KR102049212B1 - A Fabric for Applying a Micro Current - Google Patents

Abstract

The present invention relates to a fabric for applying microcurrent, and more particularly, to a fabric for applying microcurrent to a human body having a structure capable of energizing microcurrent and thereby allowing contact with a human body. The microcurrent application fabric includes a conductive fiber portion 11 having a conductive layer having an electrically conductive structure formed thereon; And an insulating edge 14 formed on the circumferential surface of the conductive fiber portion 11.

Description

A fabric for applying a micro current

The present invention relates to a fabric for applying microcurrent, and more particularly, to a fabric for applying microcurrent to a human body having a structure capable of energizing microcurrent and thereby allowing contact with a human body.

In general, microcurrent refers to a current of less than 1000 mA, and a biocurrent corresponding to 40 to 60 mA in the human body flows for signal transmission between organs in the human body. As such, the bioelectric current flowing through the human body may be weakened when the state of the body becomes unstable, thereby weakening the health state. Therefore, a microcurrent for inducing the flow of the human body current flowing through the human body may be forcibly applied to the human body. The microcurrent applied to the human body is known to have an effect on the recovery of body ability while the microcurrent is effective in increasing adenosine triphosphate production, promoting fracture healing, improving blood circulation, alleviating pain, treating diabetes, treating osteoporosis, and treating arthritis. Microcurrents are also known to help prevent hair loss or treat sleep disorders. Therefore, the application of microcurrents to beds of various shapes or uses can help improve the treatment or health of sleep disorders.

The microcurrent can be applied to the human body in various ways. For example, the microcurrent can be applied by connecting a device having a contact electrode to the human body. However, this method has a disadvantage in that the contact electrode must be formed separately for the application of the microcurrent. Patent Registration No. 10-1216653, which corresponds to the prior art related to the application of microcurrents, recognizes hair loss by using a flow of microcurrents to cause a beneficial effect on a human body by causing a microcurrent to flow to a specific part of the human body. Disclosed is the prevention cap. Also, Patent Publication No. 10-2013-0104948 discloses a microcurrent control method for treating urinary incontinence and menstrual pain. However, the disclosed prior art has the disadvantage that an independent microcurrent application device must be installed. There is a need for a method capable of applying a microcurrent without the user's discomfort in everyday life or during sleep. However, the prior art does not disclose such a method.

The present invention is to solve the problems of the prior art has the following object.

Prior Art 1: Patent Registration No. 10-1216653 (Wayence Co., Ltd., December 28, 2012) Hat for preventing hair loss to induce the flow of microcurrent Prior Art 2: Patent Publication No. 10-2013-0104948 (Wayence Co., Ltd., published on September 25, 2013) Microcurrent therapy device for the treatment of urinary incontinence and dysmenorrhea

It is an object of the present invention to provide a microcurrent application fabric capable of applying a microcurrent by wearing or contacting.

According to a preferred embodiment of the present invention, the microcurrent application fabric includes a conductive fiber portion having a conductive layer having an electrically conductive structure formed thereon; And an insulating edge formed on the circumferential surface of the conductive fiber portion.

According to another suitable embodiment of the present invention, at least one resistance adjusting tab is formed in the insulating edge.

According to another suitable embodiment of the present invention, the surface resistance of the conductive fiber portion is 0.1 to 5 Ω / sq.

The fabric according to the present invention is applied to various clothes, accessories or beddings such as clothes, duvets, pillow covers, mattresses, mattresses, knee covers or masks so that microcurrents are applied to the human body in contact. The fabric according to the present invention can be applied to various types of fiber materials and can be connected to the microcurrent generator in various forms, to facilitate the installation of the microcurrent generator. For example, a microcurrent generator may be disposed inside the fabric according to the present invention, thereby facilitating the coupling of the microcurrent generator and the application means.

1 illustrates an embodiment of a microcurrent application fabric according to the present invention.
Figure 2 shows an embodiment in which the fabric for applying the microcurrent according to the present invention is applied.
Figure 3 shows another embodiment of a fabric according to the present invention.
4 illustrates an embodiment of a process in which a fabric is connected to a microcurrent generator and operated according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the embodiments set forth in the accompanying drawings, but the embodiments are provided for clarity of understanding and the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, and thus are not repeatedly described unless necessary for understanding of the invention, and well-known components are briefly described or omitted. It should not be understood to be excluded from the embodiment of.

1 illustrates an embodiment of a microcurrent application fabric according to the present invention.

Referring to FIG. 1, the microcurrent application fabric includes a conductive fiber portion 11 having a conductive layer having an electrically conductive structure formed thereon; And an insulating edge 14 formed on the circumferential surface of the conductive fiber portion 11.

The fabric may have electrical conductivity, and microcurrent may be applied to the human body by contacting the human body to a portion of the fabric. The fabric can be made from various monofilaments or multifilaments, made from natural fibers or synthetic fibers, or by blending them.

Conductive fiber portion 11 may be comprised of conductive fiber layer 12, conductive fiber nonwoven fabric, or conductive fiber rewoven. Conductive fiber layer 12 may include, for example, a base layer 121 having no conductivity; A conductive pattern layer 122 formed on one side of the base layer 121; And a protective layer 123 formed on the conductive pattern layer 122. The base layer 121 may be an insulating cotton fiber layer, a polyester or nylon fiber layer, and the conductive pattern layer 122 may be formed by printing or transferring a pattern by a conductive ink including metal particles. In addition, the protective layer 123 may have a relatively thin thickness and at the same time be formed in a coarse shape, and may be made of the same or similar material as the base layer 121. As such, the conductive fiber portion 11 may consist of multiple layers or of one layer. For example, when the conductive fiber portion 11 is in the form of a conductive fiber nonwoven, a polyester or nylon material which is a fibrous material may be made to have electrical conductivity. Alternatively, conductive metal filaments 15 may be served with warp 141 or weft 142. In detail, the metal filament 15 may be served as a weft or warp yarn in the process of being served together with the warp yarn 141 or the weft yarn 142 which is served as an insulating material. The metal filament 15 may be made of a material such as copper, stainless steel, aluminum or silver. Alternatively, the metal filament 15 may be in a form in which a mono or multi filament of polyester or cotton is coated by a conductive component.

The conductive portion in the conductive fiber portion 11 may be made in a pattern shape, for example, a plurality of conductive pattern portions CP_1 to CP_4 separated from each other may be formed. Each conductive pattern portion CP_1 to CP_4 may form one electrical resistor or one conductor. The conductive filaments forming the respective conductive pattern portions CP_1 to CP_4 may be connected to each other, for example, by the pattern forming portion 13 formed along the circumferential surface of the conductive fiber portion 11. Adjacent conductive filaments forming CP_1 to CP_4 may be connected to each other. For example, the first conducting filament CF_1 and the second conducting filament CF_2 which are adjacent to each other may be connected in parallel to each other by the pattern forming portion 13, whereby the resistance may be reduced. As such, the pattern forming portion 13 allows the resistance of each conductive pattern portion CP_1 to CP_4 to be reduced. An insulating edge 14 may be formed along the circumferential surface of the pattern forming portion 13 or the circumferential surface of the conductive fiber portion 11. The insulating border 14 may be made of insulating fiber and may have a finishing function.

According to one embodiment of the present invention, at least one resistance adjusting tab RT_1 to RT_N may be formed on the insulating edge 14.

It is advantageous for the conductive fiber portion 11 to be a conductor having a small resistance and the resistance adjusting tabs RT_1 to RT_N can have the function of the conductive fiber portion 11 to adjust the overall resistance. For example, the resistance adjusting taps RT_1 to RT_N may have a function of electrically connecting different conductive pattern portions CP_1 to CP_4. The different conductive pattern portions CP_1 to CP_4 formed in the conductive fiber portion 11 are connected in series, whereby the conductive fiber portion 11 may be electrically conductive as a whole. The resistance adjusting tabs RT_1 to RT_N may be made of a switch structure that connects or separates the conductor strips formed inside the insulating edge 14. A plurality of conductive filaments CF_1 and CF_2 connected in series with each other may be connected in parallel by the resistance adjusting taps RT_1 to RT_N.

The formation or resistance reduction structure of the conductive fiber portion 11 can be made in a variety of ways and is not limited to the embodiments shown.

Figure 2 shows an embodiment in which the fabric for applying the microcurrent according to the present invention is applied.

Referring to FIG. 2, the conductive fiber portion 11 may be formed to have conductivity, and an insulating edge 14 may be formed along the circumferential surface of the conductive fiber portion 11. The conductive fiber portions 11 can be electrically separated from one another by an electrically insulating separating strip 21. Separation strip 21 may be made of various fabrics or functional fabrics that do not have electrical conductivity. The conductive fiber portion 11 separated from each other is a microcurrent flows from the microcurrent generator connected by the 1, 2 connectors 22a, 22b and the cable CA when all the separating bins are in contact with the human body in an electrically separated state. Microcurrent may be applied to the human body. The first and second connectors 22a and 22b may be made in the form of a button and a cap, for example. Specifically, a button may be disposed in the conductive fiber portion 11, and a cap may be formed at the end of the cable CA and engaged with the button. And the button and the cap can be combined detachably.

The conductive fiber portion 11 and the microcurrent generator can be connected in various ways and are not limited to the embodiments shown.

Figure 3 shows another embodiment of a fabric according to the present invention.

Referring to FIG. 3, the conductive fabric may include a conductive fiber portion 31, wherein the conductive fiber portion 31 refers to a conductive fiber. Specifically, the conductive fabric may include a base layer 32; It may consist of a conductive fiber portion 31 formed above the base layer 32 and a functional fiber layer 33 formed above the conductive fiber portion 31. Base layer 32 may be formed of cotton fibers or similar insulating fibers, and conductive fiber portion 31 may be formed of metallic fibers or similar conductive fibers. The functional fiber layer 33 can also be formed of, for example, a fiber having an electromagnetic shielding function or having a far infrared or anion emitting function.

The conductive fibers forming the conductive fiber portion 31 may have a shape in which the metal strands 311 and the protective strands 312 made of synthetic fibers or cotton fibers are twisted with each other. The conductive strand thus formed can be covered by, for example, the protective layer 313. The metal strands 311 may be, for example, stainless steel, silver, aluminum, copper, or alloys thereof, but are not limited thereto. The conductive fiber portion 31 may be made of a structure in which, for example, polyester multifilament or nylon multifilament is coated by a carbon nato tube. The conductive fiber thus formed may have a resistance value of, for example, 10 ³ to 10 ⁷ Ω / cm. Alternatively, the surface resistance of the conductive fiber thus formed may be 0.1 to 5 Ω / sq. It is advantageous that the temperature of the conductive fiber does not change or changes in a small range with the application of the microcurrent. In the resistance values given above, for example, when a microcurrent of 200 to 800 mA is applied at 1 m 2 for 1 to 2 hours, the temperature of the conductive fiber at room temperature is varied in the range of 1 to 2 ° C.

The conductive fibers may also be subjected to plastic carbonization of acrylic or rayon, coating the surface of the organic fiber with a metal by vacuum deposition, dispersing conductive fine particles on the surface of the organic fiber, or impregnating a metal compound on the surface of the organic fiber. Can be made in a way. Alternatively, the conductive fibers may be made by dispersing the conductive fine particles to complex spinning with the organic component. Conductive fibers or conductive fiber portions 31 may be formed in various ways and are not limited to the embodiments shown.

The functional fiber layer 33 may have an electromagnetic shielding function or have a function of emitting far infrared rays or negative ions. The functional fiber layer 33 may be made by, for example, mixing conductive coating components or silver nano components or germanium components with polymer fibers or cotton fibers, or by coating. The functional fiber layer 33 may have a lower electrical conductivity compared to the conductive fiber portion 31. Alternatively, functional fiber layer 33 and conductive fiber portion 31 may be made integral.

Referring to the lower right portion of FIG. 3, the conductive fabric includes a base layer 32; A conductive pattern 35 formed on the base layer 32; And a contact layer 36 formed on the conductive pattern 35. The conductive pattern 35 may be formed in such a manner as to be printed on the base layer 32 by, for example, ink containing conductive particles. The contact layer 36 may include a plurality of separated conductive contact portions 371 and 372 formed on the conductive pattern 35 and electrically connected to the conductive pattern 35. As such, the conductive fabric may be formed in various ways or structures and is not limited to the embodiments shown.

4 illustrates an embodiment of a process in which a fabric is connected to a microcurrent generator and operated according to the present invention.

Referring to FIG. 4, the microcurrent fabric 10 may be made of one or two conductive fabrics 10a and 10b electrically separated from each other, and the one or two conductive fabrics 10a and 10b may be formed on the separation strip 21. By electrical or structural separation. The microcurrent fabric 10 may be connected to the microcurrent generator 41 by the switch module 42, and the switch module 42 may be connected to the 1 and 2 connectors made of the buttons and caps described above. Application tabs 421b and 422b electrically connected to the first and second conductive fabrics 10a and 10b by the first and second conductive strips 421a and 422a may be formed. Alternatively, the application tabs 421b and 422b may be formed directly on the first and second conductive fabrics 10a and 10b, and microcurrents may flow through the human body by the application tabs 421b and 422b. However, the application tabs 421b and 422b may be selectively formed, and microcurrents may be directly applied to the human body through the first and second conductive fabrics 10a and 10b. The application tabs 421b and 422b may have a function of allowing a microcurrent to flow to a specific part of the human body.

In the process of applying the microcurrent, the temperature of the microcurrent far end 10 may be detected by the detection module 43, and the detected temperature may be transmitted to the operation data unit 44. The operation data unit 44 can adjust the amount of microcurrent so as to reduce the temperature change and can adjust the operation of the microcurrent generator 41 based on the data thereon. The operational data unit 44 may function with the control unit.

Application of the microcurrent by the microcurrent fabric can be made in various ways and is not limited to the presented embodiments.

The fabric according to the present invention is applied to various clothes, accessories or beddings such as clothes, duvets, pillow covers, mattresses, mattresses, knee covers or masks so that microcurrents are applied to the human body in contact. The fabric according to the present invention can be applied to various types of fiber materials and can be connected to the microcurrent generator in various forms, to facilitate the installation of the microcurrent generator. For example, a microcurrent generator may be disposed inside the fabric according to the present invention, thereby facilitating the coupling of the microcurrent generator and the application means.

Although the present invention has been described in detail above with reference to the presented embodiments, those skilled in the art may make various modifications and modifications without departing from the technical spirit of the present invention with reference to the presented embodiments. . The invention is not limited by the invention as such variations and modifications but only by the claims appended hereto.

10: microcurrent fabric 10a, 10b: 1, 2 conductive fabric
11: conductive fiber part 12: conductive fiber layer
13: pattern forming part 14: insulation border
15: metal filament 21: separation strip
22a, 22b: 1, 2 connector 31: conductive fiber portion
32: base layer 33: functional fiber layer
35 conductive pattern 36 contact layer
41: microcurrent generator 42: switch module
43: detection module 44: operation data unit
121: base layer 122: conductive pattern layer
123: protective layer 141: inclined
142: weft 311: metal strands
312: protective strand 313: protective layer
371, 372: Conductive contact areas 421a, 422a: 1, 2 conductive strips
421b, 422b: Accreditation tap CA: Cable
CF_1, CF_2: 1, 2 conductive filaments CP_1 to CP_4: conductive pattern portion
RT_1 to RT_N: Resistance adjustment tap

Claims (3)

A conductive fiber portion 11 having a conductive layer formed thereon; And
It consists of an insulating edge 14 formed on the circumferential surface of the conductive fiber portion 11,
The conductive fiber portion 11 is formed of a plurality of different conductive pattern portions, and at least one resistance adjusting tab RT_1 having a switch structure for connecting or separating conductor strips formed inside the insulating edge 14. To RT_N) are formed to connect the different conductive pattern portions in series or in parallel to adjust the overall resistance of the conductive fiber portion 11,
The surface resistance of the conductive fiber portion 11 is a microcurrent application fabric, characterized in that 0.1 to 5 Ω / sq.
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