provided which are horizontal folds in the example of the embodiment shown. These pleats 4 are located on the sides of the face mask 1 fixed by any of the known methods such as, for example, fusion bonding by ultrasonic waves, and the shape of the user's face and / Thereby enabling the formation of the face mask 1 according to the size. The upper one of the long sides 2, 20 of the rectangle is in the center section molded upward in the form of an upwardly extending projection 21 for covering the nose in the example of the embodiment shown. Of the long sides 2, 20 of the rectangle, the bottom is in the form of an arch in the illustrated embodiment and is in an upwardly directed central section aimed at the recess 201. This shaping enables better adherence of the face mask 1 to the user ' s face.

At the periphery of the face mask 1, the face mask 1 is on a defined face for contact with the user's face provided with an undisplayed layer of known adhesive material with good skin fit. Prior to use of the face mask 1, the layer of adhesive material is covered with an anchorage material, which in the illustrated embodiment is covered with stripes 5, 50, 6, 60 of silicone paper. For easier removal, these stripes 5, 50, 6, 60 are longer than the respective sides 2, 20, 3, 30 of the face mask 1 and extend beyond their edges. This allows them to be easier to grip and remove before application of the face mask 1. At the same time, it is necessary to apply these streaks 5, 50, 6, 60 on the face mask 1 after the shape is cut from the semi-finished product of which the shape thereof is formed by the long strip of the woven fabric. In contrast, in one operation, with the stuck streaks 5, 50, 6, 60 of the silicone paper, which in this case are the shapes of the respective parts of the face mask 1 in this case It may be proposed to create the shape of the face mask 1 from a wide and long fabric using a single forming tool, in which case these stuck streaks are placed on the face mask 1 and the edges of the face mask 1 Do not extend beyond.

Before applying the face mask 1, the covering stripes 5, 50, 6, 60 of the silicon paper are removed from the face mask 1. After the edges of the face mask 1 have stuck onto the user's face, the space around the nose and mouth of the user is surrounded and all the air that is inhaled and exhaled passes through the face mask 1.

The face mask 1 according to the present invention, that is, the fabric from which this face mask 1 is made comprises an inner fiber layer and an outer fiber layer, and between the inner fiber layer and the outer fiber layer, a filtration layer of polymer nanofibers and / Or an active layer is disposed. The inner fiber layer in contact with the user's face can be made of a nonwoven fabric, preferably a hydrophobic material such as polypropylene (PP) or polyester (PES), a spunbond nonwoven fabric of microfibers or viscose (VS) Or from polymer microfibers to a spunlaced nonwoven fabric. The outer fiber layer is made of a nonwoven fabric of microfibers from a hydrophobic material, preferably a meltblown nonwoven fabric from polypropylene (PP), viscose (VS), polyester (PES) or other microfibers. In the most preferred embodiment, the outer layer is formed by a combination of a sub-layer formed of a spunbond type non-woven fabric and a sub-layer formed of a meltblown type non-woven fabric, Improves the mechanical properties of the outer layer and protects it from the outside of the sublayer formed of a meltblown nonwoven fabric against mechanical wear and damage. The filtration layer of the nanofibers may be formed from a hydrophobic polymer such as, for example, polyvinylidene fluoride (PVDF), polyurethane (PUR), polyester (PES), polylactic acid (PLA), polycaprolactone Fibers. The active layer of the nanofibers is formed of nanofibers from the same hydrophobic polymer and in its structure kills or at least weakens microorganisms (bacteria, viruses, mold fungi, yeast, etc.) caught in the face mask 1 or passing through the face mask A suitable substance (s) having a sterilizing action is disposed.

By ensuring that the face mask 1 is not substantially permeable to atmospheric humidity as well as to the humidity of the user's breath, if the hydrophobic nature of the outer fiber layer and the layer of polymer nanofibers and, at the same time, , The face mask 1 is not wetted and does not create a state suitable for infiltration and propagation of the captured microorganisms. The filtration layer and / or the active layer of the polymer nanofibers, due to their ultrafine porosity and the high specific surface, have a great influence on the physical and biological impurities contained in the breathed air, Dust particles and so on.

The disadvantage is that, when the hydrophobic inner fiber layer is used, the inner surface of the face mask 1 in contact with the user's face is adhered to moisture from the user's breath. Therefore, in order to make the user feel much more comfortable, it is advantageous to create a layer of hydrophilic material which is capable of absorbing moisture from the user ' s breath so that there is no condensation on its surface. This modification contributes to a better psychological stability of the user.

For the industrial production of the face mask 1 according to the invention, the same properties, in particular the filtration properties of the polymer nanofibers arranged inside the fabric and / or the filtering properties, It is necessary to correct for the mask 1. Therefore, this layer of polymeric nanofibers should be even for both the width and length of the fabric. Due to the fact that the width exhibits smaller dimensions, pucking in the longitudinal direction of the fabric is the most important. This is currently the case, for example, in the electric field induced between the spinning electrode and the collecting electrode, according to EP1673493 or according to European patent EP2059630 or European patent application EP2173930, Can only be achieved through a long and repeatable stable spinning process represented by electrostatic spinning. At the same time, for the production of an active layer of polymeric nanofibers, for example by applying a similar procedure as described in European patent application EP1869232.

In production, a layer of polymer nanofibers is laminated on a carrier substrate layer, which is made by combining a meltblown nonwoven fabric or a spunbonded and meltblown nonwoven fabric. Such a substrate layer usually has a basis weight of 30 to 80 g / m < 2 >, and the diameter of the fabric is 1 to 5 mu m. Prior to laminating the layers of polymer nanofibers, a binder may be applied to the substrate layer to ensure better interconnections of the substrate layer and the layer of polymer nanofibers. In the embodiment shown and described, the substrate layer represents the outer layer of the face mask 1.

After the layers of polymer nanofibers are laminated on the carrier substrate layer and after possible drying and / or cross-linking of the nanofibers, on the layers of polymer nanofibers, microfibers made of a hydrophobic material, preferably of the spunbond type, A cover layer of fibers is laminated, which forms an inner layer designated to contact the user's face in the face mask 1 produced. Such a cover layer usually has a basis weight of 12 to 50 g / m < 2 >, and the diameter of the fabrics is 1 to 5 mu m.

All three layers of the fabric for the production of the face mask 1 according to the invention are used in the example of the embodiment during the operation with the fabric during the production of the face mask 1, Are interconnected by unshown dense nets of spot joints formed by the binder and / or fusion binder to ensure a constant mutual position of all layers during the process. The dense net of spot joints is understood as a net of 2 to 50 bindings points / cm < 2 > of the fabric surface serving as the fabricator of the face mask 1. The specific weight of the binder used varies usually in the range of from 2 to 20 g / m < 2 >. The advantage of a spot interconnecting the layers is that it does not substantially affect the overall transmissivity of the face mask 1, which is even if it is present on the entire surface and, on the other hand, Do not create face mask holes that allow the passage of biological and / or mechanical impurities, and do not take them into any material that can contribute to such passage by so-called wicking effects . In order to interconnect the layers of the face mask 1 by means of a binder and / or a fusion binder, for example the binder or fusion binder may be applied to some of the layers of the face mask 1, , It is possible to use the procedure described in CZ PV 2010-373, interconnecting all of its layers upon subsequent lamination. The net of spot joints may be regular or irregular, and may be dense at places where the mechanical stress of the face mask 1 is increased. In other variations of the embodiment, the binder and / or the fusion binder are applied during the manufacture of some of the layers of the face mask 1, possibly some layers of the face mask 1 in the form of a fabric or a pre-prepared web So that the joints performed have the same or similar advantages as the spot joints, although they may have the shape of the transverse axes and possibly combine in the form of a network. In other variants of the embodiment, the layers of the face mask 1 are interconnected in yet another way, which ensures their proper bundling, for example by ultrasonic welding, possibly in combination with this procedure and some of the foregoing . The interconnecting of the layers of the face mask 1 according to the need and designation of the face mask 1 is carried out only on its entire surface or only on the part in the region of the corrugations 4, for example.

The face mask 1 according to the present invention is on the free surface of the inner layer provided with a layer of adhesive in the form of stripes guided along the entire periphery of the face mask 1 for fixing mainly to the face of the user. In comparison with the conventional cases so far, when the face mask 1 is fixed to the user's face in a similar manner or with streaks of fabric, the face mask according to the present invention is applied to the face of the face mask 1 And thus the overall efficiency of the face mask 1 and its utilization value will be substantially increased, which results in a significant increase in air flow between the curved or moving parts of the user's face and the face mask 1, Because the air is not ingested or spewed through the gaps created in or through its separation. In further variants, the face mask 1 according to the invention is provided with additional layers laminated on its inner and / or outer fiber layer, which increases the filtration efficiency for biological and / or mechanical impurities , Perhaps such additional layers act actively against the captured microorganisms or make contact with the face of the face mask 1 more comfortable, thereby increasing its service life, abrasion resistance, consistency, and the like. At the same time, one of the additional layers may be represented by an active layer of another filtration and / or polymer nanofibers. In addition, the face mask 1 may be provided with additional reinforcing elements, which further increase / increase its attachment rigidity or prevent it from separating from the user's face through its molding.

Industrial production of the face mask 1 according to the invention is then carried out so that all the layers of the fabric, which first act as the preparation of the face mask 1, are placed in order and then, in some of the abovementioned ways, Or transverse joints, to prevent undesired shifting in further operation. Since the carrier substrate layer for the lamination of additional layers preferably serves as the outer fiber layer of the future face mask 1, on the future face mask 1 there will be a cover layer representing the inner fiber layer of the future face mask The filtering layer and / or the active layer of the nanofibers are gradually laminated. The filtering layer of nanofibers and / or the active layer of nanofibers are preferably laminated directly onto the carrier substrate layer through electrostatic spinning. At the beginning of the fabrication, the fabric is placed upwards by the inner fiber layer of the future face mask. Continuous wrinkles of the required size and density are then created along the entire length of the fabric prepared using known devices and these wrinkles are transferred to the shorter sides 3 of the individual future face masks 1 in a suitable manner , 30), which do not make holes in the fabric, but then deteriorate the filtering properties of the face mask 1, for example by ultrasonic welding. Thereafter, a layer of a suitable adhesive having good skin compatibility is applied on the upper layer of fabric on the edge sections of future face masks 1, and the layer is formed, for example, by stripes 5, 50 and 6, 60 by an anti-adhesive material. Thereafter, one line of face masks 1 arranged side by side with the desired shape from the fabric is cut off.

In yet another variation of the face mask manufacturing, a layer of adhesive material and / or an adhesive material may be applied only after the shape of the face mask 1 is made from the fabric.

The following examples generally illustrate various modifications of the embodiments of the face mask 1 according to the invention.

Example 1

The inner fiber layer of the face mask 1 is preferably made of a spunbond type nonwoven fabric using polypropylene (PP), polyester (PES) or other microfibers, Depending on the designation and need, between 12 g / m 2 and 50 g / m 2. (PVDF), polyurethane (PUR), polyester (PES), polylactic acid (PLA), polycaprolactone (PCL), and the like, prepared via needleless electrostatic spinning, The filtration layers of the nanofibers of the hydrophobic polymer are laminated and their basis weights vary between 0.03 g / m 2 and 1 g / m 2, depending on the designation of the face mask 1 and if necessary. The diameters of the nanofibers are between 150 nm and 600 nm. On the filtration layer of the nanofibers, an outer fibrous layer of a meltblown type nonwoven fabric, preferably a face mask 1 made of polypropylene (PP), viscose (VS), polyester (PES) and possibly other microfibers, And their basis weights vary between 30 g / m 2 and 80 g / m 2, depending on the designation of the face mask 1 and the need. All layers of the face mask 1 are interconnected by a network of spot joints.

The inner fiber layer of the face mask 1 is present at the edges on its outer surface provided with a layer of adhesive material of good skin compatibility.

Example 2

The inner fiber layer of the face mask 1 and the filtration layer in which the nanofibers are stacked thereon are produced in the same manner as in Example 1. [ On the filtration layer of the nanofibers, a sublayer made of a nonwoven fabric of a meltblown type made of polypropylene (PP), polyester (PES) and possibly other microfibers, preferably a sublayer made of polypropylene (PP) An outer fiber layer formed of a combination of sub-layers made of spunbond type nonwoven fabric made of other microfibers is laminated and a basis weight resulting therefrom is set between 30 g / m 2 and 80 g / m 2 It changes. The sublayer made from the spunbond type nonwoven fabric enhances the mechanical properties of the face mask 1 at the same time as the face mask 1 and protects the sublayer made from the meltblown nonwoven fabric against mechanical wear or other damage.

All layers of the face mask 1 are interconnected in the same manner as in Example 1.

The inner fiber layer of the face mask 1 is present on the edges on the outer surface provided with a layer of adhesive material with good skin compatibility.

Example 3

The outer fiber layer of the face mask 1 and the filtration layer of the nanofibers are produced in the same manner as in Example 1. [ Both of these layers are laminated on the inner fiber layer of the face mask 1 and this face mask 1 is preferably made of a spun lace type nonwoven fabric of viscose (VS), cellulose or other polymer micro fibers, Their basis weights vary between 30 g / m 2 and 80 g / m 2, depending on the designation of the face mask 1 and the need.

All layers of the face mask 1 are interconnected in the same manner as in Example 1.

The inner fiber layer of the face mask 1 is present on the edges on the outer surface provided with a layer of adhesive material with good skin compatibility.

Example 4

The inner fiber layer and the outer fiber layer of the face mask 1 are made of nonwoven fabric in the same manner as in Example 1. [ Between these inner and outer fiber layers there is a stack of active layers of prepared nanofibers through needless electrostatic spinning and this active layer has a germicidal material (s) such as silver nanoparticles or a sterilizing action Including nanofibers of hydrophobic polymers such as polyvinylidene fluoride (PVDF), polyurethane (PUR), polyester (PES), polylactic acid (PLA), polycaprolactone do. The basis weight of the active layer of the nanofibers varies between 0.03 g / m 2 and 1 g / m 2, depending on the designation of the face mask 1 and if necessary. The diameters of the nanofibers are between 150 nm and 600 nm.

All layers of the face mask 1 are interconnected in the same manner as in Example 1.

The inner fiber layer of the face mask 1 is present on the edges on the outer surface provided with a layer of adhesive material with good skin compatibility.

Example 5

The inner and outer fiber layers of the face mask 1 are made of nonwoven fabrics in the same manner as in Example 2. [ An active layer of the nanofibers according to Example 4 is laminated between the inner fiber layer and the outer fiber layer.

All layers of the face mask 1 are interconnected in the same manner as in Example 1.

The inner fiber layer of the face mask 1 is present on the edges on the outer surface provided with a layer of adhesive material with good skin compatibility.

Example 6

The inner and outer fiber layers of the face mask 1 are made of nonwoven fabrics in the same manner as in Example 3. [ An active layer of the nanofibers according to Example 4 is laminated between the inner fiber layer and the outer fiber layer.

All layers of the face mask 1 are interconnected in the same manner as in Example 1.

The inner fiber layer of the face mask 1 is present on the edges on the outer surface provided with a layer of adhesive material with good skin compatibility.

Example 7

The inner fiber layer of the face mask 1 is made of nonwoven fabric in the same manner as in Example 1. [ Above the layer there may be mentioned, for example, polyvinylidene fluoride (PVDF), polyurethane (PUR), polyester (PES) or the like containing microbicidal substance (s), such as silver nanoparticles, , Polylactic acid (PLA), polycaprolactone (PCL), and the like, and the basis weight of the nanofibers of the hydrophobic polymer varies between 0.03 g / m 2 and 1 g / m 2. On the active layer of the nanofibers, a filtration layer of nanofibers of hydrophobic polymer whose basis weights vary between 0.03 g / m < 2 > and 1 g / m < 2 > The layers of nanofibers are all made by needle-free electrostatic spinning.

On the active layer of the nanofibers, an outer fiber layer of the face mask 1 made of a nonwoven fabric as in Example 1 is further laminated.

All layers of the face mask 1 are interconnected in the same manner as in Example 1.

The inner fiber layer of the face mask 1 is present on the edges on the outer surface provided with a layer of adhesive material with good skin compatibility.

Example 8

The inner fiber layer of the face mask 1 is made of a nonwoven fabric in the same manner as in Example 2. [ On this layer, an active layer of nanofibers of a hydrophobic polymer containing sterilizing substance (s) inside the structure is laminated as in Example 7, and on this active layer, a filtration layer of nanofibers from the hydrophobic polymer is laminated. All of the layers of nanofibers are made by needle-free electrostatic spinning. On the filtration layer of the nanofibers, an outer fiber layer of the face mask 1 formed of a nonwoven fabric as in Example 2 is further laminated.

All layers of the face mask 1 are interconnected in the same manner as in Example 1.

The inner fiber layer of the face mask 1 is present on the edges on the outer surface provided with a layer of adhesive material with good skin compatibility.

Example 9

The inner fiber layer of the face mask 1 is made of nonwoven fabric in the same manner as in Example 3. [ On this layer, an active layer of nanofibers of a hydrophobic polymer containing sterilizing substance (s) inside the structure and a filtration layer of nanofibers of hydrophobic polymer are laminated as in Example 7. All of the layers of nanofibers are made by needle-free electrostatic spinning. On the filtration layer of the nanofibers, the outer fiber layer of the face mask 1 formed of the nonwoven fabric as in Example 2 is laminated.

All layers of the face mask 1 are interconnected in the same manner as in Example 1.

The inner fiber layer of the face mask 1 is present on the edges on the outer surface provided with a layer of adhesive material with good skin compatibility.

Claims (18)

A face mask (1) for removing biological and mechanical impurities from the air and /
An active layer of polymer nanofibers containing a sterilizing material and / or a filtration layer of polymer nanofibers is disposed between the inner fiber layer and the outer fiber layer,
Wherein the outer fiber layer and the inner fiber layer are formed of microfibers, and at least the outer fiber layer and the filter layer or the active layer of the polymer nanofibers adjacent to the outer fiber layer are hydrophobic, Wherein the inner fibers are interconnected by a net of joints that prevents movement and minimizes the permeability of the face mask to a minimum, the inner fiber layer being secured to the face of the user around the face mask (1) , Said face mask (1) being fixed to the places of shorter sides along the entire width of the width of said face mask (1) at least in its central section for covering the mouth and nose A face mask characterized in that folds are provided. The method according to claim 1,
Wherein the inner fiber layer is formed of a spunbond or spunlace type nonwoven fabric and the outer fiber layer is formed of a meltblown type nonwoven fiber. The method according to claim 1,
Wherein the inner fiber layer is formed of a spunbond or spunlaced nonwoven fabric and the outer fiber layer comprises a sublayer formed of a meltblown type nonwoven fabric and a sublayer formed of a spunbond type nonwoven fabric, Wherein the sublayer formed of a meltblown type nonwoven fabric is adjacent to the filtering layer or the active layer of the nanofibers. 4. The method according to any one of claims 1 to 3,
The filtration layer of the nanofibers may comprise nanofibers of polymer from the group of polyvinylidene fluoride (PVDF), polyurethane (PUR), polyester (PES), polylactic acid (PLA), polycaprolactone Wherein the face mask comprises at least one member selected from the group consisting of: 5. The method according to any one of claims 1 to 4,
The active layer of nanofibers may comprise nanofibers of polymers from the group of polyvinylidene fluoride (PVDF), polyurethane (PUR), polyester (PES), polylactic acid (PLA), polycaprolactone (S) in their structure. ≪ RTI ID = 0.0 > 8. < / RTI > 6. The method of claim 5,
Wherein the nanofibers of the active layer contain silver nanoparticles. 7. The method according to any one of claims 1 to 6,
Wherein all layers of the face mask are interconnected by a net of spot joints having a density of 2 to 50 dots per square centimeter of the face mask surface. 7. The method according to any one of claims 1 to 6,
Characterized in that all layers of the face mask (1) are interconnected by a net of abscissa joints. 7. The method according to any one of claims 1 to 6,
Characterized in that all layers of the face mask (1) are interconnected by a net of transverse joints joined together. 10. The method according to any one of claims 7 to 9,
Characterized in that the layers of the face mask (1) are interconnected at the entire surface of the face mask (1). 10. The method according to any one of claims 7 to 9,
Wherein the layers of the face mask (1) are interconnected in an active layer of the face mask (1) surface. 12. The method according to any one of claims 1 to 11,
The long side 2 of the face mask 1 is formed into a protrusion 21 which covers the nose and extends upward so as to fit the nose of the nose and the lower long side 20 of the face mask 1, Is formed by a recess (20) facing upward in the direction of the chin and neck of the user. A method of manufacturing face masks (1)
(S) between the outer fiber layer of the face mask (1) and the inner fiber layer of the face mask (1), at least two longitudinal stripes arranged side by side along the fabric The active layer of the polymer nanofibers and / or the active layer of polymeric nanofibers is also present in the width direction as well as the length of the fabric, and layers of fibers can be used to effect mutual shifting of the layers of the fabric Wherein the fabric is arranged by the inner layer of the face mask (1) at the beginning of the production of the face mask (1), and in the first step the entire length of the fabric Thus, successive folds of the middle section of the face masks 1 in each column of the face masks 1 are created And these successive folds are fixed along the width of the fabric at the places where the short sides 3, 30 of the face mask 1 are located and then the adhesive is applied to the peripheral sections of future face masks 1 Characterized in that the adhesive is partly overlapped by the antiadhesive material and the rows of face masks (1) arranged side by side are cut into the final shape of the face masks (1) Way. A method of manufacturing face masks (1)
(S) in the fabric between the outer fibrous layer of the face mask (1) and the inner fibrous layer of the face mask (1), at least two longitudinal stripes arranged side by side along the fabric, And the active layers of the polymeric nanofibers are uniformly present in the width and length direction of the fabric and the layers of the fabric prevent mutual shifting of the layers of the fabric before the cutting is started And at the beginning of the production of the face mask (1), the fabric is placed upwards by the inner layer of the face mask, and along the entire length of the fabric in a first step, the face Continuous corrugations are created about the middle section of the face masks 1 of each column of masks 1, Is fixed along the width of the fabric at locations where the short sides 3, 30 of the face masks 1 are present, then the adhesive is applied on the peripheral sections of future face masks 1, Characterized in that the rows of face masks (1) arranged are cut into the final shape of the face masks (1), and the layers of adhesive are partially overlapped by an antiadhesive material. The method according to claim 13 or 14,
Wherein the wrinkles are fixed by ultrasonic welding. The method according to claim 13 or 14,
Wherein the layers of fabric are interconnected by a net of spot joints. 17. The method according to any one of claims 13 to 16,
Wherein the layers of fabric are interconnected by a net of transverse joints. 16. The method according to any one of claims 13 to 15,
Wherein the layers of the fabric are interconnected by a net of transverse joints joined together.

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