JP2009226711A - Mask - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mask with excellent sterilization performance to influenza virus. <P>SOLUTION: This mask comprises a sticky layer 16 formed on an unwoven fabric 15 and a fine metal particle 21 of aluminum and a fine metal particle 22 of zinc, each being supported on the unwoven fabric 15. through the sticky layer 16. In addition, an insulating film 23 is formed between these fine metal particles 21 and 22 and thereby, numerous cells are formed on the unwoven fabric 15. Thus direct current exceeding control current of a microbe, is run through the microbe, utilizing current running between both poles of the cell. Thus the sterilization effect on the microbe is brought about. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a mask, and more particularly to a mask that covers the human nose and mouth to prevent inhalation or / and release of pathogenic bacteria.

  In general, influenza is an infectious disease that occurs when a virus enters a human body. Influenza due to viruses has a feature of extremely high infectivity. Moreover, as represented by bird flu, there is a concern that viral influenza, which is a threat to mankind, will become prevalent. Such influenza viruses may spread and be explosively infected on a global scale due to the development of transportation systems. Countermeasures against such viral flu are very difficult.

  Also, conventional masks are almost powerless to prevent viral infections as described above. That is, since the virus is a very fine microorganism, the virus can easily pass through a conventional mask having air permeability. For this reason, even if a mask is worn, the virus inhales or the infected person emits the virus through the mask, and it is virtually impossible to prevent infection by the mask. there were.

  In the case of a mask using a virus-resistant high-density fiber (N95), the mask itself has a high air density and poor air permeability, which makes it difficult for a person wearing the mask to breathe. . In other words, because it is not possible to take in enough outside air into the lungs, it is difficult to work for a long time, or work that requires force work cannot be done, and the work time must be shortened was there.

Japanese Patent No. 3276141 discloses an antibacterial cloth obtained by spraying a vegetable fiber cloth with zinc or a zinc alloy. This antibacterial cloth utilizes the antibacterial property of zinc and has not only a low bactericidal performance but also a little bactericidal property against viruses. Further, when zinc is sprayed onto the vegetable fiber cloth, the vegetable fiber cloth is burned, and the adhered zinc fine particles are easily removed by washing, and there is a disadvantage that the durability is not achieved.
Japanese Patent No. 3276141

  The subject of this invention is providing the mask excellent in the bactericidal performance with respect to a pathogenic microbe.

  Another subject of this invention is providing the mask excellent in the bactericidal performance with respect to a virus.

  Still another object of the present invention is to provide a mask capable of sterilizing influenza virus.

  Yet another object of the present invention is to provide a mask capable of sterilizing chemical-resistant viruses.

  The above-described problems and other problems of the present invention will be clarified by the technical idea of the present invention and the embodiments thereof described below.

The main invention of the present application is in a mask that covers the nose and mouth to prevent inhalation or / and release of pathogenic bacteria.
It has a breathable sterilization sheet, and the sterilization sheet carries two kinds of metal fine particles having different ionization tendencies, the two kinds of metal fine particles are in contact with each other through an insulating coating, and an infinite number of minute particles are placed on the sterilization sheet. The present invention relates to a mask characterized in that a simple battery is formed.

  Here, the base material of the breathable sterilization sheet may be a nonwoven fabric. In addition, an air-permeable adhesive layer may be formed on the surface of the air-permeable sheet, and the metal fine particles may be supported via the adhesive layer. The metal fine particles may be supported on the surface of the pressure-sensitive adhesive layer formed on the breathable sheet or on the surface opposite to the surface of the sheet on which the pressure-sensitive adhesive layer is formed. Moreover, you may make it join the cover sheet | seat in which the adhesion layer was formed on the surface to the surface of the said sterilization sheet | seat with which the said metal microparticle is carry | supported. Further, the breathable sterilization sheet is constituted by joining two nonwoven fabrics, an adhesive layer is formed on one surface of the nonwoven fabric, and the metal fine particles are supported on the surface of the adhesive layer. The pressure-sensitive adhesive sheet may be formed by bonding the supported pressure-sensitive adhesive layers to each other. Further, the breathable sterilization sheet is constituted by joining two nonwoven fabrics, and an adhesive layer is formed on one surface of the nonwoven fabric, the metal fine particles are supported on the other surface, and the adhesive layers are bonded to each other. The sterilizing sheet may be formed by joining together. Moreover, you may make it join the cover sheet | seat in which the adhesion layer was formed on the surface to the surface of the said sterilization sheet | seat with which the said metal microparticle is carry | supported.

  The two kinds of metal fine particles may be supported on the sterilization sheet by thermal spraying. The two kinds of metal fine particles may be aluminum and zinc. Moreover, you may be comprised from the hot-melt-type adhesive which expresses adhesiveness when the said adhesion layer is heated. Further, it may have a moisturizing sheet that absorbs and retains moisture from the intake air, and the moisturizing sheet may be joined to the sterilizing sheet or may be sandwiched between two sterilizing sheets. In addition, a notch may be formed to prevent a gap from being generated when the sterilization sheet is attached to the peripheral edge.

  The main invention of the present application is a mask that covers the nose and mouth to prevent inhalation or / and release of pathogenic bacteria, and has a breathable sterilization sheet, and the sterilization sheet carries two kinds of metal fine particles having different ionization tendency. The two kinds of metal fine particles are brought into contact with each other through an insulating film, and an infinite number of minute batteries are formed on the sterilization sheet.

  Therefore, according to such a mask, countless minute batteries are formed by the two kinds of metal fine particles carried on the breathable sterilization sheet, and a minute current flows due to a potential difference generated between both electrodes of the battery. A minute electric current passes through a current exceeding a control current that controls a control system of a very fine microorganism such as a virus, and thus the microorganism is killed. Therefore, it is possible to reliably sterilize very minute microorganisms such as viruses.

  The present invention will be described below with reference to embodiments shown in the drawings. FIG. 1A shows a sterilization structure of a mask, in which the mask includes a plurality of, for example, two sterilization sheets 10, and these sterilization sheets 10 are stacked via a moisturizing sheet 11. It has been. Here, two sterilization sheets 10 and three moisturizing sheets 11 are stacked.

  FIG. 1B is an example of another configuration, in which three sterilization sheets 10 are combined with four moisturizing sheets 11, and these are alternately arranged to form a seven-layer mask. . Thus, the mask of the present embodiment has a structure in which a plurality of sterilization sheets 10 and a plurality of moisture retention sheets 11 are alternately combined.

  FIG. 2A shows the configuration of the sterilizing sheet 10, in which a nonwoven fabric 15 is used as a base material, and an adhesive layer 16 made of a hot melt adhesive is formed on one surface of the nonwoven fabric 15. The surface of the adhesive layer 16 carries metal fine particles 21 made of aluminum and metal fine particles 22 made of zinc. These metal fine particles 21 and 22 may be adhered and supported on the surface of the nonwoven fabric 15 on which the adhesive layer 16 is formed by a method such as spraying simultaneously or separately. At this time, the aluminum metal fine particles 21 and the zinc metal fine particles 22 are supported in a state of being separated from each other and being mixed together. In FIG. 2A, the nonwoven fabric 15 has irregularities because the adhesive layer 16 is formed on the surface of the nonwoven fabric 15 while applying pressure in a spot shape.

  Here, as the hot melt pressure-sensitive adhesive for forming the pressure-sensitive adhesive layer 16, various hot-melt pressure-sensitive adhesives such as polyethylene-based, polyamide-based, polyester-based, polyurethane-based, acrylic resin, and vinyl chloride resin are used. In this case, in order to set the melting temperature to an appropriate value, an optimum one can be selected from the various adhesives described above.

  FIG. 2B shows an example of another sterilization sheet 10. Here, an adhesive layer 16 made of a hot melt adhesive is formed on one surface of the nonwoven fabric 10. Moreover, the fine metal particles 21 made of aluminum and the fine metal particles 22 made of zinc are supported on the surface of the nonwoven fabric 15 opposite to the surface on which the adhesive layer 16 is formed so as to be mixed. In general, instead of directly supporting the metal fine particles 21, 22 on the surface of the pressure-sensitive adhesive layer 16 formed on the surface of the nonwoven fabric 15, the opposite side through the nonwoven fabric 15 using a hot melt adhesive leached on the opposite surface by heating. You may make it carry on the surface. In FIG. 2B, the pressure-sensitive adhesive layer 16 is drawn on the surface of the nonwoven fabric 15 in an independent state, but actually the pressure-sensitive adhesive layer 16 penetrates into the nonwoven fabric 15 and thereby the side opposite to the surface on which the pressure-sensitive adhesive layer 16 is formed. Since the adhesive layer 16 is leached also on the surface of the metal fine particles 21, 22 on the surface of the nonwoven fabric 15 opposite to the surface on which the adhesive layer 16 is formed using the adhesive force of the adhesive layer 16. It can be supported.

  Next, the structure which forms the sterilization sheet | seat 10 using the two nonwoven fabrics 15 is demonstrated with reference to FIG. As shown in FIG. 3A, two nonwoven fabrics 15 having an adhesive layer 16 formed on one surface are prepared. The fine metal particles 21 and 22 are supported on the surface of the adhesive layer 16 on the nonwoven fabric 15, respectively. In such a state, as shown in FIG. 3B, the nonwoven fabrics 15 on both sides are joined together, and the adhesive layers 16 formed on the surfaces of these nonwoven fabrics 15 are joined together. Then, a pair of nonwoven fabrics 15 are joined in a state where the metal fine particles 21 and 22 formed on the surface of the adhesive layer 16 are sandwiched between the adhesive layers 16 on both sides. Such a configuration makes it possible to reliably cover the metal fine particles 21 and 22 supported on the nonwoven fabric 15 via the adhesive layer 16 with the nonwoven fabric 15 on both sides. Accordingly, the metal fine particles 21 and 22 are prevented from falling off. The sterilization action by the metal fine particles 21 and 22 is because the virus contained therein can be sterilized when air or intake air passes through the sterilization sheet 10 having a structure as shown in FIG. 3B. The sterilization performance is not lowered.

  FIG. 4A shows another configuration, in which two nonwoven fabrics 15 in which the adhesive layer 16 is formed on one surface of the nonwoven fabric 15 and the metal fine particles 21 and 22 are formed on the opposite surface are used. . And these nonwoven fabrics 15 are joined so that the adhesive layer 16 on them faces each other. As a result, as shown in FIG. 4B, the sterilization sheet 10 having two kinds of fine metal particles 21 and 22 supported on the outer surface is formed. Here, since the sterilization sheet 10 is formed by pressure bonding the above-mentioned adhesive layer 16 by point contact, the surface of the nonwoven fabric 15 has irregularities as shown in FIG. 4B.

  The sterilization sheet 10 shown in FIG. 2A is carried with the metal fine particles 21 and 22 exposed on the surface of the pressure-sensitive adhesive layer 16. Moreover, the sterilization sheet 10 shown in FIG. 2B or FIG. 4B carries the metal fine particles 21 and 22 on its outer surface, in particular, on the surface where the adhesive layer 16 is not formed. Therefore, in order to protect the metal fine particles 21 and 22, a configuration as shown in FIG.

  As shown in FIG. 2A, when the fine metal particles 21 and 22 are further supported on the nonwoven fabric 15 via the adhesive layer 16 and the fine metal particles 21 and 22 are exposed on the outer surface, a cover is formed. What is necessary is just to cover the nonwoven fabric 25 which comprises a sheet | seat on the surface. Here, an adhesive layer 26 is formed on one surface of the nonwoven fabric 25 constituting the cover sheet, and such an adhesive layer 26 is formed on the adhesive layer 16 carrying the metal fine particles 21 and 22 of the sterilizing sheet 10. Join to cover the surface. In the case of the sterilization sheet 10 of FIG. 2B, a cover sheet may be bonded to the surface of the nonwoven fabric 15 where the metal fine particles 21 and 22 are exposed.

  As shown in FIG. 4B, when the metal fine particles 21 and 22 are respectively supported on the outer surfaces of the nonwoven fabrics 15 on both sides bonded to each other through the adhesive layer 16, the metal fine particles 21 and 22 are What is necessary is just to cover the nonwoven fabric 25 which has the adhesion layer 16 on the outer surface of the both sides so that it may cover. Here, the adhesive layer 26 covers the metal fine particles 21 and 22 on the outer surface of the non-woven fabric 15, thereby preventing the metal fine particles 21 and 22 from falling off.

  FIG. 6 shows a configuration in which a cut 30 is made in the sterilizing sheet 10 used inside the mask. In the case of a mask for preventing influenza virus infection, even if the sterilization sheet 10 itself has sterilization performance against the virus, if a gap is formed between the mask and the peripheral portion of the face wearing position, Viruses enter or are released through this gap. Therefore, in order to prevent the above-described gap from occurring, a notch 30 is appropriately made in the peripheral edge portion of the sterilizing sheet 10 so as to eliminate the gap between the face wearing part and the mask.

  Next, an example of a specific mask configuration will be described with reference to FIGS. The mask 35 has a substantially semi-ellipsoidal shape as shown in FIGS. 7 to 9 and covers the mouth from the nose of the human face. Two rubber bands 36 are attached to such a mask 35. The rubber band 36 is coupled to the mask 35 by heat welding at the coupling portion 37. The peripheral portion of the mask 35 is welded to form a peripheral weld portion 38, which is integrated at the peripheral portion. The mask 35 is provided with a metal plate 39 that is bent in a U-shape on the outer surface. The metal plate 39 can be plastically deformed, thereby forming the shape of the outer portion of the nose, particularly the upper portion of the mask 35, and increasing the degree of adhesion with the upper side of the nose. Further, in correspondence with the metal plate 39, a U-shaped sponge pad 40 is bonded to the inside and upper part of the mask 35 as shown in FIG. The sponge pad 40 is for eliminating a gap between the mask 35 and the mask 35 in the upper part of the nose, in particular, and eliminating leakage of exhalation or inspiration.

  Next, the laminated structure of the mask 35 will be described with reference to FIG. 10A. The mask 35 is provided with the antibacterial sheet 10 on both sides so as to sandwich the single moisturizing sheet 11 disposed in the center, and the outer cover 42 is superposed on the outer side, and the inner sheet 44 is overlapped on the inner side. It has come to be combined. The outer cover 42 is joined to the sterilization sheet 10 by an adhesive layer 43 formed on the inner surface thereof. The inner sheet 44 is joined to the surface of the inner sterilization sheet 10 by the adhesive layer 45.

  FIG. 10B shows a configuration example of the sterilization sheet 10 shown in FIG. 10A. Here, adhesive layers 16 each made of a hot-melt adhesive material are formed on the surfaces of the two nonwoven fabrics 15, and these adhesive layers are formed. Metal fine particles 21 made of aluminum and metal fine particles 22 made of zinc are respectively welded and supported on the surface 16. The nonwoven fabrics 15 on both sides are joined and fixed to each other by the adhesive layer 16 carrying the metal fine particles 21 and 22, thereby constituting the two-layer structure sterilization sheet 10.

  Next, the principle of sterilization of the sterilization sheet 10 as described above will be described. The metal fine particles 21 made of aluminum and the metal fine particles 22 made of zinc are formed, for example, by being simultaneously supported on the adhesive layer 16 or the nonwoven fabric 15 by thermal spraying. At this time, since the ionization tendency of aluminum and zinc is different from each other, a potential difference of 0.9 V is generated between the aluminum fine particles 21 and the zinc fine particles 22 as shown in Table 1.

  The melting temperature of metallic aluminum is 660 ° C., and the melting temperature of zinc is about 420 ° C. Therefore, for example, when thermal spraying is performed with an electric mark of 1000 ° C., both aluminum and zinc are instantaneously melted, and the molten metal is sprayed in a mist form by a high-speed air flow generated by compressed air. Therefore, when the nonwoven fabric 15 having the adhesive layer 16 is disposed so as to be exposed to the air flow, the metal fine particles 21 and 22 are adhered and fixed to the surface of the nonwoven fabric 15. Instead of such a configuration, one of the metal fine particles 22 made of zinc, for example, may first be attached to the nonwoven fabric 15 and then the metal fine particles 21 made of aluminum may be attached thereafter.

  Due to the adhesion of the metal fine particles 21 and 22 to the nonwoven fabric 15 by thermal spraying, the metal aluminum melts and penetrates around the metal zinc fine particles 22, and further bonds with oxygen at a high temperature, and is a special oxide film harder than alumite. Form. This oxide film has an electrically high insulating property and becomes an insulating film. Moreover, such an insulating coating 23 is formed at the interface between the two metal fine particles 21 and 22, as shown in an enlarged view in FIG. Note that the thickness of the insulating coating 23 is 1000 mm or less. A dry battery is formed by the aluminum fine particles 21 and the zinc fine particles 22 having different ionization tendencies with the insulating coating 23 interposed therebetween. That is, the particulate metal sprayed in the form of a mist forms a dry battery using both metals 21 and 22 as electrodes. The metal fine particles 21 and 22 attached so as to be struck against the nonwoven fabric 15 form several tens of dry batteries per particle. And the metal fine particles 21 and 22 adhering to the nonwoven fabric 15 are innumerable quantities, and therefore, countless dry batteries are formed on the surface of the nonwoven fabric 15. In such a dry battery, as shown in FIG. 12, a potential difference of about 0.9 V is generated due to the ionization tendency, and a current flows between both electrodes as shown in FIG. 12 due to such a potential difference. Such an electric current instantly destroys the microorganism.

  As shown in FIG. 13, fine microorganisms such as viruses carry a control current for controlling ecosystems in their bodies, and the microorganisms maintain their life activities by such control currents. However, the current from the dry battery formed on the nonwoven fabric 15 is a direct current that far exceeds the voltage of the control current. Such direct current makes it impossible to control the microorganism, and the microorganism cannot maintain its life and die. That is, here, sterilization is performed by dying microorganisms by applying a DC voltage much higher than the control current of the ecosystem.

  In general, the conventional bactericidal action has not occurred unless the microorganisms are in direct contact with the drug. On the other hand, the sterilization sheet 10 used in the mask of the present invention is an electric current that flows due to a potential difference generated between the two kinds of metal fine particles 21 and 22 even if the target microorganism is not in direct contact, and is easy even in the air. Will be killed. Therefore, it is possible to sterilize harmful microorganisms such as influenza virus by a principle completely different from the sterilizing action using conventional chemicals.

  The bactericidal action using the two kinds of metal fine particles 21 and 22 as described above reacts with moisture, carbon dioxide gas, or water in the air and has the energy to hydrolyze without using an external DC power source. This strong electrical energy is thought to sterilize bacteria and viruses.

  A battery composed of two kinds of metal fine particles 21 and 22 reacts with moisture and carbon dioxide gas, and the zinc metal fine particles 22 are slowly dissolved. Therefore, the period of use is in units of years, and the service life of the bactericidal mask is kept long. In vacuum, it can be stored for several tens of years. Therefore, when storing a mask for emergencies, storing it in a vacuum pack allows it to be stored stably for a long period of time while preventing moisture and carbon dioxide from being blocked and preventing metallic zinc from melting. become able to.

  In addition, influenza viruses have the property of preventing their growth when humidity is high. Therefore, in order to increase the humidity inside the mask by using the humidity of the air and suppress the growth of the virus, a moisture retention sheet 11 is used as shown in FIGS. 1A and 1B. The moisturizing sheet 11 protects against invading microorganisms and promotes sterilization. In addition, as such a moisture retention sheet | seat 11, vegetable cotton or a chemical fiber cotton is used suitably.

  The laminated structure of the sterilizing sheet 10 and the moisturizing sheet 11 as shown in FIG. 1A or FIG. 1B is housed inside the outer cover. Therefore, the lips and nose do not come into direct contact with the laminated structure shown in FIG. Further, as shown in FIG. 6, the sterilization sheet 10 has a structure in which notches 30 are appropriately formed in the peripheral portion thereof to eliminate gaps for invasion or release of microorganisms and to improve the flexibility and fit of the mask. In addition, the cut 30 can be adjusted in length according to the mounting site, and by avoiding a sudden change in length, the mask 30 can be slightly shifted laterally to eliminate the mask gap and prevent invasion of microorganisms. It becomes like this.

The result of having tested about the influenza virus activity of the sterilization sheet | seat 10 used for the mask of this invention is shown in Table 2 and FIG. G in Table 2 is a 3 cm ² non-woven fabric formed by spraying aluminum and zinc at the same time, added 100 μl of influenza virus solution, sealed in a 15 ml centrifuge tube and allowed to stand at room temperature (25 ° C.). It is a result of measuring the amount of virus in the supernatant after adding 2 ml of liquid medium at the time in the table, vortexing, and centrifuging at 3000 rpm for 15 minutes. C (no cloth) is 100 ml of the same influenza virus solution as G above, sealed in a 15 ml centrifuge tube and allowed to stand at room temperature (25 ° C). After that, the amount of virus was measured by the same treatment as G. is there. C (with cloth) is a 3 cm ² non-woven fabric added with 100 μl of the same influenza virus solution as G, sealed in a 15 ml centrifuge tube and allowed to stand at room temperature (25 ° C.). It is the result of measuring the viral load. In addition, for G, C (no cloth) and C (with cloth), about 10 ⁶ PFU / 100 μl of influenza virus (PR-8 strain) is added per 3 cm ² non-woven fabric, and the infectious titer is used. The virus activity is evaluated.

  Table 2 shows the results of the influenza virus activity evaluation when C (with cloth) at each time is 100%. Moreover, the number in this table | surface is a virus Plaque formation rate (%).

  FIG. 14 is a graph showing the results of Table 1 above. As is apparent from this result, it is clearly proved that the sterilization sheet 10 of the present embodiment has a high sterilization performance especially against influenza viruses.

  Although the present invention has been described above with reference to the illustrated embodiments, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the technical idea of the present invention. For example, the laminated structure of the sterilizing sheet 10 and the moisturizing sheet 11 in the above embodiment is not necessarily limited to the structure shown in FIG. Further, the combination of the metal fine particles supported on the sterilization sheet is not necessarily limited to the combination of aluminum and zinc, and other metals that generate a potential difference due to a difference in ionization tendency can be used. .

  The present invention can be used as a mask excellent in sterilizing performance of microorganisms such as influenza virus.

It is sectional drawing which shows the combination of the disinfection sheet | seat and moisturizing sheet which are distribute | arranged inside the mask. It is sectional drawing which shows carrying | support of the metal microparticle on a nonwoven fabric. It is a longitudinal cross-sectional view which shows the assembly of the sterilization sheet using two nonwoven fabrics. It is a longitudinal cross-sectional view which shows the assembly of another sterilization sheet | seat using two nonwoven fabrics. It is sectional drawing which shows the combination of the cover sheet with respect to a disinfection sheet | seat. It is a top view which shows arrangement | positioning of the cut with respect to a disinfection sheet | seat. It is an external appearance perspective view of the mask of one Example. It is the front view seen from the outside of the mask. It is the front view seen from the inner side of the same mask. It is sectional drawing of the laminated structure (A) of the cross section of a mask, and the laminated structure of a sterilization sheet. It is an expanded sectional view which shows arrangement | positioning of a metal microparticle and an insulating film. It is an expanded sectional view which shows the flow of the electric current produced with two metals. It is a graph which shows the change of the voltage with respect to time. It is a graph which shows the activity with respect to influenza virus.

Explanation of symbols

10 Sterilization sheet 11 Moisturizing sheet 15 Non-woven fabric 16 Adhesive layer (hot melt adhesive)
21 Fine metal particles (aluminum)
22 Fine metal particles (zinc)
23 Insulation coating 25 Non-woven fabric (cover sheet)
26 Adhesive layer 30 Notch 35 Mask 36 Rubber band 37 Coupling part 38 Peripheral weld part 39 Metal plate 40 Sponge pad 42 Outer cover 43 Adhesive layer 44 Inner sheet 45 Adhesive layer

Claims (13)

In a mask that covers the nose and mouth to prevent inhalation or / and release of pathogens,
It has a breathable sterilization sheet, and the sterilization sheet carries two kinds of metal fine particles having different ionization tendencies, the two kinds of metal fine particles are in contact with each other through an insulating film, and an infinite number of minute particles are placed on the sterilization sheet. A mask characterized in that a simple battery is formed.   The mask according to claim 1, wherein the base material of the breathable sterilization sheet is a nonwoven fabric.   2. The mask according to claim 1, wherein an air-permeable adhesive layer is formed on a surface of the air-permeable sheet, and the metal fine particles are supported through the adhesive layer.   The metal fine particles are supported on the surface of the pressure-sensitive adhesive layer formed on the breathable sheet or the surface of the sheet opposite to the surface on which the pressure-sensitive adhesive layer is formed. The mask described in 1.   The mask according to claim 3, wherein a cover sheet having an adhesive layer formed on a surface thereof is bonded to a surface of the sterilizing sheet on which the metal fine particles are supported.   The breathable sterilization sheet is formed by joining two nonwoven fabrics, an adhesive layer is formed on one surface of the nonwoven fabric, the metal fine particles are supported on the surface of the adhesive layer, and the metal particulates are supported. The mask according to claim 1, wherein the pressure-sensitive adhesive sheet is formed by bonding the pressure-sensitive adhesive layers to each other.   The breathable sterilization sheet is formed by joining two nonwoven fabrics, and an adhesive layer is formed on one surface of the nonwoven fabric, the metal fine particles are supported on the other surface, and the adhesive layers are bonded to each other. The mask according to claim 1, wherein the sterilizing sheet is formed by bonding.   The mask according to claim 7, wherein a cover sheet having an adhesive layer formed on a surface thereof is joined to a surface of the sterilizing sheet on which the metal fine particles are supported.   2. The mask according to claim 1, wherein the two kinds of metal fine particles are carried on a sterilizing sheet by thermal spraying.   2. The mask according to claim 1, wherein the two kinds of metal fine particles are aluminum and zinc.   The mask according to claim 1, wherein the mask is composed of a hot-melt adhesive that exhibits adhesiveness when the adhesive layer is heated.   The mask according to claim 1, further comprising a moisturizing sheet that absorbs and retains moisture from the intake air, and the moisturizing sheet is bonded to the sterilizing sheet or sandwiched between two sterilizing sheets.   The mask according to claim 1, wherein a notch is formed to prevent a gap from being generated when the sterilizing sheet is attached to a peripheral portion.

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