KR20110090538A - Electromagnetic wave shielding fabric with high bio-energy radiation function - Google Patents

Abstract

PURPOSE: An electromagnetic wave shielding fabric is provided to form a far-infrared ray radiation layer on an electromagnetic wave shielding layer, thereby continuously emitting the far-infrared ray at room temperature. CONSTITUTION: An electromagnetic wave shielding layer(20) is laminated in one surface of a fabric material(10). A far-infrared ray radiation layer(30) is laminated on the other surface or fabric material or the electromagnetic wave shielding layer. The fabric material is made by a woven fabric, non-woven fabric, or macromolecular film. The composition for far-infrared radiation including binder polymer resin, far-infrared radiation component, and solvent is coated on the electromagnetic wave shielding layer or the other side of the fabric material. The far-infrared ray radiation layer is formed by drying overall structure.

Description

Electromagnetic wave shielding fabric with high bio-energy radiation function

The present invention relates to an electromagnetic wave shielding fabric, and more preferably, to an electromagnetic wave shielding fabric that can emit high bioenergy even at room temperature.

Electromagnetic waves affect various automation equipments and automatic control devices, causing malfunctions, and when infiltrated into the human body, cause various problems such as destroying biological tissue cells by high frequency energy or causing mutations and weakening immune function. In addition, due to the development of the integration technology of electronic circuits, it has become technically possible to use unit circuits having various functions in a narrow space, but at the same time, electromagnetic disturbances generated from the respective circuits between adjacent circuits have been made. Interference (EMI) is an important issue, and there is an increasing demand for products that meet Electromagnetic Compatibility (EMC).

Conventional electromagnetic wave absorbers are functional materials that attenuate radio wave energy by using high frequency loss characteristics of constituent materials or reduce reflected waves below a reference value, and according to the materials used, conductive loss materials, dielectric loss materials, magnetic loss materials, or two or more of them. Are classified as materials containing losses. The composite ferrite electromagnetic wave absorber, which is mainly used as an electromagnetic wave absorber, is a ferrite mixed with a nonmagnetic material such as silicone rubber and plastic as a support material. The composite ferrite electromagnetic wave absorber is manufactured in the form of a sheet of about 1 mm and used for anti-radar reflection in the GHz band. In addition, the electromagnetic wave shielding material is usually manufactured in the form of conductive mesh, fiber, rubber, etc. by adding metals (Fe, Cu, Ni, etc.) to the plastic. In addition, an absorbent in the form of a thick sheet of 0.2 mm or more manufactured by a method of rolling or extrusion by mixing ferrite or soft magnetic metal powder into rubber or plastic is mainly used.

On the other hand, even when using the conventional electromagnetic shielding material as described above, because the complete electromagnetic shielding is not made, especially when the electronic products such as heating mats, heating beds, sofas, etc. that are in direct contact with the user for a long time to use by harmful electromagnetic waves, etc. Electronic devices that use touch panels such as mobile phones and PDAs can cause unpleasant feelings or headaches, and can be contaminated with germs when they are operated for a long time by the user's fingers. Almost no products have additional bio-functions that can relieve user's discomfort or headache, or can continue antibacterial action semi-permanently.

The present invention is derived to solve the conventional problems, the present invention has an excellent electromagnetic shielding function, additionally continuously emits far infrared rays at room temperature and semi-permanently antibacterial, deodorizing odors such as ammonia It is an object of the present invention to provide a fabric for shielding electromagnetic waves that can implement electronic products of bio-concepts beneficial to the human body.

The present invention in order to solve the object of the present invention; An electromagnetic shielding layer laminated on one surface of the fabric substrate; And a far-infrared radiation layer laminated on the other surface or the electromagnetic shielding layer of the fabric substrate.

In the fabric for electromagnetic wave shield of the present invention, the fabric base material is preferably any one selected from woven fabric, nonwoven fabric or polymer film. In particular, the fabric substrate is more preferably a conductive fabric substrate coated with at least one conductive metal selected from the group consisting of silver, copper, nickel, gold, aluminum, cobalt, silver coated copper and silver coated nickel.

In the electromagnetic wave shielding fabric of the present invention, the electromagnetic wave shielding layer is a concept including all layers having a predetermined thickness having a function of reflecting or absorbing electromagnetic waves, and preferably, copper is plated on a fabric substrate with a thickness of 1 to 5 μm. Nickel (Ni), cobalt (Co), nickel-cobalt (Ni-Co), or nickel-iron-cobalt (Ni-Fe-Co) was electrolytically deposited on the first plating layer and the first plating layer. Or a composite layer including an electroless plated second plating layer. In addition, the electromagnetic shielding layer may be composed of a layer formed by dispersing the magnetic powder for absorbing electromagnetic waves on the polymer matrix resin, wherein the magnetic powder for absorbing electromagnetic waves is ferrite, carbonyl iron, iron-silicon alloy, iron-silicon-aluminum alloy, One or more selected from the group consisting of iron-cobalt alloys and iron-nickel alloys.

The far-infrared radiation layer in the electromagnetic wave shielding fabric of the present invention is not limited to the type or form of the far-infrared radiation radiation, so long as it can minimize the adverse effect of the human body by the electromagnetic wave, preferably binder polymer resin, far-infrared radiation component And a coating layer formed by applying a composition for far-infrared radiation comprising a solvent and a solvent on the other surface or the electromagnetic shielding layer of a fabric substrate, and drying the composition, wherein the far-infrared radiation component is 5 to 40 parts by weight based on 100 parts by weight of the binder polymer resin. The solvent is characterized in that 10 to 60 parts by weight based on 100 parts by weight of the binder polymer resin. The far-infrared radiation composition may further include 1 to 10 parts by weight of a dispersant based on 100 parts by weight of the binder polymer resin, wherein the dispersant is at least one selected from the group consisting of a wet dispersant, a silicone-based surfactant, and a fluorine-based surfactant. It is characterized by consisting of a material. In addition, the far-infrared radiation composition may further comprise 1 to 10 parts by weight of the colorant based on 100 parts by weight of the binder polymer resin.

Among the components of the composition for far-infrared radiation, the binder polymer resin is not particularly limited as long as it can maintain the far-infrared radiation component uniformly and at the same time form a layer having a predetermined thickness, and specifically, polyimide resin, melamine resin, and silicone resin. And an aqueous urethane resin, an oily urethane resin, an epoxy resin, and an acrylic resin.

 Among the components of the composition for far-infrared radiation, the far-infrared radiation component is 45 to 65% by weight of silicon oxide, 7 to 9% by weight of feldspar, 10 to 20% by weight of borax, 4 to 6% by weight of boric acid, Potassium carbonate 2 ~ 4 wt%, saltpeter 1 ~ 1.2 wt%, alumina hydroxide 3.3 ~ 6.8 wt%, limestone 1.4 ~ 1.8 wt%, barium carbonate 0.8 ~ 1 wt%, lithium 0.7 ~ 0.8 wt%, zircon 1 ~ 1.3 wt% %, 0.2 to 0.4% by weight of phosphoric acid, 3 to 3.5% by weight of carbon, 0.4 to 0.5% by weight of magnesium carbonate, characterized in that the melt, wherein the far-infrared radiation component is colored based on the total weight of the far-infrared radiation component It may further comprise 0.2 to 0.22% by weight.

Bio-energy emitting electromagnetic wave shielding fabric according to the present invention, in addition to the electromagnetic wave shielding layer (electromagnetic wave shielding layer or electromagnetic wave absorbing layer) that can reflect (block) or absorb the electromagnetic waves, additionally emits far infrared rays beneficial to the human body and has excellent antibacterial effect. And, it includes a far-infrared radiation layer that can deodorize odors such as ammonia, it is possible to implement a healthy environment for users who use electronic products that emit electromagnetic waves for a long time. In particular, the housewife who applies the bio-energy emitting electromagnetic wave shielding fabric according to the present invention or frequently contacts the electronic product emitting electromagnetic waves to electronic products such as a heating mat, a heating bed, a heating sofa, etc. used in direct contact with a user. When applied to aprons, vests, etc. for pregnant women, the effectiveness of the beneficial effect of the bio-function such as far-infrared radiation is maximized.

Figure 1 schematically shows a cross section of the electromagnetic wave shielding fabric according to an embodiment of the present invention, Figure 2 schematically shows a cross section of the electromagnetic wave shielding fabric according to another embodiment of the present invention.
Figure 3 shows the E. coli killing rate test results for the electromagnetic wave shielding fabric of Preparation Example 1, Figure 4 shows the results of a test for Pseudomonas aeruginosa killing rate for the electromagnetic wave shielding fabric of Preparation Example 1.
5 is a graph showing the ammonia gas deodorizing ability of the electromagnetic wave shielding fabric of Preparation Example 1.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the following will describe a preferred embodiment of the present invention, but the technical idea of the present invention is not limited thereto and may be variously modified and modified by those skilled in the art.

The present invention relates to an electromagnetic wave shielding fabric, and more preferably, to an electromagnetic wave shielding fabric including a bioenergy (particularly far-infrared) emitting layer at room temperature.

Figure 1 schematically shows a cross section of the electromagnetic wave shielding fabric according to an embodiment of the present invention, Figure 2 schematically shows a cross section of the electromagnetic wave shielding fabric according to another embodiment of the present invention.

As shown in Figure 1 below, the electromagnetic wave shielding fabric 100 according to an embodiment of the present invention is a fabric substrate 10; An electromagnetic shielding layer 20 laminated on one surface of the fabric substrate; And a far infrared ray emitting layer 30 stacked on the electromagnetic shielding layer. In addition, as shown in Figure 2, the electromagnetic wave shielding fabric 200 according to another embodiment of the present invention is a fabric substrate 110; An electromagnetic shielding layer 120 laminated on one surface of the fabric substrate; And a far infrared ray emitting layer 130 stacked on the other surface of the fabric substrate. In addition, although not shown in Figure 1 to 2, the electromagnetic wave shielding fabric according to the present invention is a fabric substrate; A far infrared ray emitting layer laminated on one surface of the fabric substrate; And an electromagnetic shielding layer stacked on the far infrared ray emitting layer.

1. Fabric Base

The base material is not particularly limited as long as it can laminate the electromagnetic shielding layer or far-infrared radiation layer thereon, specifically, metal foil, woven fabric, nonwoven fabric, porous sponge, mesh sheet, polymer film, etc. In particular, when the electromagnetic wave shielding fabric according to the present invention is applied in an electronic product such as a heating mat, a heating bed, a heating sofa, or an apron, a vest, or the like, it is preferably any one selected from a woven fabric, a nonwoven fabric, or a polymer film. As the metal foil, pure iron foil, iron foil, aluminum foil, copper foil, nickel foil, tin foil, tin foil, tin foil, or permalloy foil may be used. Examples of the polymer film include polyethylene terephthalate (PET) film, polyethylene (PE) film, polyimide (PI) film, polytetrafluoroethylene (PTFE) film, polyethyleneimide (PEI) film, or polyvinylidene fluoride ( PVDF) film and the like can be used. Woven or nonwoven fabrics include polyamide fibers (nylon fibers), polyester fibers, polyurethane fibers, polyurea fibers, polyethylene fibers, polyvinyl chloride fibers, polyvinylidene fibers, polytetrafluoroethylene fibers, polyvinyl alcohol fibers, Polyacrylonitrile fibers, or those formed of polypropylene fibers and the like can be used. As the porous sponge, a polyurethane foam or a natural rubber foam can be used.

A more preferred form of the fabric substrate is a conductive fabric substrate coated with at least one conductive metal selected from the group consisting of silver, copper, nickel, gold, aluminum, cobalt, silver coated copper and silver coated nickel thereon. It is done. The conductive metal coating method may include plating, vapor deposition, impregnation, and spray coating. Specific examples of conductive fabric substrates include copper (Cu), cobalt (Co), nickel (Ni), and silver (Ag). ), A conductive metal deposition layer in which a conductive metal selected from the group consisting of aluminum (Al), iron (Fe), and gold (Au) is dry deposited to a thickness of 500 to 4000 kPa is formed.

2. Electromagnetic shielding layer

The electromagnetic wave shielding layer is laminated on one surface of the fabric base material, and the electromagnetic wave shielding layer in the fabric for electromagnetic wave shielding according to the present invention includes a layer having a function of shielding electromagnetic waves in various forms such as reflecting electromagnetic waves or absorbing electromagnetic waves. Concept. Accordingly, the electromagnetic wave shielding layer according to the present invention includes various types of materials known as electromagnetic wave shielding sheets, electromagnetic wave absorbing sheets, electromagnetic wave reflecting sheets, electromagnetic wave shielding materials, electromagnetic wave absorbing materials, electromagnetic wave shielding bodies, or electromagnetic wave absorbers by conventional techniques. Can be used. The materials may be laminated on the fabric substrate by various methods such as plating, deposition, impregnation, spray coating, knife coating, roll coating, calender coating, cast coating and the like.

The electromagnetic wave shielding layer of the present invention is preferably a first plating layer in which copper is plated with a thickness of 1 to 5 μm on a fabric substrate and nickel (Ni), cobalt (Co), and nickel-cobalt (Ni-Co) on the first plating layer. Or nickel-iron-cobalt (Ni-Fe-Co) is a composite layer including a second plating layer electrolytically or electrolessly plated to a thickness of 1 to 3 μm. On the original substrate, a first plating layer in which copper (Cu) is electroplated to a thickness of 1 to 5 μm is laminated. If the thickness of the first plating layer is less than 1㎛ does not completely shield the electromagnetic wave, if the thickness of more than 5㎛ is good shielding rate of electromagnetic waves, but the increase of the electromagnetic shielding rate due to the thickness is not large increase unnecessary costs and cracks Surface defects, such as a crack, generate | occur | produce, and productability is inferior. In particular, when the base material is a conductive base material, the electrolytic plating method is used to reinforce the conductivity through the copper (Cu) electroplating layer. The reason for adopting the electrolytic plating method is that the electrolytic plating method is faster than the electroless plating method. It is because the surface resistance and the vertical resistance can be lowered through the improvement of plating adhesion and uniformity. Nickel (Ni), cobalt (Co), nickel-cobalt (Ni-Co), or nickel-iron-cobalt (Ni-Fe-Co) is electrolytic or electroless in the copper (Cu) electroplating layer. The plated second plating layer is laminated. The second plating layer is for preventing corrosion of the copper (Cu) electroplating layer and is preferably made of nickel (Ni). The electromagnetic shielding layer formed of the above composite layer has not only excellent shock and vibration absorption, plating adhesion and uniformity, and environmental friendliness, but also low surface resistance, vertical resistance, and compressive deformation. Looking at the method of forming the composite layer in more detail, the first electrolytic plating (copper electrolytic plating) is a base material of the cathode current density of 1 to 8 A / dm ² , the anode current density of 1 to 5 A / dm ² , bath 160 to 320 g / l CuSO ₄ · 5H ₂ O, sulfuric acid 22 to 60 g / l, chlorine 20 to 100 mg / l, under conditions of a bath voltage of 3 to 9 volts and a bath temperature of 20 to 35 ° C. This is done by immersing in a mixed solution of 0.01 g / l of thiourea and 0.01 g / l of dextrin. In the second electrolytic or electroless plating (especially nickel plating), the raw material substrate on which the first plating layer is formed is 18 to 45 g / l nickel sulfate, 12 to 32 g / l sodium hypophosphite and 27 to 70 g / citric acid It is carried out by dipping in 1 liter of mixed solution. The electromagnetic shielding layer thus formed has an electromagnetic shielding ratio of about 80 kHz in the frequency band of about 10 MHz to 1 kHz.

In addition, the electromagnetic wave shielding layer of the present invention is characterized in that the magnetic powder for absorbing electromagnetic waves is dispersed on the polymer matrix resin. In this case, the magnetic powder for absorbing electromagnetic waves includes at least one selected from the group consisting of ferrite, carbonyl iron, iron-silicon alloy, iron-silicon-aluminum alloy, iron-cobalt alloy, and iron-nickel alloy. In addition, the polymer matrix resin may be acrylic resin, urethane resin, melamine resin, silicone resin, fluorine resin, ethylene propylene diene monomer (EDPM), polypropylene, polyethylene, polyvinyl chloride, chlorinated polyethylene, polyvinylidenefluoride (PVDF), polyester, Polyamide, polymethyl methacrylate, and the like, and two or more polymer resins may be mixed and used. Looking at the method of forming the above-mentioned electromagnetic wave shielding layer on the base material in detail, first, a mixed slurry containing a magnetic powder for absorbing electromagnetic waves, a thermosetting polymer resin, and a solvent is prepared. In this case, the mixed slurry may preferably further include a curing catalyst such as platinum. In addition, as a solvent, methanol, ethanol, isopropanol, ethyl acetate, toluene, chloroform, xylene, benzene, dichloromethane, dichloroethane, tetrachloroethane, dichloroethylene, tetrachloroethylene, chlorobenzene, acetone, methyl ethyl ketone (MEK) , Methyl butyl ketone (MBK), methyl isobutyl ketone (MIBK), hexane and the like. The weight ratio of the thermosetting polymer resin and the electromagnetic wave absorption powder is in the range of about 1: 2 to 1: 5, and the weight ratio of the thermosetting polymer resin and the solvent is in the range of about 2: 1 to 1: 2. Planetary mixers are preferred as dispersion equipment for the production of mixed slurries. Next, a bubble is removed from the mixed slurry using a deaerator. If molding is performed without removing the bubbles contained in the mixed slurry, there is a problem of detachment of the product or dimensional instability. Thereafter, the degassed mixed slurry is applied to one surface of the fabric substrate using a molding equipment such as casting. Thereafter, the mixed slurry is cured and dried to remove the solvent to form an electromagnetic wave shielding layer. The electromagnetic shielding layer thus formed has an electromagnetic shielding ratio of about 60 Hz or more in the frequency band from about 30 MHz to 100 MHz.

3. Far Infrared Emissive layer

The far-infrared radiation layer is laminated on the original substrate or the electromagnetic wave shielding layer, and the form, the forming material, and the like are not limited as long as it can emit far-infrared rays beneficial to the human body. In the electromagnetic wave shielding fabric according to the present invention, the far-infrared radiation layer is a coating layer formed by applying a far-infrared radiation composition containing a binder polymer resin, a far-infrared radiation component, and a solvent on the other surface or the electromagnetic wave shielding layer of the fabric substrate and then drying it. to be. The composition for far-infrared radiation may preferably further include a dispersant or a colorant. Hereinafter, the composition of the composition for far-infrared radiation will be described in more detail.

(1) binder polymer resin and solvent

The binder polymer resin is a component forming the far-infrared radiation layer while keeping the far-infrared radiation component evenly dispersed, and is composed of polyimide resin, melamine resin, silicone resin, aqueous urethane resin, oil-based urethane resin, epoxy resin, and acrylic resin. It may consist of one or more resins selected from the group consisting of.

The solvent allows the far-infrared radiation component to be uniformly dispersed in the binder polymer resin, and is a component that adjusts the viscosity of the far-infrared radiation composition to facilitate the application of the far-infrared radiation composition, and is removed in the drying step of forming the far-infrared radiation layer. do. The type of solvent is not particularly limited, and specifically, methanol, ethanol, isopropanol, ethyl acetate, toluene, chloroform, xylene, benzene, dichloromethane, dichloroethane, tetrachloroethane, dichloroethylene, tetrachloroethylene, chlorobenzene, acetone, It may be composed of one or more components selected from methyl ethyl ketone (MEK), methyl butyl ketone (MBK), methyl isobutyl ketone (MIBK), methyl siloxane, hexane and the like. The content of the solvent is preferably characterized in that 10 to 60 parts by weight based on 100 parts by weight of the binder polymer resin, if the content of the solvent is less than 10 parts by weight, it is difficult to uniformly apply the composition for far-infrared radiation, more than 60 parts by weight. If the lower surface, the coating amount per unit area is small, it is not possible to form a far-infrared radiation layer of an appropriate thickness.

(2) far-infrared radiation component

The far-infrared radiation component is a component that emits far-infrared rays having a wavelength of a predetermined frequency band, and has a content of 5 to 40 parts by weight based on 100 parts by weight of the binder polymer resin. If the far-infrared radiation component is less than 5 parts by weight with respect to 100 parts by weight of the binder polymer resin, the far-infrared emission effect, the antibacterial effect, and the deodorizing effect of the far-infrared radiation layer are inadequate. This is because it is difficult to form a quality far infrared ray emitting layer and it is difficult to uniformly apply the composition for far infrared ray radiation. In consideration of the far-infrared emission effect of the far-infrared radiation layer, the antibacterial effect, the deodorizing effect, the uniform dispersibility in the composition for the far-infrared radiation, and the uniform applicability of the composition for the far-infrared radiation, the content of the far-infrared radiation component is more preferably a binder polymer. It is 10 to 30 parts by weight based on 100 parts by weight of the resin.

The far-infrared radiation component may emit far-infrared rays, and as long as it is compatible with a binder polymer resin, a solvent, and a dispersant, which is a component of the far-infrared radiation composition according to the present invention, there is no limitation in the kind thereof, specifically, silicon oxide , Feldspar oxide, borax, boric acid, potassium carbonate, saltpeter, alumina hydroxide, limestone, barium carbonate, lithium, zircon, phosphoric acid, carbon, and magnesium carbonate as a composition comprising melting the composition. At this time, the melting temperature is about 1350 ~ 1550 ℃, the far-infrared radiation component is characterized in that the composition is pulverized after cooling and finely pulverized the composition. More specifically, the far-infrared radiation component is 45 to 65% by weight of silicon oxide, 7 to 9% by weight of feldspar, 10 to 20% by weight of borax, 4 to 6% by weight of boric acid, and 2 to 2 parts of potassium carbonate based on the total weight of the far-infrared radiation component. 4% by weight, salty 1-1.2% by weight, alumina hydroxide 3.3-6.8% by weight, limestone 1.4-1.8% by weight, barium carbonate 0.8-1% by weight, lithium 0.7-0.8% by weight, zircon 1-1.3% by weight, phosphoric acid 0.2 It includes-0.4% by weight, 3 to 3.5% by weight of carbon, 0.4 to 0.5% by weight of magnesium carbonate, which may further comprise 0.2 to 0.22% by weight of the coloring agent based on the total weight of the far-infrared radiation component. At this time, the colorant includes cupric oxide, cobalt oxide, manganese dioxide, or nickel oxide, and when the manganese dioxide and nickel oxide are used as the colorant, black far-infrared radiation components are produced, and 0.1 wt% of cupric oxide and 0.1 wt. The use of ˜0.12% by weight produces a cobalt colored far-infrared radiation component, and when no colorant is added, a transparent colored far-infrared radiation component is produced.

(3) dispersants and coloring agents

Dispersants and colorants are components that can be optionally added to the composition for far-infrared radiation according to the present invention.

The dispersant may be improved depending on the purpose of addition, such as improving the dispersibility of the far-infrared radiation component, deglocking and atomizing the inorganic pigment to improve high gloss and coloring power, or improving flow and smoothness when applying the composition for far-infrared radiation. In particular, the wet dispersing agent of the product name DISPERBYK (product of BYK-Chemie GmbH, alkylol ammonium salt solution of polycarboxylic acid polymers to stericly stabilize, deagglomerate and atomize inorganic pigments), Silicone-based surfactants, fluorine-based surfactants, and the like. Silicone surfactants include graft polymers or block polymers of dimethyl siloxane and alkylene oxide, and fluorochemical surfactants include FC430 (product of 3M). The content of the dispersant is characterized in that 1 to 10 parts by weight with respect to 100 parts by weight of the binder polymer resin, if the content of the dispersant is less than 1 part by weight, the dispersing effect due to the addition of the dispersant is insufficient, and if it exceeds 10 parts by weight This is because the increase rate of the dispersion effect is not so large.

The colorant is for imparting color to the far-infrared emitting layer, and pigments or dyes may be used as the colorant. The content of the colorant is preferably 1 to 10 parts by weight with respect to 100 parts by weight of the binder polymer resin, but if it is less than 1 part by weight, the coloring effect is insufficient. .

The pigment in the colorant refers to a colorant that is insoluble in water and most organic solvents. In the present invention, the pigment is not particularly limited, and most inorganic pigments and organic pigments can be used. Pigments scatter light with particles having excellent light resistance and heat resistance, and the smaller the particles, the higher the transparency and excellent dispersion characteristics. Inorganic pigments refer to chemically inorganic pigments and are also referred to as mineral pigments. Natural minerals are produced as they are or by milling them, and metal compounds such as zinc, titanium, lead, iron, copper, chromium and aluminum are used as raw materials. An organic pigment refers to a pigment mainly composed of an organic compound, and may be precipitated by adding a metal salt or the like to a dye-soluble dye which is insoluble in water (lake). Heat resistance is not only inorganic pigment but many kinds of color and widely used for paint, plastic dyeing. Preferred pigments that may be used in the composition for far-infrared radiation according to the present invention include pearl pigments, silver particles, aluminum particles, and more specifically neodymium (Nd), praseodymium (Pr), and erbium (Er). Neodymium carbonate octahydrate (Nd ₂ (CO ₃ ) ₃ .8H ₂ O) containing rare earth elements such as), prasedium nitrate hexahydrate [Pr (NO ₃ ) ₃ .6H ₂ O], Erbium nitrate pentahydrate [Er (NO ₃ ) ₃ .8H ₂ O], kappaacetylacetonate ((CH ₃ COCHCO ₃ ) ₂ Cu), iron chloride hydrate (FeCl ₂ nH ₂ O), silver acetate (CH Transition element hydrates such as ₃ COOAg), and complex salts.

The dye in the colorant refers to a colored substance which is dissolved in water or an organic solvent, dispersed as a single molecule, combined with a molecule such as fiber, and colored. The pigment is not particularly limited in the present invention. Specifically, pigments that can be used in the composition for far-infrared radiation according to the present invention include ORIKO COLORS of Orient Chemical Co., Ltd., and various desired colors can be expressed using four basic colors of red, yellow, blue, and black.

(4) Formation method of far infrared ray emitting layer

Looking at the method of forming the far-infrared radiation layer on the base material or the electromagnetic wave shielding layer, the solvent is first added to the binder polymer resin and stirred, and then the far-infrared radiation component is added and stirred to prepare a composition for far-infrared radiation. At this time, a dispersing agent or scavenging may be added. After applying the composition for far-infrared radiation on the fabric substrate or the electromagnetic shielding layer, and heat-cured and dried in the temperature range of about 80 ~ 150 ℃ to form a far-infrared radiation layer in the form of a film of a certain thickness. As a method of applying the composition for far-infrared radiation, various methods such as knife coating, roll coating, calender coating, cast coating, spray coating, and comma coating exist, and of these, a comma coating method is preferable. In the case of coating by using a comma coater, there is an advantage that the composition for high-infrared far-infrared radiation can also be uniformly and evenly applied.

Hereinafter, the present invention will be described more clearly through specific examples. However, the protection scope of the present invention is not limited by the following examples.

Manufacturing example  One.

Copper (Cu) was deposited on a polyurethane film (fabric substrate) by vacuum sputtering to a thickness of 2300 kPa to prepare a conductive fabric substrate. The conductive fabric substrate was subjected to CuSO ₄ · 5H ₂ O 220 g / L under conditions of cathode current density 3 A / dm ² , anode current density 2 A / dm ² , bath voltage 6 volts and bath temperature 25 ° C. , Immersed in a mixed solution of 55 g / l sulfuric acid, 20 mg / l chlorine, 0.01 g / l thiourea and 0.01 g / l dextrin, and electroplating copper (Cu) on a conductive fabric substrate to a thickness of 3.5 μm. The first plating layer (copper (Cu) electroplating layer) was laminated. The conductive fabric base material on which the first plating layer was laminated was immersed in a mixed solution of nickel sulfate 27 g / l, sodium hypophosphite 18 g / l, and sodium citrate 37 g / l, to perform a second electrolytic plating (nickel plating). An electromagnetic shielding layer was formed by laminating a second plating layer having a thickness of about 2 μm on the one plating layer. Thereafter, the composition for far-infrared radiation was applied on the electromagnetic shielding layer using a comma coater, and dried and cured for 2 hours at a temperature range of 100 to 120 ° C. to form a far-infrared radiation layer.

The composition for far-infrared radiation was prepared by adding 20 parts by weight of ethanol, 10 parts by weight of far-infrared radiation components, and 3 parts by weight of a dispersant (DISPERBYK-111) to 100 parts by weight of an aqueous urethane resin. At this time, the far-infrared radiation component is 45% by weight of silicon oxide, 9% by weight of feldspar, 18.48% by weight of borax, 6% by weight of boric acid, 4% by weight of potassium carbonate, 1.2% by weight of salt, 6.8% by weight of alumina hydroxide, 1.8% by weight of limestone, A composition consisting of 1% by weight of barium carbonate, 0.8% by weight of lithium, 1.3% by weight of zircon, 0.4% by weight of phosphoric acid, 3.5% by weight of carbon, 0.5% by weight of magnesium carbonate, and 0.22% by weight of a colorant was prepared at a high temperature of 1350 to 1550 ° C. It consisted of finely ground powder after melting and cooling for ˜21 hours.

Manufacturing example  2.

The surface of the polyethylene terephthalate (PET) nonwoven fabric (fabric substrate) was ultrasonically degreased in an aqueous solution at room temperature containing stearyltrimethylammonium chloride (surfactant) and washed with water two to three times. Subsequently, the surface of the degreasing and washed raw fabric substrate was etched using caustic soda and phosphoric acid, followed by washing with water two to three times. Subsequently, after plating Co-Ni-Fe terpolymer having a composition ratio of Co: Ni: Fe on the one surface of the etched and washed fabric substrate, 13: 3: 1, washing with water and drying two to three times, is performed by about 30 to An electromagnetic wave shielding layer having a thickness of 35 μm was formed. Thereafter, the composition for far-infrared radiation was applied on the electromagnetic shielding layer by a comma coating method, and then dried and cured in a temperature range of 120 to 130 ° C. for 2 hours to form a far-infrared radiation layer.

The composition for far-infrared radiation was prepared by adding 25 parts by weight of methylsiloxane, 40 parts by weight of far-infrared radiation component, and 8 parts by weight of dispersant (DISPERBYK-111) to 100 parts by weight of the thermosetting silicone resin, followed by stirring. At this time, the far-infrared radiation component was the same as that of Example 1.

compare Manufacturing example  One.

An electromagnetic wave shielding layer was formed on the conductive fabric substrate in the same manner as in Preparation Example 1. Thereafter, 20 parts by weight of ethanol and 3 parts by weight of a dispersant (DISPERBYK-111) were added to 100 parts by weight of the aqueous urethane resin and a dispersant (DISPERBYK-111) on the electromagnetic shielding layer, and then the composition prepared by applying a comma coating method was used. Drying and curing for 2 hours at a temperature range of 120 ℃ to form a coating layer.

Experimental Example  One.

The dispersibility of the components in the process of preparing the compositions for far-infrared radiation in Preparation Example 1 and Preparation Example 2 and the applicability in the process of applying the same on the electromagnetic shielding layer were observed. In the case of Preparation Example 2, the content of the far-infrared radiation component was 40 parts by weight based on 100 parts by weight of the binder polymer resin, and in order to uniformly disperse the far-infrared radiation component in the binder polymer resin, high shear force and a lot of agitation time were required in comparison with other preparation examples. It was set as. In addition, in the case of Preparation Example 2, when the composition for far-infrared radiation was applied on the electromagnetic wave shielding layer, the surface of the coating was slightly rougher than in the case of Preparation Example 1.

Experimental Example  2.

Far-infrared emissivity and E. coli killing rate by the far-infrared radiation layer (simple coating layer in Comparative Example 1) was measured in the fabric for electromagnetic shielding prepared in Preparation Examples 1 to 2 and Comparative Preparation Example 1.

Far-infrared emissivity was measured by KS L 2514 Clause 6.4 by the Korea Institute of Construction Materials, and the emissivity was measured at the wavelength of 5 ~ 20㎛ (temperature condition is room temperature). Indicated.

E. coli reduction rate was measured by KICM-FIR-1002 method by the Korea Far Infrared Association. E. coli (ATCC 25922) was inoculated into a far-infrared radiation layer (simple coating layer in Comparative Preparation Example 1) and incubated at 37 ° C for 24 hours, and then the percentage of E. coli reduced relative to the number of initial E. coli was determined to determine the killing rate of E. coli. .

Table 1 shows the results of far-infrared emissivity and E. coli reduction.

division Far Infrared Emissivity (5 ~ 20㎛) Escherichia coli killing rate (%) Example 1 0.960 99 Example 2 0.968 99 Comparative Example 1 0.670 20

As shown in Table 1, in Preparation Examples 1 to 2, the far-infrared emissivity was 0.96 or more and E. coli killing rate was 99% or more. The far infrared radiation energy in Preparation Example 1 was 5.47 × 10 ² W / m ² .µm.

Figure 3 shows the E. coli killing rate test results for the fabric for electromagnetic wave shield of Preparation Example 1. Figure 1 in Figure 1 shows the initial E. coli number, Figure 2 shows the number of E. coli after 24 hours of culture. The initial rate of 102 was reduced to 1 after 24 hours, indicating an E. coli killing rate of 99%. Figure 4 shows the test results of Pseudomonas aeruginosa killing rate for the fabric for electromagnetic wave shield of Preparation Example 1. In Figure 2, Photo 1 shows the initial number of Pseudomonas aeruginosa, Photo 2 shows the number of Pseudomonas aeruginosa after 24 hours of culture. The initial rate of 129 was reduced to 1 after 24 hours, resulting in 99% Pseudomonas aeruginosa killing rate.

Experimental Example  3.

The ammonia gas deodorizing ability of the electromagnetic wave shielding fabric prepared in Preparation Example 1 was measured. The microwave shielding fabric of Preparation Example 1 was loaded in a sealed container having an initial 500 ppm ammonia gas concentration, and the change in ammonia gas concentration over time was observed. The change in ammonia concentration according to the natural leakage of a closed container loaded with nothing was used as a control. 5 is a graph showing the ammonia gas deodorizing ability of the electromagnetic wave shielding fabric prepared in Preparation Example 1. After 120 minutes, the ammonia gas concentration (red line in the graph) of the airtight container with the electromagnetic shielding fabric according to Preparation Example 1 was about 36%, and the deodorization rate was about 64%. The ammonia gas deodorizing effect was mainly exerted by the far infrared emitting layer.

10, 110: base material 20, 120: electromagnetic shielding layer
30, 130: far infrared ray emitting layer

Claims (13)

Fabric base material;
An electromagnetic shielding layer laminated on one surface of the fabric substrate; And
Far-infrared radiation layer laminated on the other surface or the electromagnetic wave shielding layer of the fabric base material.
The method of claim 1, wherein the base material is the electromagnetic wave shielding fabric, characterized in that any one selected from woven fabric, nonwoven fabric or polymer film.
The method of claim 2 wherein the fabric substrate is a conductive fabric substrate coated with at least one conductive metal selected from the group consisting of silver, copper, nickel, gold, aluminum, cobalt, silver coated copper and silver coated nickel thereon. Electromagnetic shielding fabric, characterized in that.
The method of claim 2, wherein the far-infrared radiation layer is a coating layer formed by applying a composition for far-infrared radiation containing a binder polymer resin, a far-infrared radiation component, and a solvent on the other surface or the electromagnetic shielding layer of the base material, and dried,
The far-infrared radiation component is 5 to 40 parts by weight based on 100 parts by weight of the binder polymer resin, and the solvent is 10 to 60 parts by weight based on 100 parts by weight of the binder polymer resin.
The method of claim 4, wherein the far-infrared radiation component is 45 to 65% by weight of silicon oxide, 7 to 9% by weight feldspar oxide, 10 to 20% by weight borax, 4 to 6% by weight boric acid, carbonic acid based on the total weight of the far infrared radiation component Potassium 2 ~ 4 wt%, salt stone 1 ~ 1.2 wt%, alumina hydroxide 3.3 ~ 6.8 wt%, limestone 1.4 ~ 1.8 wt%, barium carbonate 0.8 ~ 1 wt%, lithium 0.7 ~ 0.8 wt%, zircon 1 ~ 1.3 wt% , 0.2 to 0.4% by weight of phosphoric acid, 3 to 3.5% by weight of carbon, 0.4 to 0.5% by weight of a magnesium carbonate composition for the electromagnetic shielding characterized in that the melt.
6. The fabric of claim 5, wherein the far-infrared radiation component further comprises 0.2 to 0.22% by weight of a coloring agent based on the total weight of the far-infrared radiation component.
The method of claim 5, wherein the far-infrared radiation composition further comprises 1 to 10 parts by weight of the dispersant based on 100 parts by weight of the binder polymer resin.
The fabric of claim 7, wherein the dispersant is composed of one or more materials selected from the group consisting of a wet dispersant, a silicone-based surfactant, and a fluorine-based surfactant.
The method of claim 5, wherein the far-infrared radiation composition further comprises 1 to 10 parts by weight of the colorant based on 100 parts by weight of the binder polymer resin.
6. The binder polymer resin of claim 5, wherein the binder polymer resin is made of at least one resin selected from the group consisting of polyimide resin, melamine resin, silicone resin, aqueous urethane resin, oily urethane resin, epoxy resin, and acrylic resin. Electromagnetic shielding fabric.
The method according to any one of claims 1 to 10, wherein the electromagnetic shielding layer is nickel (Ni), cobalt (Co) on the first plating layer and the first plating layer of copper plated with a thickness of 1 ~ 5㎛ on the base material , Nickel-cobalt (Ni-Co), or nickel-iron-cobalt (Ni-Fe-Co) is a composite layer comprising a second plating layer electrolytically or electrolessly plated to a thickness of 1 ~ 3㎛ Shielding fabric.
11. The electromagnetic wave shielding fabric according to any one of claims 1 to 10, wherein the electromagnetic shielding layer is formed by dispersing magnetic powder for absorbing electromagnetic waves on a polymer matrix resin.
The method of claim 12, wherein the magnetic powder for absorbing electromagnetic waves comprises at least one selected from the group consisting of ferrite, carbonyl iron, iron-silicon alloy, iron-silicon-aluminum alloy, iron-cobalt alloy and iron-nickel alloy. Electromagnetic shielding fabric, characterized in that.

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