JP2011042615A - Antiviral substance, antiviral fiber and antiviral fiber structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an antiviral substance effective for inactivating viruses, a fiber product carrying an antiviral substance and a fiber structure. <P>SOLUTION: The antiviral substance is a polymer comprising a copolymer component of a styrene or an α-olefin and (meth)acrylic acid in the polymer chain. The polymer carries an ion of metal selected from copper, silver, zinc and nickel and is effective for avian influenza viruses. The antiviral fiber obtained by spinning or carrying the polymer of the antiviral substance is effectively inactivating viruses. The antiviral fiber product comprising the antiviral fiber at least partially is formed into, for example, clothing, bedding, curtain, wallpaper, carpet, mat, sheet, filter, mask, wiper, towel, protective clothing, protective net, waste chicken bag, poultry house article or sheet for medical use, and used. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an antiviral substance comprising a polymer effective against viruses and a fiber having an antiviral function.

  In recent years, viral diseases such as SARS (Severe Acute Respiratory Syndrome) and avian influenza have been rampant worldwide. In particular, new influenza viruses have been discovered one after another, which poses a threat to humankind. Originally, the host range of viruses is limited, and it is normal that only mammals infect mammals and only birds infect birds. However, since avian influenza virus is a virus with a wide host range that can infect not only birds but also mammals, it may infect humans. At present, H5N1 influenza is prevalent in Asia and Europe, and there are concerns about the emergence of new human influenza based on it.

  In addition, since bird flu viruses are transported to remote areas by migratory birds, imports from countries with diseases such as food cannot be stopped and entry into the country cannot be prevented by quarantine alone.

  An agent for inactivating such an influenza virus is disclosed in Patent Document 1. This influenza virus inactivating agent is a solution containing iodine and β-cyclodextrin.

  In Patent Document 2, a crosslinked acrylic fiber is used as a fiber having a crosslinked structure and having a carboxyl group in the molecule, and fine particles of metal and / or metal compound that are hardly soluble in water are dispersed in the fiber. Antiviral fibers are disclosed. However, although the virus is in contact with the fine particles of the metal and / or metal compound that are sparingly soluble in the water finely dispersed in the fiber to obtain a virus inactivating effect, this method provides a sufficient virus inactivating effect. It is considered that the effect is reduced unless it is made into a moisture atmosphere.

Patent Document 3 discloses a sterilizing filter formed by dipping a nonwoven fabric in polyacrylic acid and drying it. In this filter, polyacrylic acid COO ⁻ and H ⁺ are ionized, and bacteria and viruses are adsorbed at this position.

JP 2006-328039 A International Publication No. 2005/083171 JP 2005-125141 A

  In view of the fact that it is extremely difficult to completely eliminate the outbreak of influenza as described above, the present invention inactivates viruses much smaller than the size of bacteria such as staphylococci and gram-negative bacteria. An object is to provide an effective antiviral substance, a fiber carrying an antiviral substance, a fiber structure, and a textile product.

  The antiviral substance of the present invention is a polymer containing a copolymer component of styrene or α-olefin and (meth) acrylic acid in a polymer chain, and the polymer is copper, silver, zinc, nickel It is characterized by carrying metal ions selected from

  The antiviral fiber of the present invention contains a copolymer component of styrene or α-olefin and (meth) acrylic acid in the polymer chain, and the copolymer component is selected from copper, silver, zinc, and nickel. And an antiviral substance composed of a polymer carrying metal ions as an active ingredient.

  The antiviral fiber structure of the present invention is characterized in that the antiviral fiber is contained at least in part.

  The antiviral fiber product of the present invention includes at least a part of the antiviral fiber, and includes clothing, bedding, futon, curtain, wallpaper, carpet, mat, sheets, filter, mask, wiper, towel, protective clothing, protective net, It is formed into waste chicken bags, poultry house supplies, and medical sheets.

  The antiviral substance of the present invention is effective for inactivating viruses. Further, the antiviral fiber of the present invention in which the polymer of the antiviral substance of the present invention is spun or supported is effective for inactivating viruses. Furthermore, the antiviral fiber of the present invention is processed into a fiber product to constitute the fiber structure of the present invention. The antiviral fiber structure has a high inactivation effect on the virus in contact.

  The antiviral substance of the present invention is a polymer containing a copolymer component of styrene or α-olefin and (meth) acrylic acid in a polymer chain, and the polymer is copper, silver, zinc, nickel It is characterized by carrying metal ions selected from The present inventor has found that the polymer supporting the metal ions has a virus inactivating effect.

  This antiviral substance has an inactivating effect against various viruses. In the present invention, the viruses that are the target of the inactivation effect include all viruses regardless of the kind of genome and the presence or absence of an envelope. Examples of viruses having DNA as a genome include herpes virus, smallpox virus, cowpox virus, chicken pox virus, adenovirus and the like, and viruses having RNA as a genome include measles virus, influenza virus, coxsackie virus, calicivirus. (Norovirus genus), retrovirus (lentivirus genus such as HIV (human immunodeficiency virus)), coronavirus and the like. Among these viruses, viruses having an envelope include herpes virus, smallpox virus, cowpox virus, chicken pox virus, measles virus, influenza virus, etc., and viruses having no envelope include adenovirus, Examples include Coxsackie virus and Norovirus.

  The reason why this antiviral substance has an inactivating effect on the virus is presumed to be because it inhibits the activity of protrusion HA (hemagglutinin) and NA (neuramitase) on the virus surface against influenza virus. In other viruses, it is presumed to inhibit the activity of protrusions on the surface of the virus or directly destroy virus particles.

  The antiviral substance has a high inactivating effect on the avian influenza virus, and is particularly effective for highly pathogenic avian influenza viruses having strong toxicity such as H5 or H7 subtypes. In the present invention, the antiviral effect has been demonstrated for the avian influenza virus A / whistling swan / Shimane / 499/83 (H5N3) strain, but it is also considered effective for avian influenza viruses such as H5N1 and H9N2 . It is also considered effective for human influenza virus and swine influenza virus.

  In the polymer chain, a polymer containing a copolymer component of styrene or α-olefin and (meth) acrylic acid (hereinafter also referred to as “polymer containing (meth) acrylic acid component”) is originally It is used as a sizing agent for papermaking for the purpose of suppressing the penetration of liquid such as ink to paper and preventing set-off and bleeding. It was found that when a predetermined metal ion is supported on this polymer, the protein is denatured and has an inactivating effect on the virus. The polymer containing the (meth) acrylic acid component has a hydrophobic group and a hydrophilic group. Monomers having a hydrophobic group include styrenes such as styrene, α-methylstyrene, vinyltoluene, or carbon. Examples thereof include linear or branched α-olefins having 2 to 22, preferably 6 to 22 carbon atoms, and one or more of these monomers are copolymerized and used. The monomer having a hydrophobic group is preferably 30 to 90 mol% in the copolymer. More preferably, it is 50-90 mol%.

  Examples of the hydrophilic group of the polymer containing the (meth) acrylic acid component include a polymer compound containing (meth) acrylic acid. In addition, "(meth) acrylic acid" in this specification means methacrylic acid and / or acrylic acid. Specific monomers having hydrophilic groups include (meth) acrylic acid N, N-dimethylaminomethyl ester, (meth) acrylic acid N, N-dimethylaminoethyl ester, (meth) acrylic acid N, N-dimethyl One or more of aminopropyl ester, (meth) acrylic acid N, N-diethylaminomethyl ester, (meth) acrylic acid N, N-diethylaminoethyl ester, (meth) acrylic acid N, N-diethylaminopropyl ester (Meth) acrylic acid N, N-dialkylaminoalkyl ester, or its epihalhydrin modified product, (meth) acrylic acid N, N-dialkylaminoalkyl ester non-crosslinked quaternized product having no epihalohydrin group, methyl (Meth) acrylate, butyl (meth) acrylate, 2-ethylhexyl (meth) a Examples include (meth) acrylic acid alkyl esters such as relate, 2-hydroxyethyl (meth) acrylate, lauryl (meth) acrylate, and stearyl (meth) acrylate, and one or more of these (meth) acrylic monomers are included. It is used after being copolymerized. The monomer having a hydrophilic group is preferably 70 to 10 mol% in the copolymer. More preferably, it is 50-10 mol%.

  As a preferred form of the polymer containing the (meth) acrylic acid component used in the present invention, a styrene-acrylic acid polymer is shown as an example.

  The polymer containing a (meth) acrylic acid component used in the present invention can be easily obtained by solution polymerization or bulk polymerization of a mixed monomer of a monomer having a hydrophobic group and a monomer having a hydrophilic group. . The polymerization method is not particularly limited, and conventionally known conditions can be employed as they are. As a solvent in the solution polymerization method, isopropyl alcohol, toluene, benzene, methyl isobutyl ketone and the like can be used. Subsequently, a polymer mixed solution can be obtained by adding a predetermined amount of water to the polymer as the obtained copolymer. The solid content concentration of the polymer mixed solution is not particularly limited, but is usually about 20 to 40%, and it can be diluted as appropriate. The polymer may be copolymerized with a small amount of a third component other than the above-described monomer within a range not impairing the function of the present invention.

  Specifically, “Polymalon” manufactured by Arakawa Chemical Industries, Ltd. is preferable as the polymer mixture. This polymer mixture is in the form of a light brown or light yellow transparent liquid, a turbid liquid, or an emulsion, and preferably has a viscosity of 100 to 5000 mPa · s. With such a viscosity, mixing into viscose, which will be described later, or application to a carrier is easy. In addition, the pH of the polymer mixed solution is preferably 7 to 11, and more preferably 8.5 to 10.5.

  In the antiviral substance of the present invention, at least one metal ion selected from copper, silver, zinc, and nickel is supported on a polymer containing a (meth) acrylic acid component. A polymer emulsion containing a (meth) acrylic acid component is mixed with a solution containing a metal ion selected from copper, silver, zinc and nickel, or a polymer containing a (meth) acrylic acid component is organic or inorganic. After being supported on the carrier, it is immersed in a solution containing a metal ion selected from copper, silver, zinc, nickel, etc., and subjected to processing such as coating to select from copper ion, silver ion, zinc ion, and nickel ion At least one metal ion. As the metal ion, copper ions have a high antiviral effect and are particularly preferable.

  The polymer containing the (meth) acrylic acid component can be supported on or mixed with an organic or inorganic carrier. The content of the polymer containing the (meth) acrylic acid component in the carrier is not particularly limited as long as it can be supported or mixed on the carrier and can exhibit an antiviral effect. The polymer containing the (meth) acrylic acid component is preferably 0.1 to 100 parts by mass. The content of the polymer containing the (meth) acrylic acid component is more preferably 0.5 to 60 parts by mass.

  The antiviral substance of the present invention is preferably carried on a cellulose material as the organic carrier. Cellulose materials tend to exhibit antiviral effects because of their good water absorption. In particular, when a metal ion selected from copper, silver, and zinc, which will be described later, is supported, it is important to hold the carrier in a + ion or -ion state, and the cellulose material that can hold moisture Is advantageous. Cellulose material is processed into the form of a fiber, sponge, etc., for example.

  As the organic carrier, fibers are particularly preferable. Since the fiber is bulky and has a large surface area, the polymer containing the (meth) acrylic acid component efficiently contacts viruses in the air.

  Examples of the fiber material include cellulosic fibers (cotton, hemp, rayon, pulp, etc.), protein fibers (wool, silk, etc.), polyamide fibers, polyester fibers, polyacrylic fibers, polyvinyl alcohol fibers, polychlorinated fibers. Any natural fiber such as vinyl fiber, polyvinylidene chloride fiber, polyolefin fiber, and polyurethane fiber, recycled fiber, semi-synthetic fiber, and synthetic fiber are used. Among these, cellulosic fibers are advantageous as well as the reason why the cellulose material is preferable. Cellulosic fibers do not accumulate dust due to static electricity unlike synthetic fibers, so that the reaction sites are not blocked by dust, and can exhibit a more antiviral effect. In particular, rayon has good water absorption and can easily adjust the fineness and fiber length, so that it can be applied to various fiber structures and fiber products.

  A polymer solution containing a (meth) acrylic acid component, for example, a styrene- (meth) acrylic acid copolymer solution is a metal-containing alkali such as a viscose solution of cellulose obtained by a known method or a copper ammonia solution of cellulose. The mixed solution dissolved and mixed with the solution is discharged into a spinning solution through a spinning nozzle, and a rayon fiber in which a polymer containing a (meth) acrylic acid component is mixed into the fiber can be obtained by so-called wet spinning.

  The mixing ratio of the cellulose and the polymer containing the (meth) acrylic acid component is preferably about 60 to 99% by mass for the former and about 40 to 1% by mass for the latter. When the ratio of cellulose used is less than 60% by mass, the resulting cellulose composition may have a sticky feeling on the surface, and disadvantages such as blocking may occur in subsequent processes such as weaving and compositing. On the other hand, if it exceeds 99% by mass, the antiviral effect due to the use of the polymer containing the (meth) acrylic acid component may be lowered.

  The antiviral fiber of the present invention is a fiber carrying a polymer containing a (meth) acrylic acid component, which is subjected to processing such as immersion and coating in a solution containing metal ions selected from copper, silver, zinc and nickel. Thus, at least one metal ion selected from copper ions, silver ions, zinc ions, and nickel ions is supported.

For example, as a method for supporting copper ions on a fiber supporting a polymer containing a (meth) acrylic acid component, it is immersed in a solution such as copper sulfate (CuSO ₄ ) or copper nitrate (Cu (NO ₃ ) ₂ ). Thus, copper ions can be adsorbed. As a method for supporting zinc ions, for example, the zinc ions can be adsorbed by being immersed in a zinc chloride (ZnCl ₂ ) solution. As a method for supporting nickel ions, for example, the nickel ions can be adsorbed by being immersed in a nickel chloride (NiCl ₂ ) solution.

  The antiviral fiber can be added to, for example, a sheet-like product, a resin molded product, an inorganic molded product, or the like. Moreover, it can adhere | attach on a sheet-like material, a resin molding, an inorganic molding, etc. using a binder etc. together.

  The cross-sectional shape of the antiviral fiber is not particularly limited, and may be any of circular, irregular, hollow and the like. Further, the fiber length of the antiviral fiber is not particularly limited, and may be any of long fiber, short fiber, fine fiber, and the like. If it is a long fiber, it can be obtained by winding the fiber around a bobbin or the like after spinning. If it is a short fiber, it can be cut into a predetermined fiber length with a cutter or the like, or if it is a natural fiber, it can be used as it is. If it is a fine fiber, it can be obtained by grinding and grinding with a grind mill or the like, and classifying through a sieve having an arbitrary mesh. The fine fibers ground and cut are moderately curved. Furthermore, the fineness of the antiviral fiber is not particularly limited, and may be appropriately selected depending on the application.

  The antiviral fiber structure of the present invention can be used by forming the antiviral fiber at least in part and forming it into yarn, woven or knitted fabric, web, nonwoven fabric, paper, net or the like. Moreover, it is good also as a lamination sheet laminated | stacked with other sheets, such as the said fiber structure and a film.

  Hereinafter, a specific antiviral fiber structure will be described. When obtaining the antiviral fiber structure of the present invention with yarn, (1) spinning or supporting a polymer in which a metal ion such as copper, silver, zinc or the like is first supported on a (meth) acrylic acid component as an antiviral substance A method for producing a yarn containing an antiviral fiber at least partially after obtaining the obtained fiber, and (2) spinning or carrying a polymer containing a (meth) acrylic acid component as an antiviral substance. After obtaining a fiber and producing a yarn containing at least a part of an antiviral fiber, (meth) acrylic acid component is loaded with metal ions such as copper, silver, zinc, or (3) by a known method After producing the yarn, a method in which a polymer in which a metal ion such as copper, silver, or zinc is supported on the (meth) acrylic acid component is supported on the fiber surface can be employed. The above-described yarn can be obtained by a known method for producing spun yarn or multifilament yarn.

  When the antiviral fiber structure of the present invention is obtained with a woven or knitted fabric, (1) a polymer in which a metal ion such as copper, silver, zinc or the like is previously supported on a (meth) acrylic acid component as an antiviral substance is spun or A method of obtaining a supported fiber and making it an antiviral fiber, and then weaving a yarn containing a predetermined antiviral fiber and dyeing it as necessary to produce a woven or knitted fabric. (2) As an antiviral substance ( A fiber containing a polymer containing a (meth) acrylic acid component is spun or supported, and a yarn containing at least a part of an antiviral fiber is produced and woven, and then dyed as necessary to obtain a (meth) acrylic acid component. A method of supporting metal ions such as copper, silver, zinc and the like, (3) Short fibers previously cut into 5 mm or less of antiviral fibers, or finely pulverized fibers are supported on the fiber surface constituting the woven or knitted fabric by a binder. How to It is possible to take. The woven or knitted fabric described above can be obtained by a known method for producing woven or knitted fabric.

  When the antiviral fiber structure is obtained from a web, non-woven fabric, paper, or net, it can be obtained by the same method as the processing of the woven or knitted fabric.

  The antiviral fiber is included at least in part, for example, clothing (including hats, gloves, handkerchiefs), futons, curtains, wallpaper, carpets, mats, sheets, filters, masks, wipers, towels, protective clothing, protective nets. It is possible to inactivate viruses that are used in daily life as textile products such as waste chicken bags and poultry house supplies, and that are scattered and suspended in the living space.

  Hereinafter, the antiviral fiber structure and antiviral fiber product of the present invention will be specifically exemplified. When the antiviral fiber structure of the present invention is a nonwoven fabric, the fiber web may be formed by a card method, an airlaid method, a wet papermaking method, a spunbond method, a melt blown method, a flash spinning method, an electrostatic spinning method, or the like. it can. The obtained fiber web is processed into a thermal bond nonwoven fabric such as an air-through nonwoven fabric or a thermocompression bonded nonwoven fabric, a chemical bond nonwoven fabric, a needle punched nonwoven fabric, a hydroentangled nonwoven fabric, a spunbond nonwoven fabric, or a melt blown nonwoven fabric.

  For example, when an antiviral fiber in which an antiviral substance is mixed or supported in advance is used, the fiber web may be 100% by mass of the antiviral fiber, but may be mixed with other antiviral fibers or antiviral. You may mix with another fiber within the range in which an effect is acquired. When mixed with other fibers, the antiviral fiber is preferably at least 20% by mass. More preferably, it is at least 30% by mass. Even more preferably, it is 50 mass% or more. The fiber web obtained in this manner can be subjected to predetermined processing to obtain a nonwoven fabric. Moreover, a metal ion can also be carry | supported by the method mentioned above to the obtained fiber web or a nonwoven fabric.

  For example, when a fiber (hereinafter also referred to as a carrier fiber) is prepared, a fiber web is prepared, processed into a nonwoven fabric, and then loaded with an antiviral substance, the fiber web is 100% by mass of the carrier fiber. However, it may be mixed with other antiviral fibers, or may be mixed with other fibers within a range where an antiviral effect can be obtained. When mixed with other fibers, the carrier fibers are preferably at least 20% by mass. More preferably, it is at least 30% by mass. Even more preferably, it is 50 mass% or more. Moreover, a metal ion can also be carry | supported by the method mentioned above to the obtained fiber web or a nonwoven fabric. As described above, when antiviral substances and / or metal ions are carried on the fiber web or the nonwoven fabric in the post-processing, when the other sheet is laminated and integrated with the nonwoven fabric, for example, the strength of the nonwoven fabric can be greatly increased and the production speed can be increased. The handling property at the time of processing such as is good and preferable. As other sheets, spunbond nonwoven fabric, melt blown nonwoven fabric, unidirectional stretched arrayed fiber nonwoven fabric in which filaments are aligned and stretched in one direction, and background-orthogonal laminated fiber nonwoven fabric laminated so that the array directions of filaments are orthogonal to each other, Examples include wet papermaking, nets, films, and woven and knitted fabrics. In particular, a spunbond nonwoven fabric, a unidirectionally stretched fiber nonwoven fabric, and a history-orthogonal laminated fiber nonwoven fabric are preferably used as a reinforcing layer because the strength of the nonwoven fabric after lamination can be increased.

  An example of a thermal bond nonwoven fabric is shown as an antiviral fiber structure of the present invention. The antiviral fiber of the present invention, the heat-adhesive fiber, and other antiviral fibers as necessary, and other fibers are mixed to form a fiber web, which is heat-treated at a temperature at which the heat-adhesive fiber is thermally bonded. A thermal bond nonwoven fabric can be obtained. Examples of the heat-bonding fibers include polymers such as polyethylene terephthalate, polybutylene terephthalate, polytrimethylene terephthalate, and polylactic acid terephthalate, polyamides such as nylon 6, nylon 66, polyolefins such as polypropylene, polyethylene, and polybutene, and polymers or co-polymers. Single component fibers or composite fibers in which the polymer is at least partially exposed on the fiber surface can be used.

  An example of a chemical bond nonwoven fabric is shown as an antiviral fiber structure. First, the antiviral fiber of the present invention is mixed with other antiviral fibers and other fibers as necessary to form a fiber web. If necessary, after forming the fibrous web into a non-woven fabric (eg, needle punched non-woven fabric), a binder is applied by dipping, spraying (eg, spray bonding), coating (eg, foam bonding), etc., and drying and / or curing It can ring and a chemical bond nonwoven fabric can be obtained. As the binder, an acrylic binder, a urethane binder, or the like can be used. The adhesion amount of the binder is not particularly limited as long as the form of the nonwoven fabric can be maintained and the antiviral effect is not inhibited. For example, it is preferable that it is 5-50 mass% by solid content with respect to the nonwoven fabric mass.

  An example of hydroentangled nonwoven fabric is shown as an antiviral fiber structure. First, the antiviral fiber of the present invention is mixed with other antiviral fibers and other fibers as necessary to form a fiber web. Other sheets can be laminated on the fiber web as required. Examples of other sheets include spunbonded nonwoven fabrics, meltblown nonwoven fabrics, unidirectionally stretched arrayed fiber nonwoven fabrics, wefted laminated fiber nonwoven fabrics, wet papermaking, nets, films, and woven and knitted fabrics. In particular, a spunbond nonwoven fabric, a unidirectionally stretched fiber nonwoven fabric, and a history-orthogonal laminated fiber nonwoven fabric are preferably used as a reinforcing layer because the strength of the nonwoven fabric after lamination can be increased. For example, an orifice having a hole diameter of 0.05 mm or more and 0.5 mm or less is provided on the fiber web or the laminated sheet from a nozzle provided with an interval of 0.5 mm or more and 1.5 mm or less. It can be obtained by injecting fibers 1 to 4 times each from the front and back sides of the web to entangle the fibers.

  In the antiviral fiber structure of the present invention, if waterproofness is required, a waterproof film is laminated on the surface of the antiviral fiber structure, or a resin is laminated using an extrusion laminating machine, etc. An antiviral fiber structure having the following can be obtained. When moisture permeability and waterproof properties are required, an antiviral fiber structure having moisture permeability and waterproof properties can be obtained by laminating ultrafine fiber nonwoven fabrics such as melt blown nonwoven fabrics or laminating moisture permeable resins. .

  Such a waterproof and moisture-permeable waterproof antiviral fiber structure can be used for medical sheets such as hospital bed sheets, hospital curtains, surgical sheets, and experimental sheets.

The thermal bond nonwoven fabric, chemical bond nonwoven fabric, and hydroentangled nonwoven fabric can be used, for example, in an air filter. When used in an air filter, the fineness of the fibers constituting the medium coarse dust filter is preferably 2 to 50 dtex. The basis weight is preferably 10 to 150 g / m ² . The air filter thus obtained can be used as a filter for home appliances such as an air conditioner, an air cleaner, and a vacuum cleaner. For example, a filter for an air purifier has a laminated structure of a support such as a chemical bond nonwoven fabric, an antiviral fiber structure, and a high-accuracy filter layer such as an electret nonwoven fabric, HEPA, or ULPA, and is pleated. A processed sheet is used.

The antiviral fiber structure of the present invention can also be used for masks such as sanitary masks, surgical masks, dust masks (for example, N95 compatible masks (Particulate Respirator Type N95), respiratory protection equipment). Examples of the antiviral fiber structure that can be used for the mask include the thermal bond nonwoven fabric and hydroentangled nonwoven fabric. The fineness of the antiviral fiber that can be used for the mask is preferably 1 to 10 dtex. More preferably, it is 2-8 dtex. The basis weight is preferably 20 to 60 g / m ² . As the constitution of the mask, for example, from the outside to the mouth side, a reinforced nonwoven fabric (for example, spunbond nonwoven fabric, thermal bond nonwoven fabric) / antiviral nonwoven fabric of the present invention / ultrafine fiber nonwoven fabric (for example, meltblown nonwoven fabric) / reinforced or flexible nonwoven fabric ( For example, when a laminated structure of a spunbond nonwoven fabric or a thermal bond nonwoven fabric is used, the antiviral performance can be effectively exhibited.

  As another example of the antiviral fiber structure of the present invention, a short fiber obtained by cutting an antiviral fiber to 5 mm or less or a fine fiber (hereinafter collectively referred to as fiber powder) supported on another fiber surface is supported. Non-woven fabric. Thus, the antiviral fiber made into fiber powder can be carry | supported on the surface of another fiber with a binder. As a method for supporting the antiviral fiber powder with a binder, for example, a predetermined amount of antiviral fiber powder and a binder (for example, acrylic binder, urethane binder, etc.) are added to prepare a binder solution, The binder solution can be applied by dipping, spraying (for example, spray bonding), coating (for example, knife coater, gravure coater), etc., and dried and / or cured to obtain an antiviral fiber powder-carrying nonwoven fabric. As another method, an antiviral fiber powder is prepared by preparing an aqueous dispersion of antiviral fiber powder and immersing, spraying, coating, etc. the aqueous dispersion in a fiber structure containing heat-adhesive fibers or wet heat-adhesive fibers. After adhering, the antiviral fiber powder-supporting nonwoven fabric can be obtained by heat treatment and adhering the powder with heat-adhesive fibers or wet heat-adhesive fibers.

  As said fiber base fabric, nonwoven fabrics, such as a thermal bond nonwoven fabric, a spun bond nonwoven fabric, a hydroentangled nonwoven fabric, and a woven / knitted fabric can be used, for example.

  The antiviral fiber powder-supporting nonwoven fabric can be used for protective clothing, for example. The non-woven fabric can be cut into a predetermined shape, and the end portions of the non-woven fabric can be overlapped to perform heat sealing, ultrasonic sealing, high-frequency sealing, or sewing.

  A specific example is shown when the antiviral fiber structure of the present invention is a woven or knitted fabric. First, an antiviral fiber that spins or carries a polymer containing a (meth) acrylic acid component as an antiviral substance is used, and then a yarn containing a predetermined antiviral fiber is woven. The obtained woven or knitted fabric is used in a dyeing machine such as a zicker dyeing machine, a high-pressure liquid dyeing machine, or a paddle dyeing machine, and 0.05 to 5 parts by mass, ie 0.05 to 5% owf, with respect to 100 parts by mass of fibers. Immerse the woven or knitted fabric in a solution containing a metal ion compound (on weight fiber) (for example, an aqueous copper sulfate solution), wash it with water, dry it, and drip acrylic resin or urethane resin, etc., if necessary. It is possible to obtain an antiviral woven or knitted fabric in which a metal ion such as copper, silver, or zinc is supported on the (meth) acrylic acid component.

  The antiviral woven or knitted fabric thus obtained can be used for, for example, clothing, futons, curtains, carpets, mats, sheets, towels, protective clothing, protective nets, waste chicken bags, poultry house supplies, medical sheet materials, etc. it can.

  Examples of the present invention will be described in detail below, but the scope of the present invention is not limited to these examples.

[Production of antiviral fiber]
Example 1
A mixture of styrene-acrylic acid copolymer (manufactured by Arakawa Chemical Industry Co., Ltd., trade name “Polymalon 356-25”, light brown transparent liquid) was added to the viscose solution of cellulose (cellulose concentration 8.5%). The polymer solid content was added and dissolved so as to be 10 parts with respect to 100 parts of cellulose solid content. Each mixed solution was spun by extrusion from a platinum nozzle in a strongly acidic bath of sulfuric acid 100 g / l, zinc sulfate 15 g / l, and sodium sulfate 350 g / l. A sample of viscose rayon fiber mixed with a styrene-acrylic acid copolymer was obtained by desulfurization and scouring bleaching by a conventional method. The fineness was 1.4 dtex, and the fiber length was 38 mm.

  The obtained viscose rayon fiber was immersed in a 0.16% aqueous copper sulfate solution and allowed to stand for 5 minutes, then washed with distilled water and dried at 80 ° C. for 1 hour to obtain a sample of antiviral fiber. The copper loading of this antiviral fiber was 0.325% by mass.

(Example 2)
The antiviral fiber was prepared in the same manner as in Example 1 except that Arakawa Chemical Industries, Ltd., trade name “Polymalon 1308” (light yellow turbid solution) was used as the styrene-acrylic acid copolymer mixture. Got. The copper loading of this antiviral fiber was 0.3% by mass.

(Example 3)
Antiviral fibers were obtained in the same manner as in Example 1, except that Arakawa Chemical Industries, Ltd., trade name “Polymaron 326” was used as the styrene-acrylic acid copolymer mixture. The copper loading of this antiviral fiber was 0.275% by mass.

[Performance evaluation of antiviral fiber against avian influenza virus]
As a test virus, avian influenza virus A / whistling swan / Shimane / 499/83 (H5N3) strain stored in Tottori University Center for Bird Influenza was used. This avian influenza virus strain is also referred to as avian influenza virus A / swan / Shimane / 499/83 (H5N3) (hereinafter referred to as H5N3 strain).

  The antiviral fibers produced in each of the above examples were trimmed to a length of about 1.5 cm, 0.2 g was put in a polyethylene bag, and the test virus was 100 times with phosphate buffered saline (PBS). Each 0.6 ml of diluted virus solution A was dispensed into polyethylene bags, and the virus solution was soaked into the antiviral fiber. The reaction time was left at 4 ° C. for 10 minutes. The virus solution was collected, further diluted 10-fold with PBS, and inoculated into a chorioallantoic cavity 0.2 ml each for 10-day-old chicken eggs (SPF). After culturing for 2 days, allantoic fluid B was collected and the presence or absence of virus growth was determined by chicken hemagglutination. The virus titer was calculated by the method of Reed & Muench (1938).

  As a comparative example, unprocessed rayon fiber was used.

  Table 1 shows the virus titer of each antiviral fiber (Examples 1 to 3).

  From Table 1, the allantoic fluid B using the antiviral fibers of Examples 1 to 3 had a virus titer significantly decreased as compared with the virus fluid A, and the virus reduction rate was 99% or more. This has shown that the antiviral fiber of Examples 1-3 has the antiviral effect with respect to avian influenza virus. On the other hand, the allantoic fluid B of the comparative example using no antiviral fiber under the same conditions had a virus titer decreased as compared with the virus A, but was not sufficient.

[Production of antiviral mask]
Example 4
In order to produce an anti-virus mask, the anti-virus fiber of Example 2 and a sheath-core composite fiber having a fineness of 2.2 dtex and a fiber length of 51 mm made of polypropylene as the core component and high-density polyethylene as the sheath component (Daiwabo Polytech Co., Ltd.) ), NBF (H)). The antiviral fiber of the present invention was mixed so as to be 60% by mass and the sheath-core composite fiber was 40% by mass, and opened using a parallel card machine to prepare a card web. The basis weight was 40 g / m ² .

  The obtained card web was sprayed twice on the surface of the web using a nozzle provided with orifices having a hole diameter of 0.08 mm at intervals of 0.6 mm, and similarly on the opposite surface. The fiber was entangled by jetting a columnar water flow with a water pressure of 4 MPa twice. Then, after dewatering in a box-type vacuum suction device, the water flow is fused and dried by a drum-type dryer (set temperature: 140 ° C.) with the sheath component of the sheath-core composite fiber, and is integrated by hydroentanglement. A entangled nonwoven fabric was obtained.

  The obtained laminated nonwoven fabric is immersed in a 0.1% aqueous copper sulfate solution at 25 ° C., squeezed with a nip roll, sufficiently washed with a water washing tank, dried at 80 ° C., and a sample of an antiviral nonwoven fabric. Got. This antiviral nonwoven fabric had a copper loading of 0.18% by mass.

  The antiviral nonwoven fabric thus obtained is placed on a polypropylene spunbond nonwoven fabric, and a polypropylene meltblown nonwoven fabric and a polypropylene spunbond nonwoven fabric are overlapped, cut into 15 cm length and 15 cm width, and pleated in three stages. Folded, an ear strap was provided at the center of the lateral edge, and the four sides of the sheet edge were heat sealed to produce an antiviral mask in which the antiviral nonwoven fabric constituted the second layer from the outside. When this mask was worn, there was no breathing and the wearability was good.

(Example 5)
A laminated nonwoven fabric comprising the following first to third fiber layers was produced. For the first fiber layer and the third fiber layer, a card web was produced in the same manner as in Example 3 except that the basis weight of each layer was 20 g / m ² .

As the second fiber layer, a one-way stretched array nonwoven fabric (trade name: Milife T05, manufactured by Nippon Petroleum Co., Ltd.) made of polyester fiber and having a basis weight of 5 g / m ² was prepared.

  A laminated web was prepared by laminating three fiber layers so that the second fiber layer was positioned between the first fiber layer and the third fiber layer. Next, using a nozzle in which orifices having a hole diameter of 0.08 mm are provided at intervals of 0.6 mm, a columnar water flow having a water pressure of 4 MPa is sprayed twice on the surface of the web on the first fiber layer side. The fibers were entangled by injecting a columnar water flow with a water pressure of 4 MPa twice on the surface on the side. Then, after dehydrating in a box-type vacuum suction device, fusion is performed with a sheath component of the sheath-core type composite fiber in a drum-type dryer (set temperature: 140 ° C.), dried, and integrated by hydroentanglement A nonwoven fabric was obtained.

  The obtained laminated nonwoven fabric is immersed in a 0.1% aqueous copper sulfate solution at 25 ° C., squeezed with a nip roll, sufficiently washed with a water washing tank, dried at 80 ° C., and a sample of an antiviral nonwoven fabric. Got. This antiviral nonwoven fabric had a copper loading of 0.16% by mass.

  The antiviral nonwoven fabric thus obtained is placed on a polypropylene spunbond nonwoven fabric, and a polypropylene meltblown nonwoven fabric and a polypropylene spunbond nonwoven fabric are overlapped, cut into 15 cm length and 15 cm width, and pleated in three stages. Folded, an ear strap was provided at the center of the lateral edge, and the four sides of the sheet edge were heat sealed to produce an antiviral mask in which the antiviral nonwoven fabric constituted the second layer from the outside. When this mask was worn, there was no breathing and the wearability was good.

[Production of waterproof antiviral nonwoven fabric]
(Example 6)
A waterproof antiviral nonwoven fabric was prepared by laminating low density polyethylene having a melting point of 103 ° C. to a thickness of 30 μm on the surface of the antiviral nonwoven fabric using an extrusion laminator. When this waterproof nonwoven fabric was used for medical bed sheets and experimental sheets, it was confirmed that it had waterproofness and antiviral effect.

[Production of air filter]
(Example 7)
1. An antiviral nonwoven fabric having a fineness of 7.8 dtex and an antiviral fiber having a fiber length of 76 mm obtained by the same method as in Example 1, 50% by mass, a core component made of polypropylene, and a sheath component made of high-density polyethylene. 50% by mass of 2 dtex, a sheath-core type composite fiber having a fiber length of 51 mm (manufactured by Daiwabo Polytech Co., Ltd., NBF (H)) was used. These fibers were mixed and a card web opened using a parallel card machine was produced. Next, heat treatment is performed at 140 ° C. using a hot roll processing machine composed of a pair of emboss rolls / flat rolls, and the sheath component of the sheath-core composite fiber is melted and partially pressed (emboss area ratio is about 18%). A thermal bond nonwoven fabric (antiviral nonwoven fabric) having a basis weight of 30 g / m ² was produced.

Next, a chemical bond nonwoven fabric in which polyester fibers and rayon fibers were mixed was used as a support, and a hot melt agent was sprayed on the support, and then the obtained antiviral nonwoven was laminated and integrated with the hot melt agent. Next, after spraying a hot melt agent on the antiviral nonwoven fabric, an electret nonwoven fabric (precision filter layer) having a basis weight of 150 g / m ² was laminated and integrated with the hot melt agent. The obtained sheet was pleated by a pleating machine and fitted into a plastic unit to produce an air purifier filter. When this filter was mounted on an air purifier, it was confirmed that sufficient filter performance was obtained.

  The antiviral substance of the present invention can be used as a raw material for the antiviral fiber of the present invention.

  The antiviral fiber structure containing at least a part of the antiviral fiber of the present invention can be formed into yarns, woven or knitted fabrics, webs, nonwoven fabrics, papers, nets and the like and used in various textile industries. The antiviral fiber structure has a high inactivation effect against the virus that comes into contact with it, and is useful for medical treatment.

  Further, the antiviral fiber product containing at least a part of the antiviral fiber includes, for example, clothing, futon, curtain, wallpaper, carpet, mat, bed sheet, filter, mask, wiper, towel, protective clothing, protective net, waste chicken Can be used in the form of bags, poultry house supplies and medical sheets.

Claims (8)

  The polymer chain is a polymer containing a copolymer component of styrene or α-olefin and (meth) acrylic acid, and the polymer carries a metal ion selected from copper, silver, zinc and nickel. Antiviral substances characterized by   The antiviral substance according to claim 1, wherein the polymer is a styrene- (meth) acrylic acid copolymer carrying copper ions.   The antiviral substance according to claim 1 or 2, wherein the polymer and cellulose are mixed.   The antiviral substance according to any one of claims 1 to 3, wherein the polymer is effective against avian influenza virus.   The antiviral substance according to claim 4, wherein the avian influenza virus is A / whistling swan / Shimane / 499/83 (H5N3) strain.   The polymer chain contains a copolymer component of styrene or α-olefin and (meth) acrylic acid, and the copolymer component carries a metal ion selected from copper, silver, zinc and nickel. An antiviral fiber comprising an antiviral substance comprising a polymer as an active ingredient.   An antiviral fiber structure comprising at least a part of the antiviral fiber according to claim 6.   The antiviral fiber according to claim 6 is included at least in part, and clothing, bedding, futon, curtain, wallpaper, carpet, mat, sheets, filter, mask, wiper, towel, protective clothing, protective net, waste chicken bag, Antiviral fiber products shaped into poultry house supplies and medical sheets.