KR101003674B1 - Deposition and Coating Method of Nano Far Infrared Radiation - Google Patents

Abstract

PURPOSE: A deposition and coating method of nano far infrared ray emitter is provided to impart sterilization, antibiotic and fat infrared ray radiation effects by configuring an antibacterial clothing coating emitter with excellent safety by nanosilver dispersant. CONSTITUTION: A deposition and coating method of nano far infrared ray emitter comprises the steps of: heating and drying aluminum silicate at 600-800°C, and pulverizing it to 3000-3500mesh(45μm) to obtain aluminum silicate powder; drying illite at 100°C and pulverizing it to 35-40μm to obtain illite powder; mixing aluminum silicate powder 70 weight% and illite powder 29.98-29.99 weight% to prepare sample 99.98-99.99 weight%; and mixing nanosilver sample 0.01-0.02 weight%, adding a softening agent, and depositing clothing and heating it.

Description

Deposition and Coating Method of Nano Far Infrared Radiation

The present invention provides an antimicrobial antimicrobial garment deposition coating composition excellent in antimicrobial far-infrared radiation and silver nano dispersion having antimicrobial and bactericidal effect against many kinds of bacteria and fungi in the method of manufacturing, depositing and coating far-infrared radiation. The present invention relates to a deposition coating method of silver nano far-infrared radiation, which is a material that penetrates and coats clothing, health clothing, and the like made of a textile fabric.

In general, a number of applications using the far-infrared emitter or silver nano-coating have been applied and published, among which 10-0512599 anion-releasing and far-infrared radiation-inorganic ceramic composition is composed of a binder, a powder silicon oxide, and water which acts as a silane or a binder derived therefrom. Powdered functional filler and quartz monzonite gneiss and rhyolite rock Like this, it is composed of proper wt% of a mixture of a functional filler in the form of one natural color selected from the group of natural minerals, a ceramic powder composed of an infrared emitter and an anion emitter selected from the gneiss and rhyolite natural minerals 3 levels of configuration One would Girona,

A method for preparing an antimicrobial agent includes a metal having an antimicrobial action on an N-long chain acyl amino acid directly attached to a surface of an inorganic particle or a synthetic resin particle by a hydrophilic organic material, and contacting with an N-long chain acyl amino acid ion-containing aqueous solution. After the process and the contact process, the particles are contacted with a metal-containing aqueous solution having an antimicrobial effect.

In addition, 10-2003-0090880 discloses a method for treating far-infrared radiation in which silicon, aluminum, magnesium iron oxide, potassium, sodium, ocher, etc. are formed in an appropriate amount, but mixed with 60% of a catalyst liquid composed of kaolin and loess, and a softener 40%. The fabric was dipped into one fabric so that the mixture of catalyst and softener was penetrated and deposited on the fabric, and the mixed liquid of dye and catalyst was treated by heat treatment and drying through a dyeing process.

However, the above-described structure is fabricated by depositing the fabric fabric on a solution mixed with 40% of a catalyst liquid 60% softener composed of silicon, aluminum, magnesium oxide, magnesium oxide, potassium, sodium, ocher, etc., and mixing dye and catalyst solution. The main purpose of this is to dye and heat treatment and dry treatment, there is a problem that it is somewhat unsuitable as far-infrared radiation that requires non-toxic because it is not a silver nano-addition of silver particles.

The present invention, unlike the conventional configuration described above, in the process of manufacturing or composition of the far-infrared radiation itself, should be composed of finely pulverized raw materials, etc. consisting of sodium, iron, calcium, magnesium, etc. When the solution is mixed with a solution containing nano silver and penetrated into a textile fabric or clothing health suit, the solution should not be washed away when the coating is deposited. In particular, it is necessary to solve the problem that far-infrared radiation (emission) effect, which is useful for the biological rhythm of the human body, as well as deodorization such as antibacterial, anion generation, sweat odor, etc. to skin diseases, should be solved.

In other words, silver (colloidal silver), in particular colloidal silver (Colloidal 銀) has been focused on the effect of eradicating more than 600 kinds of bacteria in a short time without side effects, the recognition of the above effect is already commonplace at home and abroad is known. (The US FDA has allowed the sale of silver-based drugs: predominantly antibiotic silver.)

In the composition of the far-infrared radiant herein, the object is to produce a far-infrared radiant that can be used as an additive composition in the preparation of a composition that can be deposited on a textile fabric.

The present invention is configured to use as an antimicrobial additive composition that penetrates and deposits far-infrared material and clothes in the yarn, fabric, and clothing of the fabric in the conventional method, unlike liquid emitters made of powder, liquid or gel samples It is composed of so that it has excellent far-infrared radiation, antibacterial and bactericidal effect on clothing,

Aluminum silicate containing components such as magnesium, potassium, calcium, silicon, iron and sodium, which can be used by drying the aluminum silicate having the above components. It is pulverized to 3,500 mesh, and the aluminum silicate is composed of mud-like raw material , which is dried, pulverized, and heated. Do,

Silver nanoparticles are manufactured in two ways. First, a silver plate is provided as a positive electrode in an electrolysis process, and a high voltage is applied. However, silver nanoparticles of 5 nm or less are produced and controlled by microcurrent, and second, silver nanoparticles. AgNO ₃ and PVP are mixed with EG and stirred to heat the mixture, and then heated to 100-140 ° C., cooled to normal temperature, distilled water is diluted, filtered and washed in a filtration apparatus, and a concentrate is prepared. Either of the two methods can be implemented in the present invention, the following description of the present application will be described by the latter method with good safety of uniform dispersion.

As a method of composition of nano-silver clothing, which is composed of nano silver clothing, which emits far-infrared rays, antibacterial and anti-discoloration, and nano-silver, which is added with 0.01-0.02% by weight of nano silver, A composition composed of a combination of silver nano, aluminum, magnesium, potassium, calcium, silicon, iron, and sodium with an appropriate amount of natural aluminum silicate and illite is mixed with a softening agent, and then penetrated into clothing and health clothing made of fabric. Or by coating the health clothing to prepare a composition to obtain the efficacy of the silver nanoparticles in the radiant and the composition of the composition as a penetration coating agent.

Here, the radiation of far-infrared radiation not only has antibacterial effect but also promotes active activities in preventing corruption and promoting blood circulation, and looking at the nature of far-infrared rays, about 80% of light energy occupies about infrared rays, based on 4㎛. The short side is called near-infrared and the far side is far-infrared. There are three types of heat conduction methods: convection, conduction, and radiation. Infrared rays transmit heat by radiation. Radiation is a convection that indirectly propagates heat, such as air and water, and unlike heat conduction, radiation has a very good thermal efficiency by directly transferring heat to an object.

The present invention as described above is used to penetrate and coat the fabric fabric is used for wearing and wearing the coating before making the sterilization, bacteriostatic, antibacterial action as well as bedding, clothing, etc. by adding nanosilver. It is beneficial to health by activating a biorhythm that affects the physiology of the human body due to the large amount of far-infrared radiation, and by adding and mixing silver nano, it is treated according to the present invention by sterilization, antibacterial and anion generation for various bacteria. When exercising with clothing and health clothing, it can play a role in preventing premature fatigue and is effective in improving the user's health.

1 is a schematic diagram of the present invention

70% by weight of aluminum silicate containing iron, magnesium, sodium, potassium and calcium silicon, which are substances that affect the human body's biological activities due to the emission of far infrared rays, dried at 100 ℃ and then crushed into particles of 35-40㎛ size Sample 1 (Example 1 process base material) was prepared by filtration with fine polar fine powder (3000-3500 mesh) at a ratio of 30% by weight of illite.

When the aluminum silicate is mined, it is heated to about 600 ~ 800 ℃ as the dough phase of the mud, but it is indirectly heated so that it does not directly touch the ore. After cooling, only the pure aluminum silicate is obtained through the screening removal process. The light is also indirectly heated to a temperature of 100 ℃, then cooled and dried before being crushed into 35-40㎛ particles.

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In order to further increase the emission effect of far infrared rays by containing silver processed silver nanoparticles into fine particles in sample 1, sample 3 is prepared by mixing sample silver having 0.01-0.02% by weight of nanosilver.

The far infrared radiation test prepared from sample 3 is shown in the table below.

Test 1

1) Test Method: KFIA-FI-1005

2) This test was conducted at 37 ℃, and the result was measured by BLACK-BODY using FT-IR Spectrometer.

It is the result of depositing sample 3 in the diet health suit in the test.

The following is an anion (ION / CC) generation test table

Test 2 (anion release test)

1) Test Method: KFIA-FI-1042

2) Test piece: 100 × 150mm

3) Tested under the condition of room temperature 21 ℃, humidity 30%, and anion water 102ion / cc using charged particle measuring device. It is the result of measuring the anion emitted from the object to be expressed as ION per volume.

Test 3 (antibacterial test)

(Note) The number of bacteria on the medium is calculated by multiplying the dilution factor.

1) Test Method: KS K0693-2001

2) Number of bacteria used: Staphy lococcus aureus ATCC 6538

               Klebstells Pneumoniae ATCC 4352

3) Nonionic Surfactant: 0.05% nonionic surfactant is used for inoculating bacteria (Sonogen)

4) Standard cloth: KSK 0905 Dyeing fastness

Exam 4 (Deodorization Test)

(Note) Blank: Measured without sample

1) Test Method: KFIA-FI-1004

2) Test gas name: Ammonia

3) Gas concentration measurement: gas detector

The above tests were conducted by Korea Far Infrared Applied Evaluation Institute

The radiant of the sample prepared as described above penetrates into the woven clothing as a liquid phase, so that the absorption is well conceived. For example, if the health clothing as in the test is deposited on the far-infrared radiation, the surface of the health clothing is allowed to elapse for a certain time. Of course, it is absorbed and deposited onto the inside, whereby the constituents of the composition deposit the health clothing with the softener in a ratio of 30% by weight to 70% by weight of the sample to give the softness of the health clothing. When the time of 15 to 20 minutes elapses at a temperature of ˜120 ° C., immersion implantation is completed and dried again at room temperature, thereby completing.

In the deposition process, the heat treatment temperature needs to be adjusted according to the health clothing, and the heat treatment process is carried out by the deposition of the silver nanoparticles added to the clothing by the deposition on the sweat caused by excessive exercise when worn or winter climate change, In the repeated washing process, there is no alteration of the texture or properties of clothing, and in particular, it prevents the detachment of the far-infrared radiation that is infiltrated and prevents the antibacterial, sterilization and static electricity generation by far-infrared and anion radiation, as well as the beneficial function of far-infrared radiation. You get clothing,

1 step

Aluminum silicates containing iron, magnesium, sodium, calcium, potassium, and silicon, which are beneficial to the human body and have an essential effect on biological activity. (Aluminum silicate is a compound of alumina and silicic anhydride. It is usually weathered in feldspar in mud rock. Ash, white), which is heated to 600-800 ° C, dried, and then pulverized to 3000-3500 mesh, and the illite used for pigments, paint linoleum, etc. is mixed in an amount of 70: 29.98 to 29.99% by weight. Sample 1 is composed by drying the illite at 100 ° C. and then crushing it into particles having a size of 35-40 μm.

2 process

In order to add 0.01 to 0.02% by weight of silver nanoparticles, silver nanoparticles were prepared by mixing silver nitrate (AgNO ₃ ) and polyvinyl pyrrolidone (PVP) with ethylene glycol (EG), followed by heating to 100-140 ° C. After reducing to normal temperature, distilled water was added, washed with a filtration device to form a concentrated liquid and dried, to prepare Sample 2. here,

※ PVP is C ₆ H ₉ ON, vinyl polymer Pyrroliaone with molecular weight 111.14 is a colorless liquid, specific gravity 1.04 (25 ℃) melting point 13.5 ℃ boiling point 214-215 ℃ Use for heating element Textile dye dispersant Used as

※ EG: CH ₂ OHCH ₂ OH, Molecular Weight 62.07 Colorless, Odorless Specific Gravity 1.11336 (20/20 ℃) Melting Point -13 ℃ Boiling Point 197.2 ℃, Flash Point 111.1 ℃ Applications: Substitute polyester fiber, antifreeze solvent, glycerin, cold-resistant lubricant, Desiccant, surfactant, etc.

3 process

The nano far-infrared radiant according to the present invention is prepared by adding and mixing 0.01-0.02% by weight of the nanosilver according to the second step to 99.98 to 99.99% by weight of the sample 1 according to the above process.

The method according to the present invention described above is obtained when 15-20 minutes at 100-120 ° C. temperature is deposited by dipping clothing and a health clothing on the radiation composition to which the softening agent 30% is added to 70% by weight of the far-infrared radiation formed by the above process. Objects are infiltrated and coated with clothing, and the deodorizing, antibacterial, sterilizing and anion releasing effects are retained even after repeated washing, and the effect of the above test can be obtained.

Claims (1)

In the deposition coating method of far-infrared radiation added with nano silver,
The aluminum silicate was heated to 600-800 ° C., dried and pulverized to 3000-3500 mesh (45 μm) to 70% by weight. The illite was dried at 100 ° C. and then pulverized to 35-40 μm particles. To 99.98 to 99.99% by weight of the sample, which was mixed at a content of 29.98 to 29.99% by weight, 0.01-0.02% by weight of the silver nano sample was mixed, and the clothes were immersed in the spinning material to which the softening agent was added. Deposition and coating method of nano-infrared radiation which is heated and deposited for 20 minutes

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