KR20130005178A - A functinal shoe sole - Google Patents

Abstract

PURPOSE: A functional shoe insole is provided to obtain dehumidifying, deodorization, and antibacterial functions. CONSTITUTION: A functional shoe insole is manufactured as follows. Biotite with 1-10 micrometer particle size range is obtained through drying, crushing, and sieving biotite. Fabric sheet dyed with biotite is obtained by pouring water and putting salt in the biotite and boiling fabric sheet. A functional fabric sheet for a shoe insole is obtained through rinsing with cold water. The functional fabric sheet is bonded to a shoe insole made of rubber or polyurethane.

Description

 A functinal shoe sole provided to absorb sweat and odor from the foot

The present invention relates to a functional shoe insole provided to absorb sweat and odor from the foot, and more specifically, using a biotite with a weathering degree of 40 to 50% to obtain a functional fabric paper with high far-infrared radiation function and adsorption, and shoes A shoe insole provided by wrapping the contents of an insole with functional textile paper.

In general, the insole that is in contact with the sole when wearing shoes is formed by injection molding of polyurethane, silicone, rubber, etc. to increase the ignition feeling, and a nonwoven fabric or cotton cloth that absorbs sweat on the upper surface. .

In the case of such a shoe insole is not able to sufficiently absorb the secretion, such as sweat secreted from the sole of the foot, which is a major cause of athlete's foot and foot odor occurs, in recent years a number of problems to solve the problems of the conventional shoe insole Techniques are being presented.

For example, when the air pump is installed in the heel of a shoe sole and the air pump is pumped by foot pressure, the shoes are discharged to the outside to improve the fit, remove foot odor, and prevent skin diseases such as athlete's foot. The insole is disclosed, but in addition to the assembly of parts of the air pump, which must be fixedly installed in the sole of the air pump, a number of manufacturing processes have to be added to increase the material cost and labor costs, and eventually increase the manufacturing cost, using shoes Even if a failure occurs during the use of the replacement was not possible to reduce the shoe function.

The cause of the imperfections and odors of the bottom of the shoes as described above is caused by the growth of bacteria and molds as the sweat comes out of the user's body and the sweat cools down. It has been developed / researched and proposed.

Looking at the prior art attempted in order to remove the dirt and smell of the bottom of the shoe in the prior art, Utility Model Registration Application No. 2000-13194 discloses a charcoal shoe insole made of charcoal bar, the strong A shoe insole made of charcoal has been disclosed for the purpose of removing foot odor and improving the health of the foot, paying attention to the air purification effect by the moisture absorption power.

In addition, Korean Patent No. 1996-9925 discloses a shoe insole containing a germanium component, which is prepared by mixing a soft resin such as PVC and EVA with a germanium emitting large amount of oxygen ions and a silicon compound emitting far infrared rays. A shoe insole is disclosed.

In addition, Korean Patent Laid-Open Publication No. 1996-28093 discloses a fragrant shoe insole incorporating a fragrance that smells like flowers or fruits inside a breathable cotton wrapper, and Korean Patent Laid-Open Publication No. 2002-44123 discloses By incorporating a functional mixture consisting of herbal medicines into a shoe insole composed of inner and outer wrappers, a shoe insole for removing foot odor and absorbing sweat, antibacterial function such as bacteria and mold, and antiseptic effect is disclosed.

However, the shoe insole has been provided with a variety of means as described above, but due to the structural characteristics of the shoe structure that the shoe structure covers the entire foot, the foot wrapped around the shoe is always outside air It is a structure that is blocked and does not have a space to absorb sweat from the sole of the foot, and is stored in shoes or insoles, so the bacteria such as bacteria are formed by the stored moisture and foreign substances, and various bacteria grow and multiply. This has not solved the problem of generating a bad odor.

Furthermore, in the shoes structure of soldiers, policemen, and construction workers, who have to wear walker or work shoes every day, a worse environment is created, and if they repeatedly wear walker or work shoes without releasing enough sweat, diseases such as athlete's foot or frostbite It caused a lot of trouble.

The present application was devised in view of the problems of the prior art as described above, the object of the present invention is to provide the anti-bacterial function while absorbing all the sweat and odor coming from the foot and the insole embedded in the footwear has dehumidification, deodorization, antibacterial function It is an invention having the purpose of providing a functional shoe insole provided.

The shoe insole provided herein does not apply the conventional method of absorbing sweat or drying feet by putting charcoal, germanium, or herbal medicines in the shoe insole as in the prior art, but boiling the fine powder with biotite in a natural dyeing process. It is possible to obtain functional textile paper with dehumidification, deodorization, and antibacterial effect by carrying out natural dyeing process by repeating the process of putting the woven fabric twisted in cotton, cotton or cotton or cotton, cotton, etc. in a dye bath several times. The present invention has a purpose of providing a manufacturing method for obtaining a functional shoe insole having dehumidification, deodorization, and antibacterial effect by applying a composite paper covering the upper and lower portions of a shoe insole sheet using the functional fabric paper.

The present application utilizes the characteristics of biotite as a means for achieving the above object, to obtain biotite in the range of 1 ~ 100㎛ particle size through the sieve (sieve) separation and drying after grinding the biotite up to 40-50% weathering degree, Pour 5 ~ 10 times water based on biotite weight and put salt of sea salt at 1/2 ~ 1/10 weight ratio based on biotite weight and put it in a boiling salt bath in a boiling salt bath for 5 ~ 10 minutes. After repeating the process of rubbing 3 ~ 5 times until it reaches room temperature, natural dyeing process is performed in which biotite adheres to all surfaces of fabric paper provided with twisted form of biotite component. Functional paper paper with dehumidification, deodorization, and antibacterial activity by means of rinsing with the biotite dyed fabric paper in cold water and then rinsing 2 ~ 4 times until clear water comes out. It get is used.

The technical idea of the present application is to obtain a shoe insole using the functional fabric paper having the dehumidifying, deodorizing and antibacterial effects, and can be used as a means of reducing the fatigue of the foot when walking for a long time by cushioning the shoe to absorb shock. When forming the normal shoe insole shape using cork, polyurethane, latex, silicone, etc., the work process of wrapping the outer sole of the insole using the functional fabric paper obtained in the above process with the outer material or the synthetic leather of the shoe insole. The invention is completed by confirming that it can provide a shoe insole with far-infrared radiation function and adsorption function and antibacterial function.

The shoe insole disclosed in the present application obtains biotite having a particle size ranging from 1 to 10 μm through sieve separation by pulverizing biotite having a weathering degree of 40 to 50%, and water of 5 to 10 times based on biotite weight. Pour and add salt of sea salt in 1/2 ~ 1/10 weight ratio based on biotite weight and boil it in boiling molten cloth or cotton cloth or wool and boil it for 5-10 minutes. Repeat the process of rubbing 3 ~ 5 times until it gets the fabric paper dyed with biotite, and rinse the fabric paper dyed with biotite in cold water and rinse it 2 ~ 4 times until clear water comes out. Step 1 work process to obtain functional fabric paper for shoe insole, and obtain the shoe insole using rubber, polyurethane or silicone in the usual way, and use the functional fabric paper obtained in the first step work process to the insole of the shoe insole. Through the second step work process of wrapping and bonding, a shoe insole having far-infrared radiation function, adsorption function and antibacterial function can be obtained.

In the second step of the work process, the adhesive for wrapping the textile paper on the shoe insole material has a weathering degree in the range of 40-50% to aqueous or oil-based adhesive and biotite in the range of 1 to 10㎛ particle size in the range of 20 to 30% by weight of the adhesive weight. When used in combination, it is possible to obtain a shoe insole exhibiting the best physical properties to achieve the objectives of the present application.

In addition, the present invention is characterized in that the natural dyeing process is carried out using a woven fabric woven in the state of cotton, cotton or cotton, cotton, cotton, etc., for example, chemical fibers or synthetic fibers, polyimide, polyethylene Fabrics in which weaving / providing polyester, ethylene vinyl acetate, ethylene acrylic or copolymers thereof in a straight form without twisting by injection or linear melt spinning do not provide space for the biotite dye component provided herein to be adsorbed or impregnated. In case of the first natural dyeing process, dyeing is done smoothly, and rinsing is performed about 4 times when rinsing the fabric paper dyed with biotite in cold water, it shows dehumidification, deodorization, and antibacterial effect. Significantly far-infrared radiation when washing is done for reuse after a period In order to apply chemical fiber such as nylon and polyester to the technical concept of the present application because it exhibits a drop in function, odor absorption function and antibacterial function, weathered biotite is pre-blended in the raw material mixing process when melt spinning. If it does not, simply relying on the means of carrying out the natural dyeing process may fail.

Biochemicals of biotite are minerals represented by K (Mg, Fe) 3AlSi ₃ O ₁₀ (OH) _2. They form a plate or impression and often represent hexagons or rhombohedrons. The cleaved surface has pearl gloss, sometimes metal gloss, hardening 2.5-3.0, specific gravity 2.7-3.1, produced from igneous rocks and metamorphic rocks, and huge paurite crystals can be obtained from pegmatite.

Weathering is the process by which rocks are broken into soil by physical or chemical reactions. When rocks are exposed to the surface, hard rocks are converted into soil through chemical and physical weathering by air, water, and plants and animals. It can be said that the biotite used in the present application can be seen that if the mining used in the underground just because the adsorption function, antimicrobial function is significantly lowered because the biotite is mined in a sunny place when When the weathering degree meets the conditions of 40 ~ 50% through the weathering process that blows wind in the sunlight for 2 ~ 4 weeks, it shows the optimal far-infrared radiation function, odor absorption function and antibacterial function. I could confirm it.

Far infrared rays are infrared rays having long wavelengths in the range of 5.6 to 1000 µm among non-visible rays of light, and far infrared rays in the range of 6 to 14 µm are known to be beneficial to the human body, and the effect of far infrared rays on the human body is to promote blood circulation (blood flow). Speed increases) to maintain body temperature, enhance metabolism, improve fatigue, promote digestion and help relieve stress, and also increase energy to improve biorhythms and grow It is known to promote pain relief, increase body flexibility, antibacterial, deodorant and insect repellent effects to remove odors, inhibit the growth of fungi, and prevent the growth of fungi. .

The shoe insole manufactured according to the technical idea of the present invention was commissioned by the Korea Institute of Construction Materials for the antibacterial test, the antifungal test, the deodorization test, the far infrared test, etc., and the effect was confirmed. As a result, the far infrared radiation energy was measured. The result was 3.64 × 10 ² W / ㎡ at the temperature of 40 ℃ and the measurement wavelength of 5 ~ 20㎛, and the far infrared radiation energy at the measurement temperature of 45 ℃ and the measurement wavelength of 5 ~ 20㎛ was 3.9 × 10 ² W / ㎡. In addition, in the deodorization test conducted according to the KICM-FIR-1085: 2010 test method based on ammonia (NH ₃ ), the deodorization rate 61.5% at 60 minutes elapsed time, and the deodorization rate 69.7% at 90 minutes elapsed time, 120 minutes Deodorizing effect of 75.1% deodorization rate was confirmed in the elapsed time.

1: Application example of the air flow classifier shown to obtain a fine particle size biotite here.
2: Antibacterial test result data for the shoe insole made by the method of the present application.
Figure 3: Antifungal test result data for the shoe insole made by the method of the present application.
4: Deodorization test result data for the shoe insole made by the method of the present application.
5: Far-infrared emissivity and radiation energy measurement data for the shoe insole made by the method of the present application.
6: Summary data of the test results for biotite natural dyeing insole of the present application notified to the applicant from the Korea Institute of Construction Materials.

Hereinafter, embodiments of the present invention for implementing the technical idea of the present application will be described. The following descriptions illustrate one application example for implementing the technical idea of the present invention, which should not be construed as being limited thereto. It should be understood that the scope of protection of the present application should be interpreted as meanings and concepts corresponding to the technical spirit of the present invention, and that there may be various equivalents and modifications that may substitute them at the time of the present application.

In addition, the examples described herein describe the best examples in the range that meets the level of results desired by the inventors through numerous trial and error, and the ranges indicating the upper and lower limits of the numerical values are set to the upper and lower limits of the numerical values set forth. In the case of deviation, it should be recognized that the inventors are determined values because they cannot achieve or lack the desired purpose.

Applicant digging into the depth of about 2 meters from the ground to the bottom of the biotite mine, Boeunjik-dong, Bonghwa-ji, Gyeongsangbuk-do, Korea, to collect biotite with a purity of 80-85, and to obtain biotite with a weathering degree of 40-50%. After drying for 3 to 4 days in the grinding using a hammer mill grinder and using the air flow classifier shown in Figure 1 to obtain biotite of 1 ~ 10㎛ particle size range shoes having antibacterial function, deodorizing function, far infrared radiation function It was intended to be used as a raw material for obtaining the insole.

The air flow classifier shown in FIG. 1 includes two high-pressure gas (10, 20) for supplying air or nitrogen fluid and a raw material supply unit (30) into which biotite pulverized products are fed as a fractionation device for obtaining microparticles of biotite. It can be applied to the air classifier 50, the body 51 of the air classifier 50 is made of stainless steel SUS 303 or 314 material, the biotite flowed into the air classifier on one side of the air classifier The high pressure air tank 10 or the liquid carbon dioxide tank 20 may be used as a transfer fluid that functions to disperse / disperse the pulverized product. The high pressure air tank 10 is filled with compressed air from a compressor and has a high pressure air. It is provided to have a plurality of injection nozzles 12 in order to increase the dispersion / scattering effect of the biotite pulverization when injecting high pressure air to the air flow classification device 50 through the on-off valve 11, and also the liquid carbon dioxide tank 20 Degree When the carbon dioxide gas is supplied to the air flow classifier 50 through the closed valve 21, the carbon dioxide gas is sterilized / sterilized when the biotite pulverized product passes through an UV infrared lamp or a halogen lamp in the air flow classifier. It is provided to perform a function that prevents biotite from being deteriorated by thermal energy.

In addition, the upper part of the inlet of the air flow classification device of the present invention has a hopper 31 for accommodating biotite powder obtained in the crushing process, and the inside of the hopper distributed feed roller for evenly feeding (feeding) biotite powder to the air flow classification device ( It is connected to the raw material input part having 33a, 33b and the supply shutoff valve 32 to adjust the rotational speed of the distributed feed rollers 33a, 33b and perform air flow classification.

In addition, the bottom of the air flow classification device 50 has a discharge means 52 for discharging the fractions of the biotite by particle size, and the UV infrared lamp 53 and the halogen lamp 54 on the side of the air flow classification device. It is provided to perform sterilization function by irradiating infrared rays to the conveyed biotite crushed instantaneously, and at the end of the air flow classifier, a propeller 55 capable of adjusting the wind speed and direction is installed to raise or lower the discharge pressure of the air volume. It shows the configuration provided to be carried out.

In the present application, only the main part of the air flow classifier 50 is illustrated to avoid the complexity of the technical configuration, but the biotite fine powder 56 passing through the propeller 55 provided at the end of the air flow classifier may collect the air stream discharged again. It is installed to collect all by connecting the cyclone facility can be applied as a device for obtaining nano-scale biotite.

Accordingly, the biotite pulverized product is accommodated in the raw material input portion of the air flow classifier, and high pressure air is supplied to the airflow classifier 50 through the high pressure air open / close valve 11 through a plurality of injection nozzles 12. When air or carbon dioxide gas passes through the air flow classification device 50, the rotational speed of the raw material supply and dispersion supply rollers 33a and 33b is controlled, the object to be sorted is introduced, the air flow classification is performed, and the size fraction of the biotite powder is obtained. For example, a pulverized product of 200 μm or more may be obtained through the path of the discharge means 52-a, and particles in the range of 100 to 200 μm may be obtained through the path of the discharge means 52-b. And particles in the range of 50 μm to 100 μm can be obtained through the path of the discharge means 52-c, and particles in the range of 1 to 50 μm can be obtained through the path of the discharge means 52-d. The path of each discharge means 52-a, a path of discharge means 52-b, The fractions to be fractionated through the path of the discharge means (52-c) c, the path of the discharge means (52-d) d, and the fractions are applied by particle size separation to discharge to the outside through the transfer conveyor 1 ~ 10 It shows by showing that the biotite of the micrometer range can be obtained and used.

1. Example of obtaining functional textile paper

Pour about 5 liters of biotite with a weathering degree of 40-50% through the air flow classifier shown in FIG. 1 into 50 kg of biotite classified in the range of 1 to 10 μm particle size, and also boil 5 kg of natural salt. Boil the fabric paper provided with cotton in a boiling molten metal and boil it for 5 to 20 minutes, take out the fabric paper from the molten metal, rub it with your hands until it reaches room temperature, and impregnate the biotite three times to obtain fabric paper dyed with biotite. The fabric paper dyed with biotite was rinsed in cold water, but rinsed four times until clear water was obtained to obtain functional textile paper for shoe insoles.

In the description of the above example, a specific number was used, but the process was poured in 5-10 times water based on the biotite weight, and the salt salt was added while boiling in a 1/5 to 1/20 weight ratio based on the biotite weight basis. Put the tissue paper in a boiling salt bath and boil it in the range of 5 to 10 minutes, and then rub it 3 to 5 times until it reaches room temperature. It can be applied as a natural dyeing process in which biotite adheres to the surface. Dehumidification by means of rinsing the fabric paper dyed with biotite in cold water and then rinsing 2 to 4 times until clear water comes out Functional textile paper having a deodorant and antibacterial effect can be obtained.

2. Example of Obtaining Shoe Insole Using Functional Fabric Paper

In general, to obtain a shoe insole material in the front portion is provided with a thickness of 3 ~ 5㎜ and the back portion is provided in a polyurethane shoe insole material provided in the process by using the functional fabric paper obtained in the process as an outer covering material. The adhesive work process that wraps the shoe insole material can be selected from the aqueous adhesive or the oil-based adhesive, and since the oil-based adhesive may cause skin trouble, it is preferable to use the aqueous adhesive, and the applicant is recommended by Myung-Kwang Chemical Co., Ltd. 7.5 kg of an aqueous latex adhesive produced / sold is prepared using an adhesive comprising 2.5 kg of biotite classified in the range of 40 to 50% obtained in the above process and classified into a particle size range of 1 to 10 µm. Biotite 2.5 with 7.5 kg of oil-based PU adhesive produced / sold in the above) and the weathering degree obtained in the above process ranged from 40 to 50% and the particle size ranged from 1 to 10 ㎛ particle size range. Applied to the shoe insole material with an adhesive formulation, and the case that the functional jikmulji wrapped in both water-based and oil-based adhesive mixed with biotite was confirmed that it is possible to achieve the object of the present application.

Applicant is a means to check the dehumidification, deodorization, and antibacterial effect of the shoe insoles provided at the beginning of the present application, the factory of the applicant's company's factory is a natural dyeing company usually uses a lot of water because the normal As a result of wearing and working, a means of requesting cooperation from 5 workers to use the shoe insole provided by applying the technical idea of this application to the inside of the boot and wearing the resultant state and the shoe insole into the boot after 1 week. One week after the result was compared to compare the results, when wearing the shoe insole provided in the rain boots in the summer, difficult field work to boil water, perform the bibim process and rinse process is performed Even if your feet are in a state of no sweating, while wearing socks in a soft state, After being worn for a week, it was confirmed that the shoe insole did not smell bad.If the shoe insole of the present application was applied without wearing boots, the socks were soaked with sweat even during the morning work of the day. It is necessary to replace the socks twice a day, and it is possible to identify the phenomenon that is different from the fact that odor occurs inside the boots, and objectively check the characteristics of the shoe insole provided by the manufacturing method of the present application. As a means of receiving, we requested the antimicrobial test, antifungal test, deodorization test and far-infrared radiation test for biotite natural dyeing insole provided by applicant.

The results of the test report notified to the applicant from the Korea Institute of Construction Materials after three months of test results were submitted to E. coli (Escherichia coli ATCC 25922) and Pseudomonas aeruginosa. ATCC 15442), the bacterium reduction rate of Trichophyton rubrum ATCC 28188 showed that B. E. coli increased the number of bacteria after 24 hours, and the sample [Biotite natural stained insole] decreased the number of bacteria after 24 hours, resulting in 99.9% of bacteria. In the case of Pseudomonas aeruginosa, BLANK increased the number of bacteria after 24 hours, and the sample [Biotite Natural Dyeing Insole] decreased the number of bacteria after 24 hours, and 99.9% of bacteria decreased. The number of bacteria increased afterwards, and the sample [Biotite Natural Dyeing Insole] showed a decrease of 99.9% of bacteria after 24 hours. It has been informed.

In addition, the antifungal test result was informed that the antifungal test result on the requested sample [biotite natural dyeing insole] that the development of hyphae was not recognized in the inoculated part of the test specimen for 1 to 4 weeks. Deodorization rate of the sample [Biotite Natural Dyeing Insole] was tested for ammonia, methylmercaptan and acetaldehyde gas, and showed a deodorization rate of 75.1% compared to BLANK after 120 minutes for ammonia and BLANK for 120 minutes after methylmercaptan. The deodorization rate was 70.6%. It was informed that acetaldehyde gas had a deodorization rate of 19.8% compared to BLANK after 120 minutes.

In addition, the results of far-infrared tests showed far-infrared emissivity and radiation energy at 40 ℃ and 45 ℃, respectively, for the requested sample [Biotite natural dyeing insole], and the far-infrared emissivity at 40 ℃ was 0.903 compared to the black body. Radiation energy was 3.64 × 10 ² . The far-infrared emissivity at 45 ℃ was 0.902 compared to the black body, and the far-infrared radiation energy was reported as 3.90 × 10 ^{2. The} evidence for the test results reported by the Korea Institute of Construction Materials was attached to the drawings. It was.

When the test result data reported from the Korea Institute of Construction Materials is classified and explained in the accompanying drawings, the data presented in FIG. The data presented in Figure 2b is a comparative test data for E. coli, the data presented in Figure 2c is a comparative test data for Pseudomonas aeruginosa, the data presented in Figure 2d is a comparative test data for Bacillus pneumoniae .

The data presented in Figure 3a is Aspergillus niger ATCC 9642, Penicillium pinophilum ATCC 11797, Chaetomium globosum ATCC 6205, Gliocldium virens ATCC 9645, Aureobasidium pullulans ATCC 15233 The antifungal effect test in the mixed fungal strains, and the data presented in Figure 3b is a photographic data of the antifungal test.

The data shown in Figure 4a is a deodorization test data for ammonia (NH ₃ ) gas, the data shown in Figure 4b is a deodorization test data for methylmercuptane (CH ₃ SH), the data shown in Figure 4c is acet Deodorization test data for aldehyde (CH ₃ CHO), the data shown in Figure 4a is a deodorization test data for ammonia (NH ₃ ) gas.

The data presented in Figure 5a is a result of the far-infrared emissivity and radiation energy measured by the shoe insole provided herein at the measurement temperature 40 ℃ and 45 ℃, the data presented in Figure 5b represents the far infrared emissivity at the measurement temperature 40 ℃ 5C is a graph showing far-infrared radiation energy at a measurement temperature of 40 ° C., and the data shown in FIG. 5D is a graph showing far-infrared emissivity at a measurement temperature of 45 ° C., and the data shown in FIG. Graph showing far-infrared radiation energy at temperature 45 ℃

Figure 6 is a summary of the test results for biotite natural dyeing insole of the present application notified to the applicant from the Korea Institute of Construction Materials.

The shoe insole provided by the technical concept of the present application from the above description is provided with far-infrared radiation function, absorbing function and antibacterial function, and when provided in the shoe, it is sufficiently effective as a functional shoe insole absorbing sweat and odor in the shoe. You can check the facts.

10: high pressure air tank 11: high pressure air on-off valve
12: injection nozzle 20: liquid carbon dioxide tank
21: CO ₂ opening and closing valve 30: raw material supply
31: Hopper 32: Supply shutoff valve
33: distributed feed roller 50: air flow classification device
51: air flow classification device body 52: discharge means
53 UV lamp 54 Halogen lamp
55 propeller 56 biotite derivative

Claims (3)

In the method of manufacturing a functional shoe insole that is provided to absorb the sweat and odor the insole built into the footwear,
The biotite with a weathering degree of 40 to 50% is dried and pulverized to obtain biotite in a particle size range of 1 to 10 μm through sieve separation. Pour 5-10 times water on the basis of the weight of biotite and add 1 on the basis of the weight of biotite. Put the salt of the sea salt at a weight ratio of 2 ~ 1/10 and boil it while boiling it in boiling water for 5 ~ 20 minutes and then boil it until it reaches room temperature. Repeated ~ 5 times to obtain a fabric paper dyed with biotite, rinse the fabric paper dyed with biotite in cold water, and rinsing 2 to 4 times until clear water comes out to obtain functional fabric paper for shoe insoles One step work process;
A second step working step of obtaining a shoe insole material using a rubber, polyurethane, or silicone material in a conventional manner and wrapping and bonding the shoe insole material with the functional fabric paper obtained in the first step working process; Shoe insole manufacturing method characterized in that it is provided to have a far-infrared radiation function and adsorption function and antibacterial function. The method of claim 1,
In the second step of the work process, the adhesive wraps the outer shell on the shoe insole, and the adhesive has 70 to 85 parts by weight of aqueous or oily adhesive, and has a weathering degree in the range of 40 to 50%, and a biotite having a particle size in the range of 1 to 10 μm of 15 to 30 parts by weight. Shoe insole manufacturing method characterized in that it is used in combination. A functional shoe insole that is embedded in footwear and provided to absorb sweat and odors,
Drying and pulverizing biotite with a weathering degree of 40-50% to obtain biotite in the range of 1 ~ 10㎛ particle size through sieving, pouring 5 ~ 10 times water based on biotite weight and 1/2 ~ based on biotite weight basis Put the salt of sea salt in 1/10 weight ratio and put it in a boiling salt bath while boiling it, put it in a boiling salt bath, boil it for 5 to 20 minutes, and rub it until it is room temperature. Rinse two to four times until cold water comes out using cold water to obtain functional textile paper for shoe insoles, and functional textile paper for rubber, polyurethane, or silicone shoe insoles provided by conventional methods. The adhesive is bonded to 70 ~ 85 parts by weight of aqueous or oily adhesive and 40 ~ 50% of weathering degree and 15 ~ 30 parts by weight of biotite in 1 ~ 10㎛ particle size range. Far-infrared ray radiation function and heupchwi function, the functional shoe insole being provided so as to have antimicrobial properties.

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