JP6919343B2 - Cloth, clothing, and medical components - Google Patents

Description

The present invention relates to a cloth having antibacterial properties, and clothing or medical members using the cloth.

Conventionally, many proposals have been made for fiber materials having antibacterial properties (see Patent Documents 1 to 7).

Japanese Patent No. 3281640 Japanese Unexamined Patent Publication No. 7-310284 Japanese Patent No. 3165992 Japanese Patent No. 1805853 Japanese Unexamined Patent Publication No. 8-226578 Japanese Unexamined Patent Publication No. 9-194304 Japanese Unexamined Patent Publication No. 2004-300650

However, none of the antibacterial materials had a long-lasting effect.

In addition, a material having antibacterial properties may cause an allergic reaction due to a drug or the like.

Therefore, an object of the present invention is to provide a cloth having a longer effect than a conventional material having antibacterial properties and having a higher safety than a drug or the like.

The cloth of the present invention includes charge generating fibers and conductive fibers. The charge generating fiber generates an electric charge by energy from the outside. Conductive fibers elute metal ions.

It has been known that the growth of bacteria can be suppressed by an electric field (for example, Tetsuaki Doto, Hiroki Korai, Hideaki Matsuoka, Junichi Koizumi, Kodansha: Microbial Control-See Science and Engineering. For example, see Koichi Takaki, Application of High Voltage / Plasma Technology to Agriculture / Food Fields, J.HTSJ, Vol.51, No.216). Further, depending on the potential that generates this electric field, a current may flow through a current path formed by humidity or the like or a circuit formed by a local micro discharge phenomenon or the like. It is considered that this electric current partially destroys the cell membrane of the bacterium and suppresses the growth of the bacterium. Since the cloth of the present invention includes charge generating fibers that generate electric charges by external energy, an electric field is locally generated in the cloth. In addition, an electric field is generated when the human body is close to an object having a predetermined potential (including a ground potential). Alternatively, the cloth of the present invention allows an electric current to flow between the fibers in the cloth through moisture such as sweat. In addition, when it is close to an object having a predetermined potential (including a ground potential) such as a human body, a current is passed between the object and the object.

Therefore, the cloth of the present invention generates an electric field or an electric current when applied to the cloth itself or an object (clothing, a medical product such as a mask) used in the vicinity of an object having a predetermined potential such as a human body. Due to the direct action of, the cell membrane of the bacterium and the electron transport chain for maintaining the life of the bacterium are disturbed, and the bacterium is killed or the bacterium itself is weakened. Furthermore, oxygen contained in water may be changed to reactive oxygen species by an electric field or an electric current, or oxygen radicals may be generated in the cells of a bacterium due to a stress environment due to the presence of an electric field or an electric current. Bacteria are killed or weakened by the action of reactive oxygen species including radicals. In addition, the above reasons may be combined to produce an antibacterial effect (an effect of suppressing the growth of bacteria) and a bactericidal effect.

Further, since the cloth of the present invention includes conductive fibers that elute metal ions, the metal ions further enhance the antibacterial or bactericidal effect. Further, in the cloth of the present invention, even if there is a place where the electric charge is not generated in the charge generating fiber, the locally generated charge is carried to the whole cloth by the conductive fiber, and the cloth as a whole is antibacterial or antibacterial. A bactericidal effect is produced.

The conductive fiber may be carbon-plated, a metal itself (thin wire), a slit ribbon, a polyester fiber surface electrolessly plated, or a polyester film with electrodes vapor-deposited into a slit ribbon. , May be. Further, as the metal ion to be eluted, for example, Ag +, Zn2 +, Cu2 + or the like is preferable.

As the fiber that generates an electric charge by energy from the outside, for example, a substance having a photoelectric effect, a substance having a pyroelectric effect, a fiber using a piezoelectric material, or the like can be considered. Further, a structure in which a conductor is used for the core yarn, an insulator is wound around the conductor, and electricity is passed through the conductor to generate an electric charge is also a charge generating fiber.

When a piezoelectric material is used, an electric field is generated by the piezoelectric material, so that no power source is required and there is no risk of electric shock. In addition, the life of the piezoelectric material lasts longer than the antibacterial effect of a drug or the like. Also, it is less likely to cause an allergic reaction than a drug.

Even a cloth provided with a first charge-generating fiber that generates a positive charge, a second charge-generating fiber that generates a negative charge, and a conductive fiber that elutes metal ions can be used alone as an electric field or. It can generate an electric charge and produce an antibacterial effect.

According to the present invention, it is possible to realize a cloth that has a longer lasting effect than a conventional material having antibacterial properties and is safer than a drug or the like.

FIG. 1A is a diagram showing the configuration of the piezoelectric thread 1, and FIG. 1B is a plan view of the piezoelectric film 10. 2 (A) and 2 (B) are views showing the relationship between the uniaxial stretching direction of polylactic acid, the electric field direction, and the deformation of the piezoelectric film 10. It is a figure which shows the piezoelectric thread 1 when an external force is applied. FIG. 4A is a schematic plan view of the cloth 100, and FIG. 4B is a diagram showing each thread arrangement. It is a figure which shows the structure of the piezoelectric thread 2. It is a figure which shows the electric field generated between each yarn. It is a figure which shows the electric field generated between each yarn. FIG. 8A is a partially exploded view showing the configuration of the piezoelectric thread 31, and FIG. 8B is a partially exploded view showing the configuration of the piezoelectric thread 32. FIG. 9A is a partially exploded view showing the configuration of the piezoelectric thread 33, and FIG. 9B is a partially exploded view showing the configuration of the piezoelectric thread 34. It is the figure which exaggerated the gap of the piezoelectric film 10 in the piezoelectric thread 33. It is a partial exploded view which shows the structure of a piezoelectric thread 35. It is a figure which shows the structure of a braid.

FIG. 1A is a partially exploded view showing the configuration of the piezoelectric thread 1, and FIG. 1B is a plan view of the piezoelectric film 10. The piezoelectric thread 1 is an example of a fiber that generates an electric charge by energy from the outside.

The piezoelectric thread 1 is formed by winding a piezoelectric film 10 around a core thread 11. The piezoelectric film 10 is an example of a piezoelectric material. The core yarn 11 is appropriately selected from cotton, silk, general synthetic fibers and the like. The core thread 11 may be a conductive thread having conductivity. When the core thread 11 is a conductive thread, when inspecting the piezoelectricity of the piezoelectric thread 1, an electrode formed on a part of the outer periphery of the piezoelectric thread 1 and the electric charge generated in the piezoelectric thread 1 by using the core thread 11 are applied. Can be measured. This makes it possible to inspect the piezoelectric performance of the piezoelectric film 10 used for the piezoelectric thread 1. Further, by short-circuiting the conductive threads, a circuit is clearly formed between the threads, and the electric field generated between the surfaces of the threads is dramatically increased. However, at this time, the short-circuited conductive thread defines the reference potential, and must not be a circuit that neutralizes the generated charge. Further, when a conductor is used for the core thread 11, if a voltage is applied to the core thread 11, even if an insulator other than the piezoelectric film 10 is wound around the core thread 11, it is charged by energy from the outside. It is possible to realize a thread that generates an electric charge.

The core thread 11 is not an essential configuration. Even without the core thread 11, it is possible to spirally swirl the piezoelectric film 10 to form a piezoelectric thread (swivel thread). When there is no core thread 11, the swirl thread becomes a hollow fiber, and the heat retention capacity is improved. Further, the strength can be increased by impregnating the swivel thread itself with an adhesive.

The piezoelectric film 10 is made of, for example, a piezoelectric polymer. Piezoelectric films include those having pyroelectricity and those not having pyroelectricity. For example, PVDF (polyvinylidene fluoride) has pyroelectricity, and charges are generated even when the temperature changes. The surface of a pyroelectric piezoelectric material such as PVDF is also charged by the thermal energy of the human body.

In addition, polylactic acid (PLA) is a piezoelectric film that does not have pyroelectricity. Polylactic acid is uniaxially stretched to produce piezoelectricity. Polylactic acid includes PLLA in which an L-form monomer is polymerized and PDLA in which a D-form monomer is polymerized.

Chiral polymers such as polylactic acid have a spiral main chain. The chiral polymer has piezoelectricity when it is uniaxially stretched and the molecules are oriented. When the thickness direction of the uniaxially stretched piezoelectric film 10 made of polylactic acid is defined as the first axis, the stretching direction 900 is defined as the third axis, and the direction orthogonal to both the first axis and the third axis is defined as the second axis. It has tensor components of d14 and d25 as piezoelectric strain constants. Therefore, polylactic acid generates an electric charge when the strain is generated in the direction of 45 degrees with respect to the uniaxially stretched direction.

2 (A) and 2 (B) are views showing the relationship between the uniaxial stretching direction of polylactic acid, the electric field direction, and the deformation of the piezoelectric film 10. As shown in FIG. 2A, when the piezoelectric film 10 shrinks in the direction of the first diagonal line 910A and extends in the direction of the second diagonal line 910B orthogonal to the first diagonal line 910A, the piezoelectric film 10 faces from the back side to the front side of the paper surface. Generates an electric field. That is, the piezoelectric film 10 generates a negative charge on the front side of the paper surface. As shown in FIG. 2B, the piezoelectric film 10 also generates an electric charge when it extends in the direction of the first diagonal line 910A and contracts in the direction of the second diagonal line 910B, but the polarity is reversed and the surface of the paper surface. An electric field is generated in the direction from to the back side. That is, the piezoelectric film 10 generates a positive charge on the front side of the paper surface.

Since polylactic acid produces piezoelectricity by molecular orientation treatment by stretching, it is not necessary to perform polling treatment unlike other piezoelectric polymers such as PVDF or piezoelectric ceramics. The piezoelectric constant of uniaxially stretched polylactic acid is about 5 to 30 pC / N, and has a very high piezoelectric constant among polymers. Furthermore, the piezoelectric constant of polylactic acid does not fluctuate with time and is extremely stable.

The piezoelectric film 10 is produced by cutting a uniaxially stretched polylactic acid sheet as described above to, for example, a width of about 0.5 to 2 mm. As shown in FIG. 1 (B), the piezoelectric film 10 has the same major axis direction and the stretching direction 900. As shown in FIG. 1A, the piezoelectric film 10 is a piezoelectric yarn 1 of a left-handed swirl yarn (hereinafter, referred to as S yarn) twisted by turning left with respect to the core yarn 11. The stretching direction 900 is in a state of being tilted 45 degrees to the left with respect to the axial direction of the piezoelectric thread 1.

Therefore, as shown in FIG. 3, when an external force is applied to the piezoelectric thread 1, the piezoelectric film 10 becomes as shown in FIG. 2 (A) and generates a negative charge on the surface.

As a result, the piezoelectric thread 1 generates a negative charge on the surface when an external force is applied. Therefore, the piezoelectric thread 1 generates an electric field when it is close to an object having a predetermined potential (including a ground potential) such as a human body.

It has been known that the growth of bacteria can be suppressed by an electric field (for example, Tetsuaki Doto, Hiroki Korai, Hideaki Matsuoka, Junichi Koizumi, Kodansha: Microbial Control-See Science and Engineering. For example, see Koichi Takaki, Application of High Voltage / Plasma Technology to Agriculture / Food Fields, J.HTSJ, Vol.51, No.216). Further, depending on the potential that generates this electric field, a current may flow through a current path formed by humidity or the like or a circuit formed by a local micro discharge phenomenon or the like. It is considered that this electric current partially destroys the cell membrane of the bacterium and suppresses the growth of the bacterium. The bacteria referred to in the present embodiment include bacteria, fungi, and microorganisms such as mites and fleas.

Therefore, the piezoelectric thread 1 directly exerts an antibacterial effect or a bactericidal effect by an electric field generated when it is close to an object having a predetermined electric potential such as a human body. Alternatively, the piezoelectric thread 1 passes an electric current through moisture such as sweat when it is close to an object having a predetermined potential such as a human body. This electric current may also directly exert an antibacterial effect or a bactericidal effect. Alternatively, radical species in which oxygen contained in water is changed by the action of electric current or voltage, radical species generated by interaction or catalytic action with additives contained in fibers, and other antibacterial chemical species (amine derivatives, etc.) ) May indirectly exert an antibacterial effect or a bactericidal effect. Alternatively, oxygen radicals may be generated in the cells of the bacterium due to the stress environment due to the presence of an electric field or an electric current, and the bacterium is killed or weakened by the action of reactive oxygen species containing these radicals. As radical species, generation of superoxide anion radical (active oxygen) and hydroxyl radical is considered.

The cloth 100 in which a plurality of piezoelectric threads 1 are woven also functions as a cloth for controlling bacteria. FIG. 4A is a schematic plan view of the cloth 100, and FIG. 4B is a diagram showing the arrangement of each thread. The cloth 100 is formed by weaving a piezoelectric thread 1, a normal thread 3, and a conductive thread 5. The ordinary yarn 3 is a yarn in which a piezoelectric material is not provided, and corresponds to a dielectric material. However, the ordinary yarn 3 is not an essential configuration in the present invention.

The conductive thread 5 is an example of a conductive fiber that elutes metal ions. The conductive fiber may be carbon-plated, a metal itself (thin wire), a slit ribbon, a polyester fiber surface electrolessly plated, or a polyester film with electrodes vapor-deposited into a slit ribbon. There may be. Further, as the metal ion to be eluted, for example, Ag +, Zn2 +, Cu2 + or the like is preferable.

Since the cloth 100 includes the piezoelectric thread 1 and the conductive thread 5, in addition to the antibacterial or bactericidal effect due to the electric charge generated by the piezoelectric thread 1, the antibacterial or bactericidal effect due to the metal ions eluted from the conductive thread 5. Becomes higher. Further, in the cloth 100, even if there is a place where the electric charge is not generated in the piezoelectric thread 1, the locally generated electric charge is carried to the entire cloth by the conductive thread 5, and the cloth as a whole is antibacterial or sterilized. The effect is produced. Further, by connecting the conductive thread 5 to a measuring instrument such as an oscilloscope, it is possible to check whether the piezoelectric thread 1 is functioning (whether or not it generates an electric charge) (perform a shipping inspection or the like). When a conductor that elutes metal ions is used for the core thread 11, it is not necessary to provide a conductive thread separately from the piezoelectric thread 1 because the core thread 11 functions as a conductive fiber that elutes metal ions.

Clothes made of cloth 100, or medical members using the clothes (clothes of medical workers, clothes of patients, masks, bandages, gauze or supporters) also exhibit antibacterial or bactericidal effects like cloth 100. Of the clothing, socks (or supporters) in particular are inevitably expanded and contracted along the indirect by movements such as walking, so that the piezoelectric thread 1 generates electric charges at a high frequency. In addition, socks absorb water such as sweat and serve as a hotbed for the growth of bacteria. However, since the piezoelectric thread 1 can suppress the growth of bacteria, it produces a remarkable effect as a measure against bacteria.

In addition, the cloth 100 includes underwear such as underwear, towels, hats, shoes and boots, sports goods (inners of clothing and gloves, baskets used in martial arts, etc.), kitchen goods (sponge or cloth, etc.), daily necessities. (Curtains or toilet seats, etc.), sanitary goods, various filters (water purifiers, air conditioner or air purifier filters, etc.), various mats (foot or toilet mats, etc.), seats for cars, trains, airplanes, etc. It can be used as a cushioning material for motorcycle helmets and its exterior materials, sofas, pillows, pillowcases, duvets, mattresses, sheets, stuffed animals, pet mats, inners for pet clothes, packaging materials, and the like.

As the piezoelectric thread used for the cloth 100, it is also possible to use the piezoelectric thread 2 of the right-handed swivel thread (hereinafter, referred to as Z thread) as shown in FIG. Since the piezoelectric thread 2 is a Z thread, the drawing direction 900 is in a state of being tilted 45 degrees to the right with respect to the axial direction of the piezoelectric thread 1. Therefore, when an external force is applied to the piezoelectric thread 2, the piezoelectric film 10 becomes as shown in FIG. 2B, and a positive electric charge is generated on the surface. Therefore, the piezoelectric thread 2 also generates an electric field when it is close to an object having a predetermined potential (including a ground potential) such as a human body. Alternatively, the piezoelectric thread 2 conducts an electric current when it is close to an object having a predetermined potential (including a ground potential) such as a human body through water such as sweat.

The piezoelectric thread is manufactured by any known method. For example, a method of extruding a piezoelectric polymer into fibers, a method of melt-spinning a piezoelectric polymer into fibers, a method of fiberizing a piezoelectric polymer by dry or wet spinning, or a method of fiberizing a piezoelectric polymer by dry or wet spinning. Can be adopted as a method of fiberizing the material by electrostatic spinning.

Also, many fungi have a negative charge. Therefore, the cloth provided with the piezoelectric thread 2 can adsorb many bacteria due to the generated positive charge. In addition, the cloth provided with the piezoelectric thread 2 can also inactivate bacteria having a negative charge by the generated positive charge. As described above, the cloth using the piezoelectric yarn that generates a positive charge on the surface has a high effect as the piezoelectric yarn for controlling bacteria.

The cloth provided with the piezoelectric thread 1 or the piezoelectric thread 2 has the following uses in addition to the antibacterial use.

(1) Piezoelectric cloth Many of the tissues that make up a living body have piezoelectricity. For example, collagen constituting the human body is a kind of protein, and is abundantly contained in blood vessels, dermis, ligaments, healthy bones, bones, cartilage and the like. Collagen is a piezoelectric material, and the tissue in which collagen is oriented may exhibit a very large piezoelectricity. Many reports have already been made on the piezoelectricity of bone (see, for example, Polymer Vol.16 (1967) No.9 p795-800, etc.). Therefore, when an electric field is generated by the cloth provided with the piezoelectric thread 1 or the piezoelectric thread 2, and the electric fields alternate or the strength of the electric field changes, the piezoelectric body of the living body vibrates due to the inverse piezoelectric effect. Due to the alternating electric field generated by the piezoelectric thread 1 and / or the piezoelectric thread 2, or the change in electric field strength, minute vibrations are applied to a part of the living body, for example, capillaries and dermis, which promotes improvement of blood flow in that part. can. This may promote healing of skin diseases and wounds. Therefore, the piezoelectric yarn functions as a bioactive piezoelectric yarn.

(2) Piezoelectric cloth for substance adsorption As described above, the piezoelectric thread 1 generates a negative charge when an external force is applied. The piezoelectric thread 2 generates a positive charge when an external force is applied. Therefore, the piezoelectric thread 1 has a property of adsorbing a substance having a positive charge (for example, particles such as pollen), and the piezoelectric thread 2 adsorbs a substance having a negative charge (for example, a harmful substance such as yellow sand). do. Therefore, the cloth provided with the piezoelectric thread 1 or the piezoelectric thread 2 can adsorb fine particles such as pollen or yellow sand when applied to medical supplies such as masks.

Next, FIG. 6A is a schematic plan view of the cloth 100A, and FIG. 6B is a diagram showing an electric field generated between the threads.

The cloth 100A shown in FIGS. 6 (A) and 6 (B) is formed by weaving a piezoelectric thread 1, a piezoelectric thread 2, a normal thread 3, and a conductive thread 5. The ordinary yarn 3 is a yarn in which a piezoelectric material is not provided, and corresponds to a dielectric material. Further, the ordinary yarn 3 is appropriately selected from natural fibers or chemical fibers. Natural fibers include plant fibers, animal fibers, polylactic acid and the like. The plant fiber is, for example, cotton or hemp. Plant fibers are soft to the touch and have a high affinity for water, so they absorb moisture. When plant fibers are used, an electric current is likely to be generated due to the electric charge generated in the piezoelectric thread 1 and the absorbed moisture. Animal fibers are, for example, silk or wool. When animal fibers are used, even if microorganisms such as insects are present in the animal fibers, the microorganisms can be killed by the electric charge generated by the piezoelectric thread 1. When polylactic acid is used for the ordinary yarn 3, it is preferable that the ordinary yarn 3 is not uniaxially stretched so as not to generate an electric charge. As will be described later, when polylactic acid is used for the piezoelectric film 10, the material is the same as that of the ordinary yarn 3, so that the affinity is high. Chemical fibers include, for example, synthetic fibers, glass fibers, carbon fibers and the like. Chemical fibers are tougher than natural fibers.

In the example of FIG. 6B, the piezoelectric thread 1, the piezoelectric thread 2, the ordinary thread 3, and the conductive thread 5 are arranged in parallel. The piezoelectric thread 1 and the piezoelectric thread 2 are arranged at a predetermined distance via a normal thread 3 corresponding to a dielectric material. The potential difference at each location is defined by an electric field coupling circuit formed by intricately entwining the threads, or a circuit formed by a current path accidentally formed in the threads due to moisture or the like. Therefore, when an external force is applied to these threads, an electric field indicated by a white arrow in the figure is generated between the piezoelectric thread 2 that generates a positive charge and the piezoelectric thread 1 that generates a negative charge. When the piezoelectric thread 1 and the piezoelectric thread 2 are close to each other, the adjacent portions tend to have the same potential, and the potential opposite to the surface appears at the core portion of each piezoelectric thread while maintaining the original potential difference. Therefore, in the vicinity of the piezoelectric thread 1, an electric field is formed so as to go from the core of the thread to the outside of the thread, and in the vicinity of the piezoelectric thread 2, an electric field is formed so as to go from the outside of the thread to the core of the thread. These electric fields are combined to form an electric field that goes from the piezoelectric thread 1 to the piezoelectric thread 2. However, the ordinary yarn 3 is not an essential configuration. Even if there is no ordinary thread 3, an electric field is generated between the piezoelectric thread 1 and the piezoelectric thread 2.

Since the piezoelectric threads 1 and the piezoelectric threads 2 are arranged in an extremely close state, the distance is almost 0. As the strength of the electric field increases in inverse proportion to the distance between the substances that generate electric charges, as represented by E = V / d, the strength of the electric field generated by the cloth 100A becomes a very large value. These electric fields are formed by mutually coupling the electric field generated in the piezoelectric thread 1 and the electric field generated in the piezoelectric thread 2. In some cases, a circuit may be formed as an actual current path by water containing an electrolyte such as sweat. In a cloth in which fibers are woven, the fibers are intricately entangled with each other, so that the electric field generated in a certain part of the piezoelectric thread 1 and the electric field generated in another part of the piezoelectric thread 1 may be mutually coupled. Similarly, the electric field generated in a certain part of the piezoelectric thread 2 and the electric field generated in another part of the piezoelectric thread 2 may be mutually coupled. Even when the electric field strength is zero or very weak from a macroscopic point of view, it may be an aggregate of strong electric fields whose vector directions are opposite to each other microscopically. These phenomena can be similarly explained by a cloth formed of only the piezoelectric thread 1, a cloth formed of only the piezoelectric thread 2, or a cloth in which ordinary threads and conductive threads are woven at the same time. However, an electric field is not formed in the following examples. A transducer that uses a plurality of piezoelectric yarns and conductive yarns to make a knit or woven fabric and senses that a displacement is applied to the knitted fabric is published in WO2015 / 159832. In this case, all the conductive threads are connected to the detection circuit, and there is always a pair of conductive threads for one piezoelectric thread. In WO2015 / 159832, when an electric charge is generated in the piezoelectric thread, electrons move in the conductive thread to immediately neutralize the electric charge generated in the piezoelectric thread. In WO2015 / 159832, the detection circuit captures the current due to the movement of electrons and outputs it as a signal. Therefore, in this case, since the generated potential is immediately canceled, a strong electric field is not formed between the piezoelectric thread and the conductive thread and between the piezoelectric thread and the piezoelectric thread. Therefore, the conductive fiber needs to exist as a mere floating electrode or to define a potential such as a ground potential.

Therefore, the cloth 100A functions as a cloth that generates an electric field. Further, the cloth 100A may pass an electric current between the piezoelectric threads 1 and the piezoelectric threads 2 through moisture such as sweat. This electric current may also exert an antibacterial effect or a bactericidal effect. Alternatively, radical species in which oxygen contained in water is changed by the action of electric current or voltage, radical species generated by interaction or catalytic action with additives contained in fibers, and other antibacterial chemical species (amine derivatives, etc.) ) May indirectly exert an antibacterial effect or a bactericidal effect. Alternatively, oxygen radicals may be generated in the cells of the bacterium due to the stress environment due to the presence of an electric field or an electric current, and the bacterium may be killed or weakened by the action of reactive oxygen species containing these radicals.

Cloth 100A exerts an antibacterial or bactericidal effect by the electric field generated by itself and the change in its strength, or by an electric current. Alternatively, it exerts an antibacterial or bactericidal effect due to radical species generated by the action of the current or voltage. Further, in addition to the antibacterial or bactericidal effect of the electric field, the cloth 100A has a higher antibacterial or bactericidal effect due to the metal ions from which the conductive thread 5 is eluted. Further, the cloth 100A exhibits an antibacterial or bactericidal effect due to the metal ions eluted from the conductive thread 5 even if there is a portion of the piezoelectric thread 1 where an electric charge is not generated.

The same applies to clothing made of cloth 100A or medical members using the clothing. Even in clothing made of cloth 100A, socks (or supporters) in particular produce a remarkable effect as a fungus control application as described above. Further, the cloth 100A also functions as a bioactive piezoelectric cloth or a material adsorption piezoelectric cloth in the same manner as the bioactive piezoelectric thread or the material adsorption piezoelectric thread.

Since the cloth 100A exerts an antibacterial or bactericidal effect by the electric field or the electric current generated by the piezoelectric threads 1 and the piezoelectric threads 2 constituting the cloth 100A, the cloth 100A exerts an antibacterial or bactericidal effect against bacteria transferred to the cloth 100A. .. Indigenous bacteria that play a necessary role in keeping the skin surface in a normal state are present in the human skin, but cloth 100A is unlikely to directly sterilize these indigenous bacteria. Therefore, the cloth 100A is less likely to affect the indigenous bacteria on the skin, and is more safe.

As shown in FIG. 7, in the cloth 100A, even in a mode in which the piezoelectric thread 1, the piezoelectric thread 2, the ordinary thread 3, and the conductive thread 5 are arranged so as to intersect with each other, the piezoelectric thread 1 and the piezoelectric thread 2 intersect with each other. An electric field is generated at the position where it is used.

In the present embodiment, a piezoelectric film is shown as an example of the piezoelectric film, but the piezoelectric film is, for example, a thread that is discharged from a nozzle and stretched (a piezoelectric thread having a substantially circular cross section, or a piezoelectric thread having an irregular cross section). It may be a thread). For example, polylactic acid (PLLA) piezoelectric yarns can be made through melt spinning, high drawing treatments, or heat treatment (for crystallization). Even when such a yarn (multifilament yarn) formed by twisting a plurality of PLLA piezoelectric yarns is formed and tension is applied to this yarn, a negative charge is generated on the surface of the S yarn and the surface of the Z yarn. Positive charge is generated in. Such a yarn does not use a core yarn and can be simply a twisted yarn. Such threads can be made at low cost. The number of filaments of the multifilament yarn should be set in consideration of the use of the yarn. In addition, the number of twists is also set as appropriate. The filament may contain a filament that is partially non-piezoelectric. Further, the thickness of each filament does not have to be uniform. By doing so, the potential distribution generated in the cross section of the yarn is biased, and the symmetry is broken, so that an electric field circuit between the S yarn and the Z yarn is easily formed.

Next, FIG. 8A is a partially exploded view showing the configuration of the piezoelectric thread 31, and FIG. 8B is a partially exploded view showing the configuration of the piezoelectric thread 32.

The piezoelectric thread 31 is formed by further winding the piezoelectric film 10 on the piezoelectric covering thread 1A which is an S thread. The piezoelectric thread 32 is formed by further winding the piezoelectric film 10 on the piezoelectric covering thread 2A which is a Z thread. The piezoelectric thread 31 is a left-handed turning thread (S thread) in which the piezoelectric film 10 turns left with respect to the piezoelectric covering thread 1A and is covered. The stretching direction 900 is in a state of being tilted 45 degrees to the left with respect to the axial direction of the piezoelectric thread 31. The stretching direction 900 coincides with the stretching direction 900A of the piezoelectric covering yarn 1A. The piezoelectric covering yarns 1A and 2A may be twisted yarns without a core yarn. Further, the core thread may be a conductive thread.

When the piezoelectric thread 31 is pulled in the axial direction (when an external force is applied), a negative charge is generated on the surface of the piezoelectric covering thread 1A. On the other hand, a positive charge is generated on the back surface of the piezoelectric film 10 facing the front surface of the piezoelectric covering yarn 1A. When the front surface of the piezoelectric covering thread 1A and the back surface of the piezoelectric film 10 are completely in close contact with each other, this portion has the same potential. However, in a gap that is accidentally generated due to expansion and contraction of a thread or the like, an electric field is generated in this gap when a potential difference is defined. The potential difference at each location is defined by an electric field coupling circuit formed by intricately entwining the threads, or a circuit formed by a current path accidentally formed in the threads due to moisture or the like. When the circuit is formed, the strength of the electric field increases in inverse proportion to the distance between the substances that generate electric charges. Therefore, the strength of the electric field generated between the front surface of the piezoelectric covering yarn 1A and the back surface of the piezoelectric film 10 is determined. It will be extremely high. That is, this configuration further enhances the antibacterial or bactericidal effect of the yarn itself. When the piezoelectric thread 31 is pulled in the axial direction (when an external force is applied), a negative charge is generated on the surface of the piezoelectric thread 31 (the surface of the piezoelectric film 10). Therefore, by combining with a yarn that generates a positive charge on the surface, an electric field can be further generated between the yarns.

On the other hand, as shown in FIG. 8B, the piezoelectric thread 32 is a right-handed swivel thread (Z thread) in which the piezoelectric film 10 is swiveled to the right with respect to the piezoelectric covering thread 2A and is covered. The stretching direction 900 is in a state of being tilted 45 degrees to the right with respect to the axial direction of the piezoelectric thread 31. The drawing direction 900 of the above coincides with the drawing direction 900A of the piezoelectric covering yarn 2A.

When the piezoelectric thread 32 is pulled in the axial direction (when an external force is applied), a positive charge is generated on the surface of the piezoelectric covering thread 2A (the surface of the piezoelectric film 10). A negative charge is generated on the back surface of the piezoelectric film 10 facing the front surface of the piezoelectric covering yarn 2A. When the front surface of the piezoelectric covering thread 2A and the back surface of the piezoelectric film 10 are completely in close contact with each other, this portion has the same potential. However, in a gap that is accidentally generated due to expansion and contraction of a thread or the like, an electric field is generated in this gap when a potential difference is defined. The potential difference at each location is defined by a circuit formed by intricately entwining the threads or a circuit formed by a current path accidentally formed in the threads due to moisture or the like. When the circuit is formed, the strength of the electric field increases in inverse proportion to the distance between the substances that generate electric charges. Therefore, the strength of the electric field generated between the front surface of the piezoelectric covering yarn 2A and the back surface of the piezoelectric film 10 is determined. It will be extremely high. That is, with this configuration, the antibacterial or bactericidal effect of the yarn itself is further enhanced as in the case of the piezoelectric yarn 31. When the piezoelectric thread 32 is pulled in the axial direction (when an external force is applied), a positive charge is generated on the surface of the piezoelectric thread 32 (the surface of the piezoelectric film 10A). Therefore, an electric field can be generated between the yarns by combining with the yarns that generate a negative charge on the surface, such as the piezoelectric yarns 31.

Next, FIG. 9A is a partially exploded view showing the configuration of the piezoelectric thread 33, and FIG. 9B is a partially exploded view showing the configuration of the piezoelectric thread 34.

The piezoelectric thread 33 is formed by winding a piezoelectric film 10 on a piezoelectric covering thread 1A. The piezoelectric thread 34 is formed by winding a piezoelectric film 10 around a piezoelectric covering thread 2A.

The piezoelectric thread 33 is a right-handed swivel thread (Z thread) in which the piezoelectric film 10 is swiveled to the right and covered with respect to the piezoelectric covering thread 1A. The stretching direction 900 is in a state of being tilted 45 degrees to the right with respect to the axial direction of the piezoelectric thread 33. The stretching direction 900 is different from the stretching direction 900A of the piezoelectric covering yarn 1A.

Further, as shown in FIG. 9B, the piezoelectric yarn 34 is a left-handed swirl yarn (S yarn) in which the piezoelectric film 10 is twisted to the left with respect to the piezoelectric covering yarn 2A. The stretching direction 900 is in a state of being tilted 45 degrees to the left with respect to the axial direction of the piezoelectric thread 34. The stretching direction 900 is different from the stretching direction 900A of the piezoelectric covering yarn 2A.

FIG. 10 is an exaggerated view of the gap between the piezoelectric films 10 in the piezoelectric thread 33. When the piezoelectric film 10 is wound around the covering thread, the piezoelectric thread 33 has a certain gap D. When the piezoelectric thread 33 is pulled in the axial direction by this gap D, an electric field is generated between the surface of the piezoelectric covering thread 1A and the surface of the piezoelectric film 10 to form a circuit. Therefore, this configuration enhances the antibacterial or bactericidal effect of the yarn itself. The same applies to the piezoelectric thread 34.

When PDLA is used for either the piezoelectric covering thread 1A or the piezoelectric film 10 in the piezoelectric thread 33, the polarities of the charges generated on the front surface of the piezoelectric covering thread 1A and the charges generated on the back surface of the piezoelectric film 10 are different. It has the same configuration as the piezoelectric thread 31, and a strong electric field is generated between the front surface of the piezoelectric covering thread 1A and the back surface of the piezoelectric film 10. The same applies to the case where PDLA is used for either the piezoelectric covering thread 2A or the piezoelectric film 10 in the piezoelectric thread 34.

Next, FIG. 11 is a partially exploded view showing the configuration of the piezoelectric thread 35. The piezoelectric thread 35 is a thread (S thread) in which the piezoelectric thread 1 and the piezoelectric thread 2 are twisted by turning left with each other. In the piezoelectric thread 35, since the piezoelectric thread 1 that generates a negative charge on the surface and the piezoelectric thread 2 that generates a positive charge on the surface intersect with each other, an electric field can be generated by the thread alone. As described above, the potentials generated on the surfaces of the piezoelectric thread 1 and the piezoelectric thread 2 tend to be the same potential at locations close to each other. Correspondingly, the electric potential inside the yarn changes to maintain the potential difference between the surface and the inside of the yarn. In each yarn, the electric field formed between the inside and the surface of the yarn leaks into the air, the electric fields are combined with each other, and a strong electric field is formed in the vicinity of the piezoelectric yarn 1 and the piezoelectric yarn 2. NS. The structure of the twisted yarn is complicated, and the proximity points of the piezoelectric yarn 1 and the piezoelectric yarn 2 are not uniform. Further, when tension is applied to the piezoelectric thread 1 or the piezoelectric thread 2, the proximity portion also changes. As a result, the strength of the electric field changes in each part, the symmetry shape is broken, and an electric field circuit is generated. In the yarn (Z yarn) in which the piezoelectric yarn 1 and the piezoelectric yarn 2 are twisted by turning to the right, the piezoelectric yarn 1 that generates a negative charge on the surface and the piezoelectric yarn 2 that generates a positive charge on the surface intersect. Therefore, an electric field can be generated by the yarn alone. The number of twists of the piezoelectric yarn 1, the number of twists of the piezoelectric yarn 2, or the number of twists of the piezoelectric yarn 35 obtained by twisting these yarns is determined in consideration of the antibacterial effect. All of the application examples shown so far can be configured by using the piezoelectric thread 35. In the yarn (Z yarn) in which the piezoelectric yarn 1 and the piezoelectric yarn 2 are twisted by turning to the right, the piezoelectric yarn 1 that generates a negative charge on the surface and the piezoelectric yarn 2 that generates a positive charge on the surface intersect. Therefore, an electric field can be generated by the yarn alone.

In addition, even if it is a triple covering yarn in which a normal yarn is twisted on the side surface of the S yarn (or Z yarn) and a Z yarn (or S yarn) is twisted on the side surface, the electric field is applied by the yarn alone. Can be generated.

Further, as shown in FIG. 12, a yarn (No. 1) composed of a braided yarn that simultaneously constitutes a piezoelectric yarn 1 that turns right (or turns left) and a piezoelectric yarn 2 that turns left (or turns right) on the surface of a normal yarn. Even in the case of the thread (3), since the electric field is generated at the position where the piezoelectric thread 1 and the piezoelectric thread 2 intersect, the electric field can be generated by the thread alone.

As the yarn that generates a negative charge on the surface, in addition to the S yarn using PLLA, the Z yarn using PDLA can be considered. Further, as the yarn that generates a positive charge on the surface, in addition to the Z yarn using PLLA, the S yarn using PDLA can be considered. Therefore, for example, in the configuration shown in FIG. 11, the S yarn using PLLA and the S yarn using PDLA are twisted by turning left with each other (S yarn) or twisted by turning right (Z yarn). ) Can also generate an electric field by itself. A piezoelectric yarn consisting of a Z yarn using PLLA and a yarn twisted by turning left and twisting Z yarn using PDLA (S yarn) or a yarn twisted by turning right (Z yarn) is also an electric field as a single yarn. Can be generated.

Next, the antibacterial effect of the thread made of the piezoelectric material will be described. The inventor of the present application conducted the quantitative tests shown in the following (1) and (2) in order to evaluate the fungus-suppressing effect of the cloth in which the thread made of the piezoelectric material is woven.

(1) Evaluation of antibacterial properties of cloth woven with piezoelectric threads a) Test method: Bacterial solution absorption method (JIS L1902)
b) Test bacterium: Staphylococcus aureus NBRC12732
c) Concentration of inoculated bacterial solution: 1.4 x 105 (CFU / mL)
d) Standard cloth: woven with cotton yarn and woven with cotton yarn e) Test sample (antibacterial processed sample): S yarn (piezoelectric yarn 1) and Z yarn (piezoelectric yarn 2) are twisted by turning left. A cloth woven from the S thread (piezoelectric thread 35).

[a formula]
-Proliferation value: G = Mb-Ma
-Antibacterial activity value: A = (Mb-Ma)-(Mc-Mo)
A normal antibacterial processed product has an antibacterial activity value A ≧ 2.0 to 2.2.

-Ma: Arithmetic mean common logarithm of the viable cell count (or ATP amount) of the three standard cloth samples immediately after inoculation with the test bacteria-Mb: The viable cell count (or ATP amount) of the three standard cloth samples after culturing for 18 to 24 hours. ) Arithmetic mean common logarithm ・ Mo: Arithmetic mean common logarithm (or ATP amount) of 3 test samples (antibacterial processed samples) immediately after inoculation with test bacteria ・ Mc: Test sample after culturing for 18 to 24 hours Arithmetic mean common logarithm of viable cell count (or ATP amount) of 3 samples (antibacterial processed sample)

As is clear from Table 1, the test sample (a cloth woven with a thread made of a piezoelectric material) has a higher antibacterial effect against bacteria than a standard cloth. Further, it can be seen that the antibacterial effect is higher when the test sample is vibrated than when the test sample is left standing. In particular, when the test sample is vibrated to generate an electric field, almost no positive bacteria are observed 18 hours after inoculation of the test bacteria (bacteria), and a high antibacterial effect (bactericidal effect) is exhibited.

(2) Antifungal property evaluation of cloth woven with piezoelectric thread a) Test method: Antifungal property quantitative test method (method specified by the Textile Evaluation Technology Council)
b) Test bacterium: Aspergillus niger NBRC105649
c) Concentration of inoculated bacterial solution: 1.1 x 105 (CFU / mL)
d) Standard cloth: woven with cotton yarn and woven with cotton yarn e) Test sample (antibacterial processed sample): S yarn (piezoelectric yarn 1) and Z yarn (piezoelectric yarn 2) are twisted by turning left. A cloth woven from the prepared piezoelectric yarn (piezoelectric yarn 35).

[a formula]
・ Growth value: F = Fb-Fa
-Antifungal activity value: FS = (Fb-Fa)-(Fc-Fo)
-Fa: Arithmetic mean common logarithm of the viable cell count (or ATP amount) of the three standard cloth samples immediately after inoculation with the test bacteria-Fb: The viable cell count (or ATP amount) of the three standard cloth samples after 42 hours of culture. Arithmetic mean common logarithm ・ Fo: Arithmetic mean common logarithm (or ATP amount) of 3 viable cell counts (or ATP amount) of the test sample (antibacterial processed sample) immediately after inoculation of the test bacteria ・ Fc: Test sample (antibacterial processed sample) after 42 hours of culture ) Arithmetic mean common logarithm of viable cell count (or ATP amount) of 3 samples

As is clear from Table 2, the test sample (cloth woven with a thread made of a piezoelectric material) has a higher antibacterial effect against fungi (mold, etc.) than the standard cloth. In addition, it can be seen that the antifungal effect is higher when the test sample is vibrated than when the test sample is left standing. That is, when the test sample is vibrated to generate an electric field, a high antifungal effect is exhibited.

From the above results, it was clarified that the cloth woven with the yarn made of the piezoelectric material has antibacterial and antifungal properties.

Other fibers that generate electric charges due to external energy include, for example, a substance having a photoelectric effect, a substance having a pyroelectric effect (for example, PVDF), and the like. Further, a structure in which a conductor is used for the core yarn, an insulator is wound around the conductor, and electricity is passed through the conductor to generate an electric charge is also a fiber that generates an electric charge. However, since the piezoelectric body generates an electric field by piezoelectricity, a power source is not required and there is no risk of electric shock. In addition, the life of the piezoelectric material lasts longer than the antibacterial effect of a drug or the like. Also, it is less likely to cause an allergic reaction than a drug.

Finally, the description of this embodiment should be considered to be exemplary in all respects and not restrictive. The scope of the present invention is shown not by the above-described embodiment but by the scope of claims. Furthermore, the scope of the present invention is intended to include all modifications within the meaning and scope equivalent to the claims.

1, 2, ... Piezoelectric yarn 1A, 2A ... Piezoelectric covering yarn 3 ... Ordinary yarn 5 ... Conductive yarn 10 ... Piezoelectric film 11 ... Core yarn 100, 100A ... Cloth 900 ... Stretching direction 910A ... First diagonal line 910B ... Second diagonal line

Claims (13)

Charge-generating fibers that generate electric charges from external energy,
Conductive fibers that elute metal ions and
Equipped with a,
The charge generating fiber contains a piezoelectric material and contains a piezoelectric material.
When an external force is applied to the piezoelectric body, the electric charge is generated.
cloth. The charge generating fiber is not coated with a conductive substance.
The cloth according to claim 1. The charge generating fiber includes a core yarn and
A covering yarn in which the core yarn is covered with a substance that generates an electric charge by external energy is included.
The cloth according to claim 1 or 2. The piezoelectric body is a piezoelectric polymer.
The charge generating fiber is formed by twisting the piezoelectric polymer.
The cloth according to any one of claims 1 to 3. The piezoelectric polymer comprises polylactic acid.
The cloth according to claim 4. The charge generating fiber is
The first charge generating fiber that generates a positive charge by the energy from the outside,
A second charge generating fiber that generates a negative charge due to external energy,
The cloth according to any one of claims 1 to 5. The first charge generating fiber includes a first piezoelectric body that generates the positive charge when an external force is applied.
The second charge generating fiber includes a second piezoelectric body that generates the negative charge when an external force is applied.
The cloth according to claim 6. The first charge generating fiber and the second charge generating fiber are twisted together.
The cloth according to claim 6 or 7. The first charge generating fiber and the second charge generating fiber are arranged in parallel.
The cloth according to any one of claims 6 to 8. The first charge generating fiber and the second charge generating fiber are arranged so as to intersect with each other.
The cloth according to any one of claims 6 to 8. A garment composed of a cloth provided with charge-generating fibers that generate electric charges by external energy and conductive fibers that elute metal ions. A garment made of the cloth according to any one of claims 1 to 10. A medical member composed of the clothing according to claim 11 or 12.

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