KR20130142332A - Manufacturing method of far-infrared ray emiting powder - Google Patents

Abstract

The present invention relates to a method for manufacturing far-infrared ray emitting powder which is capable of maximizing radiation efficiency of far-infrared ray and anion by maximally increasing the surface area of a unit powder itself. The method for manufacturing far-infrared ray emitting powder according to the present invention comprises: a first step which makes far-infrared ray into first powder having small diameters, second powder having middle diameters, and third powder having large diameters; a second step which stirs after adding the first and second powder to an ionic colloidal silver solution in order for the first powder to be attached to the surface of the second powder and dries after filtering and prepares the first combined powder; and a third step which stirs after adding the first combined powder and the third powder to the ionic colloidal silver solution in order for the first combined powder to be attached to the surface of the third powder and dried after filtering and prepares the second combined powder. [Reference numerals] (AA) Start;(BB) Make far-infrared ray into first powder having small diameters, second powder having middle diameters, and third powder having large diameters;(CC) Stir, filter, and dry after adding the first and second powder to an ionic colloidal silver solution in order to prepare first combined powder;(DD) Stir, filter, and dry after adding the first combined powder and the third powder to the ionic colloidal silver solution in order to prepare second combined powder;(EE) End

Description

Far infrared radiation powder manufacturing method {MANUFACTURING METHOD OF FAR-INFRARED RAY EMITING POWDER}

The present invention relates to a method for producing far-infrared radiation powder that emits far infrared rays and anions, and more particularly, to a method for producing far-infrared radiation powder which maximizes the surface area of unit powder itself to maximize the radiation efficiency of far infrared rays and anions. It is about.

Far infrared rays are light energy in the range of 2.5-20 탆 in which the wavelength of the infrared rays is rather long. These far infrared rays are emitted at temperatures above 0 K in all materials, but the radiation is very high for certain minerals, which are called far infrared emitters.

Far-infrared radiation is known to have high energy efficiency and particularly beneficial to the human body because energy is transmitted by radiation, and far-infrared radiators are used in various fields from household goods to building materials and medical use.

Such far-infrared emitters are well known as jade, elvan, and the like, and in addition, the far-infrared radiation efficiency of transition metal oxides is known.

Since the far-infrared radiator is mainly used in the form of powder, research on the far-infrared radiation powder and its manufacturing method has been conducted. For example, in Patent Registration No. 10-0074153 (registered on April 1, 1998), the ratio of clayized clay to 60% The composition of the far-infrared radiation powder, characterized in that the mixture is composed of 1: 1 mixture 13.3%, carbon 13.3%, ferrous oxide 6.7%, silica 6.7%, has been published, Korean Patent Publication No. 10-1997-0059144 No. (August 12, 1997), the silliside alumina and ganban stone, which have been pulverized by grinding mica, alumina and ganban stone, were mixed in a rotary tube and mixed evenly by high-speed rotation. Pulverize, add 3% of sulfur pulverized to 325 mesh and 5% of salt to 92% of the mixed pulverized powder, and then mix the mixture.A method for producing a far-infrared radiation powder material, which is prepared by grinding, has been published.

The above-mentioned far infrared radiation powder and its manufacturing method are limited to further adding other components to the far infrared radiation material in order to increase the far infrared radiation efficiency and provide additional functions (such as antibacterial), thereby increasing the actual far infrared radiation efficiency. There is a problem with the limitation.

It is an object of the present invention to provide a method for producing a far-infrared radiation powder which maximizes the surface area of the unit powder itself to maximize the radiation efficiency of far infrared rays and anions.

The above object of the present invention is to firstly powder the far-infrared radiator into a first powder of small diameter, a second powder of medium diameter and a third powder of large diameter, and to form colloidal silver in the first and second powders. A second step of preparing a first composite powder by adding the ionic liquid to the surface of the second powder and stirring the first powder to be attached to the surface of the second powder, followed by filtration and drying; A third step of preparing a second composite powder by adding a third powder to a colloidal silver ion solution and then stirring to make the first composite powder adhere to the surface of the third powder, followed by filtration and drying. It is achieved by providing a method for producing far-infrared radiation powder.

According to a preferred feature of the invention, the far-infrared emitter is formed of one or more of the ear of precious stones, tourmaline and elvan.

According to a preferred feature of the invention, the first powder has a diameter of 1 to 10 nm, the second powder has a diameter of 50 to 100 nm, and the third powder has a diameter of 500 to 1000 nm.

According to a preferred feature of the present invention, the colloidal silver ion solution in the second and third step is prepared by electrolysis of pure silver in purified water in multiples of 100 to 200, the stirring in the second and third steps is the colloid The silver ion solution is heated to a temperature of 60 to 90 ° C. for 0.5 to 7 hours and at a stirring speed of 30 to 180 rpm, and in the second and third steps, the drying is performed by hot air at 60 to 90 ° C. All.

According to a preferred feature of the present invention, the second composite powder is added in an amount of 0.01 to 4% by weight to one of the general paints, municipal coatings, photoluminescent coatings, light coatings, nail polish, fertilizers, synthetic resin for product molding and interior and exterior materials for construction. do.

According to the method for producing far-infrared radiation powder according to the present invention, a plurality of medium diameter second powders are attached to the outer circumferential surface of the third powder of large diameter, and a plurality of small diameters are attached to the outer circumferential surface of the second powder of medium diameter attached to the third powder. As the first powder of is attached, a far-infrared radiation powder having a much larger surface area than a conventional far-infrared radiation powder having the same diameter can be produced, which has an excellent effect of greatly increasing the radiation efficiency of far infrared rays and anions. .

In addition, according to the method for producing the far-infrared radiation powder according to the present invention, the colloidal silver ion solution acts as a kind of coating solution for the adhesion of the powder when the first powder of small diameter, the second powder of medium diameter and the third powder of large diameter are attached to each other. Accordingly, there is an excellent effect that the antimicrobial effect and far infrared ray emission effect by the colloidal silver ion solution can be additionally provided.

Improvement of the functionality of each product when the far-infrared radiation powder prepared according to the method of the present invention is mixed with general paints, city temperature paints, photoluminescent paints, light paints, nail polish, fertilizers, synthetic resins for product molding and interior and exterior materials for construction Of course, it exhibits a beneficial effect on the human body by the radiation of far infrared rays and anions.

1 is a process flowchart of a method for producing far-infrared radiation powder according to the present invention.
1 is a schematic structural diagram of a far-infrared radiation powder produced by the method for producing a far-infrared radiation powder according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. , And this does not mean that the technical idea and scope of the present invention are limited.

The far-infrared radiation powder manufacturing method according to the present invention is to maximize the surface area of the unit powder itself to maximize the radiation efficiency of the far infrared rays and anions, as shown in Figures 1 and 2 A first step of powdering the first powder 10 having a diameter, the second powder 20 having a medium diameter, and the third powder 30 having a large diameter, respectively, and the first and second powders 10 and 20 are colloided. A second step of preparing a first composite powder by adding a silver ion solution and stirring to make the first powder 10 adhere to the surface of the second powder 20, followed by filtration and drying. The powder and the third powder 30 were added to the colloidal silver ion solution, followed by stirring to attach the first composite powder to the surface of the third powder 30, followed by filtration and drying to prepare a second composite powder. It includes a third step.

The first step is to powder the far-infrared emitter into a first powder 10 of small diameter, a second powder 20 of medium diameter and a third powder 30 of large diameter, respectively.

Herein, the far-infrared radiator is preferably formed of at least one of gemstone, tourmaline and elvan.

Guiyangite is a type of feldspar, also known as a hemp feldspar, which is a rock that exists in mines formed by hot hydrothermal action in the course of tectonic change. The main components of guinea pigs are 75.50% of silicon oxide, 14.00% of aluminum oxide, 4.50% of potassium oxide, 4.30% of sodium oxide, and 0.34% of calcium oxide. There are two types of ear stones: white ear ear stones and red ear ear stones. White ear ear stones have the far-infrared emissivity of 96% at room temperature (25), which is the highest among natural ores. cc is the highest value among natural ores. According to a water science research conference in March 2000, out of 25 functional materials at home and abroad, guinea pigs generate anion of up to 9,451 (pieces / cc) and have an average value of 96% in far-infrared radiation radiation. As a natural functional material, it is being applied in industrial and living parts such as water purification, paint, humectant, filter, cosmetics, bath, bedding, and functional carpet. Guiyang stone is an ore recently discovered in the Orient such as Japan, and its official mineral name has not yet been determined.

Tourmaline is a mineral belonging to a hexagonal system having a crystal structure like crystal, and is named as tourmaline because electricity is generated by friction and both ends are positively and negatively charged when heated.

Elvan is a mineral belonging to granite calcite, and it is called ganban stone because it is like a rice ball made of barley rice mixed with quartz and feldspar. Since the main component contains silicic anhydride, aluminum oxide, and ferric oxide, an appropriate amount is added and mixed with minerals emitting strong far infrared rays.

In addition, in the description of the diameters of the first powder 10, the second powder 20, and the third powder 30, the small diameter, the medium diameter, and the large diameter represent relative sizes, and the small diameter first powder 10 Silver has a diameter of 1 to 10 nm, the medium diameter second powder 20 has a diameter of 50 to 100 nm and the large diameter third powder preferably has a diameter of 500 to 1000 nm, depending on the embodiment The small diameter first powder 10 has a diameter of 1 to 10 μm, the medium diameter second powder 20 has a diameter of 50 to 100 μm, and the large diameter third powder has a diameter of 500 to 1000 μm. It may be.

The second step is to attach the small diameter first powder 10 to the surface of the medium diameter second powder 20, in which the first and second powders 10 and 20 are colloidal silver. After the solution was added to the ionic solution, the mixture was stirred to attach the first powder 10 to the surface of the second powder 20, and then filtered and dried to prepare a first composite powder.

The colloidal silver ion solution acting as a dispersion medium acts as a kind of adhesion coating liquid which uniformly attaches and coats the small diameter first powder 10 on the surface of the second diameter powder 20 having a medium diameter. It is preferably prepared by electrolysis in purified water.

In the second step, the stirring is performed by adding the first and second powders 10 and 20 to the colloidal silver ion solution and then heating them at a temperature of 60 to 90 ° C. for 0.5 to 7 hours, and at the same time, using a conventional rotary stirrer. It is preferable to carry out at the stirring speed of rpm, filtration is performed by a semipermeable membrane similarly to the filtration of a normal colloidal solution, and drying is performed by hot air of 60-90 degreeC.

The third step is to attach the first composite powder prepared in the above-described second step to the surface of the large diameter of the third powder 30, the first composite powder and the third powder prepared in the second step (30) was added to the colloidal silver ion solution, followed by stirring to allow the first composite powder to adhere, followed by filtration and drying to prepare a second composite powder.

The colloidal silver ion solution acting as a dispersion medium acts as a kind of adhesion coating liquid to uniformly attach and coat the first composite powder prepared in the second step on the surface of the third powder 30 having a large diameter. It is preferably prepared by electrolysis in 200 multiples of purified water.

In the third step, the first composite powder and the third powder 30 were added to a colloidal silver ion solution, and then heated to a temperature of 60 to 90 ° C. for 0.5 to 7 hours, and at a time of 30 to 30 minutes by a conventional rotary stirrer. It is preferable to carry out at a stirring speed of 180 rpm, the filtration is carried out by a semipermeable membrane similar to the filtration of a normal colloidal solution, and the drying is preferably carried out by hot air at 60 to 90 ℃.

White-based guinea pigs are put into a precision ball mill, and the first powder 10 having a diameter range of 1 to 10 nm, the second powder 20 having a diameter range of 50 to 100 nm, and the powder having a diameter range of 500 to 1000 nm 3 powder 30 was prepared. Then, the first and second powders 10 and 20 were added to a colloidal silver ion solution prepared by electrolyzing pure silver in 100-fold purified water, and then heated to 90 ° C. for 7 hours, and then a conventional rotary stirrer. After stirring at a stirring speed of 180 rpm, and filtered through a semi-permeable membrane and dried with hot air at 90 ℃ to prepare a far-infrared radiation powder.

As a result of confirming the far-infrared radiation dose of 1 g of the conventional white-based guinea pig powder of the same diameter range and each of the far-infrared radiation powder prepared according to Example 1, each far-infrared radiation powder prepared according to Example 1 has the same diameter range. Far-infrared radiation amount was 1.74 times higher than that of a normal white ear cyanite powder.

The tourmaline ore was introduced into a precision ball mill, and the first powder 10 having a diameter range of 1 to 10 nm, the second powder 20 having a diameter range of 50 to 100 nm, and the third powder having a diameter range of 500 to 1000 nm 30 were each prepared. The first and second powders 10 and 20 were then heated to 75 ° C. for 4 hours in a colloidal silver ion solution prepared by electrolysis of pure silver in 150 multiples of purified water and 100 After stirring at a stirring speed of rpm, filtered through a semi-permeable membrane and dried with hot air at 75 ℃ to prepare a far-infrared radiation powder.

As a result of confirming the far-infrared radiation dose of 1 g of each tourmaline powder having the same diameter range and 1 g of each far-infrared radiation powder prepared according to Example 2, each of the far-infrared radiation powders prepared according to Example 2 had conventional tourmaline of the same diameter range Far-infrared radiation dose was about 1.52 times higher than that of powder.

Germanium ore is injected into a precision ball mill apparatus to make the first powder 10 having a diameter range of 1 to 10 nm, the second powder 20 having a diameter range of 50 to 100 nm, and the third powder having a diameter range of 500 to 1000 nm. 30 were each prepared. The first and second powders 10 and 20 were then heated to 60 ° C. for 0.5 hour in a colloidal silver ion solution prepared by electrolysis of pure silver in 200 multiples of purified water and at the same time by a conventional rotary stirrer. After stirring at a stirring speed of rpm, filtered through a semi-permeable membrane and dried with hot air at 60 ℃ to prepare a far-infrared radiation powder.

As a result of confirming the far-infrared radiation dose of 1 g of the conventional germanium powder having the same diameter range and 1 g of each of the far-infrared radiation powder prepared according to Example 3, each of the far-infrared radiation powder prepared according to Example 3 had the common germanium of the same diameter range. Far-infrared radiation dose was about 1.35 times higher than that of powder.

Therefore, the far-infrared radiation powder produced by the method for producing the far-infrared radiation powder according to the present invention has a plurality of medium diameter second powders 20 attached to the outer circumferential surface of the third powder 30 of large diameter as shown in FIG. 2. And a plurality of small diameter first powders 10 are attached to the outer circumferential surface of the medium diameter second powders 20 attached to the third powders 30, which are much larger than ordinary far-infrared radiation powders having the same diameter. It has a surface area, which greatly increases the radiation efficiency of far infrared rays and anions. In addition, the colloidal silver ion solution acts as a kind of coating solution for powder adhesion when the small diameter first powder 10, the medium diameter second powder 20 and the large diameter third powder 30 are attached to each other. Antimicrobial effect and far infrared ray emitting effect by silver ion solution is additionally provided.

In addition, when the far-infrared radiation powder prepared according to the method of manufacturing the far-infrared radiation powder according to the present invention is mixed with general paints, city temperature paints, photoluminescent paints, light paints, nail polish, fertilizers, synthetic resin for product molding and interior and exterior materials for building, Of course, it is obvious that the beneficial effect can be exerted on the human body by radiation of far infrared rays and anions.

1: Far Infrared Radiation Powder
10: first powder
20: second powder
30: third powder

Claims (5)

A first step of powdering the far infrared emitter into a first powder of small diameter, a second powder of medium diameter and a third powder of large diameter, respectively;
A second step of preparing the first composite powder by adding the first and second powders to a colloidal silver ion solution and then stirring to make the first powder adhere to the surface of the second powder, followed by filtration and drying. ; And
The first composite powder and the third powder were added to a colloidal silver ion solution, followed by stirring to allow the first composite powder to adhere to the surface of the third powder, followed by filtration and drying to form a second composite powder. Far-infrared radiation powder manufacturing method comprising a third step of manufacturing. The method according to claim 1,
The far-infrared radiator manufacturing method of the far-infrared radiation powder, characterized in that formed by one or more of yangguseok, tourmaline and elvan. The method according to claim 1,
The first powder has a diameter of 1 to 10 nm, the second powder has a diameter of 50 to 100 nm, the third powder has a diameter of the far-infrared radiation powder, characterized in that 500 to 1000 nm. . The method according to claim 1,
In the second and third steps, the colloidal silver ion solution is prepared by electrolyzing pure silver in purified water in multiples of 100 to 200, and in the second and third steps, the agitation is performed to bring the colloidal silver ion solution to 60 to 90 ° C. Far-infrared radiation powder, which is heated at a temperature of 0.5 to 7 hours and at the same time a stirring speed of 30 to 180 rpm, wherein the drying is performed by hot air at 60 to 90 ° C. in the second and third steps. Manufacturing method. The method according to any one of claims 1 to 4,
The second composite powder is far-infrared radiation powder, characterized in that it is added in an amount of 0.01 to 4% by weight to one of the general paint, municipal temperature, photoluminescent paint, light coating, nail polish, fertilizer, product molding synthetic resin and building interior and exterior materials. Manufacturing method.

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