KR101809060B1 - Cramic having activation and production thereof - Google Patents

Abstract

The main purpose of this project is to obtain a building material for construction, which is a base material that emits far infrared ray. It uses sericite powder containing loess, pearlite, tourmaline, germanium, and joins them. It is a technology to obtain a building interior material which is light in weight by bonding functional material by using as a binder and securing insulation effect, water resistance and weather resistance.
The main material of the present invention is a raw material for spinning far infrared rays, which is ground and calcined at high temperature and then subjected to a sieving process to be selected and purified to a predetermined particle size,
In order to produce a geopolymer which is a three-dimensional network macromolecule of Si-O-Al bond type, a starting material and an alkali activator for supplying aluminum and silicate, an alkali component serving as a dispersant and a plasticizer are prepared, ± 15 parts by weight of alumina silicate, 100 ± 10 parts by weight of alumina silicate, 100 ± 10 parts by weight of sodium silicate and 10 ± 1 parts by weight of an alkali component, 50 ± 5 of loess, 35 ± 3.5 of sericite and 5 ± 0.5 parts by weight of tourmaline, It is the technology to make the building material mixture for construction and to add the process water to obtain the slurry water, and then to put the interior material into the molding frame of the desired standard.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a body-sensitive far infrared ray ceramic body,

The present invention relates to a composition for obtaining a body-sensitive far infrared ray ceramic body, which uses a sericite powder containing loess, elvan, tourmaline and germanium as a base material for emitting far-infrared rays and uses an inorganic binder to form a geopolymer To provide an inorganic body-sensitive far infrared ray ceramic body having a high bonding force and securing water resistance and durability while providing a far-infrared radiation energy effect.

Visible light is visible light in human eyes. Infrared light is invisible light in human eyes. It has a longer wavelength than visible light. Infrared light is a wide wavelength range from 0.76 to 1,000 ㎛. It occupies 80% of light and 4 ㎛ Far infrared rays ", and those longer than 4 占 퐉 are classified as " far-infrared rays ".

One of the characteristics of far infrared rays is absorbed well in organic compounds, and representative examples of organic compounds are living organisms and living organisms, which are composed of various sugars, amino acids, proteins, hormones and the like.

Human beings are made of organic compounds and carry out life activities. There is a far infrared wavelength range in which organic compounds such as human body are absorbed well. This wavelength is called absorption wavelength. If it is not a radiation wavelength suitable for absorption, When the far-infrared wavelength of the wavelength range is radiated, it is absorbed in the human body, causing resonance and resonance in the human body. This is the theoretical basis for applying far-infrared rays to health products.

Since the water molecules actively resonate when the far infrared rays having a center wavelength of 6 to 11 μm are resonantly absorbed, in order to activate the water molecules in the living body, the radiation wavelength of 6 to 11 microns (㎛), which is the resonance absorption wavelength of water molecules, There is a need.

The water molecules (H ₂ O) are insufficiently bonded at an angle of about 105 ° between oxygen and hydrogen, and the hydrogen atoms make complicated movements, and the water molecules collide with each other at great speed and alternate, When the energy of the water molecules increases, the water molecule emits the energy.

The correlation between the specific wavelength of far-infrared rays and the activation of water molecules has an important meaning in life maintenance of all living things including human being. The atoms and molecules vibrate and the water molecules are activated by the "resonance absorption phenomenon" , The microvessel is expanded and the blood is diluted to promote the blood circulation, the metabolic disturbance such as the eosinophilia and the like can be solved, and the tissue can be revived and the enzyme production can be promoted. Thus, the metabolism is promoted, It smoothes the supply and excretes wastes accumulated in the body through the sweat glands and unnecessary harmful accumulation like moisture.

Metabolism is a collective term for chemical reactions taking place in vivo. The process of molecular level reactions to the acquisition and utilization of energy required for the growth of organisms, the maintenance of life, and the functioning of organisms, The phenomenon that is also synthesized is called "metabolism" or "material shift", whereby energy transfer (transfer) or conversion can be called energy metabolism.

It is covered with various layers of synthetic resin or opaque material on a material having far-infrared radiation characteristic by using ocher bed, medical device and other mat type health-aid device as means for obtaining energy metabolism effect by using far-infrared radiation characteristic However, since the far infrared rays are almost completely blocked by such synthetic resin, dense cloth or opaque material, it is preferable that there is no stopper in the middle position between the far-infrared radiator and the body in order to use the far infrared ray effect properly.

In other words, far-infrared rays in the wavelength range of 6 to 11 μm can resonate with the water molecules in the body if the far-infrared ray is directly copied on the skin of the body. In the state where it is covered with transparent materials such as thin clothes or vinyl, the effective far- And only the warming effect by heat conduction or radiant heat can be expected in the case where only the loess bed, the medical instrument and the other mat type health assist device are connected with the heating body and constitute the heating system.

Many attempts have been made to obtain far-infrared radiation materials using yellow loess as a material having a typical far-infrared radiation effect.

Hwangto is a mineral composed of quartz, feldspar, mica, carbonate minerals and silt. It has various inorganic and enzymatic action and humidity control ability. It emits far-infrared rays. It is harmless and can help the human body health by promoting blood circulation, exhausting wastes, preventing skin aging, deodorizing various odors, air purifying function, antibacterial / antifungal function, and reducing energy by causing self-heating phenomenon when using as an interior material Is known.

In addition, mica, elvanite, geoidite, quartz, jade, germanium, charcoal, etc., which are used as functional raw materials for generating far infrared rays other than the above-mentioned loess is already widely used in various stone beds, earth beds, health mat materials and the like

As a prior art for obtaining far-infrared effect using such a functional material, Korean Patent Laid-Open No. 10-2001-0099082 proposes a method of preventing the cracking of yellow clay in blending and coagulating process by mixing paper fibers and ground rice husk in natural loess, To increase the strength of the film.

Also, Korean Patent No. 10-0470079 has proposed a technique of first applying a loess material on a wall, covering a fiberglass mat on the loess, and then applying a loess material to prevent cracking of the loess material.

Korean Patent No. 10-0941609 has proposed a technique for preventing the surface strength and the occurrence of cracks by using a yellow mortar composition composed of loess powder, silica sand, pulp powder and mineral powder.

Korean Patent Registration No. 10-0886786 discloses a method for producing a building finish material by adding a liquid binder containing hydroxyapatite, elvan stone, pyrophyllite, diatomaceous earth and the like as a main component thereto and containing an acrylic water-soluble emulsion, To prevent the emission of harmful substances and to prevent the occurrence of cracks.

Korean Patent No. 10-1083743 discloses a technique for improving the heat insulating performance and the dew condensation preventing function by using an environmentally friendly functional plaster containing a natural adhesive material such as natural loess, silica airgel, vegetable reinforcing fiber and agar or gelatin It has been proposed.

As described above, the techniques for manufacturing and using the loess material are applied with different composition ratios according to the respective applications, but most of them are techniques for physically strengthening by adding auxiliary components to prevent cracking, or due to the nature of the climate in Korea, And the problem of cracking due to lack of weatherability in the process of passing through the cold weather of the present invention was solved.

The present invention has been studied as a task recognition to find out the applicability of a body-sensitive far infrared ray ceramic body which utilizes the correlation between the wavelength characteristics of far-infrared rays and the activation of water molecules.

In this paper, we use the far-infrared energy effect to accelerate the metabolism of the human body, so that it supplies nutrition and oxygen supply to the capillary blood vessels, and the body-sensitive body which can excrete the waste accumulated in the body and unnecessary harmful accumulation through the sweat glands And a far-infrared ceramic body.

This paper describes a basic structure for obtaining a body-sensitive far infrared ray ceramic body, which is a substrate material for emitting far-infrared rays, which is composed of loam, elvan, tourmaline, germanium, Infrared ceramic body which is made by combining a functional material with a geopolymer as a binder to increase bonding strength and ensure water resistance and weathering resistance.

Here, the term " body-sensitive far infrared ray ceramic body " means that the far infrared ray ceramic body to which the present invention is applied is once warmed to a temperature range of from 36.5 DEG C to less than 40 DEG C, Time to more than 36 ± 0.5 ° C. This is because even if the far infrared ray ceramic body provided by the present technology is heated to 40 ° C., it is not contacted with animal life, The ceramic body which exhibits the constant temperature characteristic for about 1 hour as described above is expressed as a body-sensitive far infrared ceramics body in comparison with the case where the temperature is lowered to the atmospheric temperature of the room temperature after one hour .

In order to achieve the above object, the present invention provides a far infrared ray ceramic body and promotes human metabolism by using far-infrared energy effect, thereby facilitating nutrient supply and oxygen supply to the capillary blood vessels, And a non-hazardous accumulation material, which can be excreted as moisture, is a composition for obtaining a body-sensitive far infrared ray ceramic body, which uses far-infrared rays as a substrate material for emitting far-infrared rays, using a sericite powder containing yellow clay, elvan, tourmaline, So as to form an exothermic composition.

Far infrared rays have characteristics of high permeability and have self-heating properties when penetrated. When applied to the human body, far infrared rays penetrate uniformly into the human body to cause self-heating, thereby expanding micro pores and promoting decomposition of harmful bacteria The possibility of self-heating in the ceramic body composition of the present invention has been recently sought in the field of food. In the field of food, a method of sterilizing by a mechanical heating process during the drying process of fish cake, vegetables, Far infrared ray heating means for sterilization has been applied recently. This is a sterilization method in which food is heated by using far-infrared self heat generated on the surface portion when far infrared rays are irradiated on a subject body which is a solid body Solid foods are thin and heat-resistant polyester or nylon And then irradiated with far infrared rays thereon, the food is easily sterilized by the heat generated from the food surface of the package contents. The fact that the far infrared wavelength region penetrates into the inside of the food, It can be said that it uses a heat generating function.

Various materials such as yellow loess, ilite, perlite, elvan, ceramics, tourmaline and germanium have been used as means for obtaining products that emit negative ions or far infrared rays. In the present invention, as a substrate material for emitting far-infrared rays In case of inclusion of impurities in the material from the raw materials of the sericite powder containing loam, elvan, tourmaline and geranium, it is likely to cause a change in physical properties.

As used herein, loess is a soil component that covers about 10-20% of the Korean land surface and is composed of calcium carbonate and silica (SiO ₂ ), alumina (Al ₂ O ₃ ), iron (Fe ₂ O ₃ ), magnesium, And the ocher structure is a honeycomb structure with a very large surface area and has a multi-layered structure with numerous spaces. In such a sponge-like hole, a large amount of far-infrared rays and moisture are absorbed and stored, and when the heat is received, It emits far-infrared rays and moisture that are necessary for stimulating molecular activity by influencing other surrounding environment. Soothe soil is called living organisms from ancient times, and is a kind of soil which provides various useful functions to the human body and natural environment. And its use has been tried in various fields. Our ancestors have been mainly used for the house of yellow clay wall, Bar, inventors of the present invention using the ball was to use yellow earth is called a so-called five colors of yellow earth Kyungnam high-performance area.

The present invention solves the problem that it is difficult to secure a high bonding force due to the heterogeneity of raw materials when using the sericite powder containing yellow ocher, elvan, tourmaline, and germanium, which are base materials that emit far infrared rays, and do not attenuate the far- By using a geopolymer, which is a three-dimensional network macromolecule of Si-O-Al bonding type, in which oxygen atoms are alternately shared in the SiO ₄ and AlO ₄ tetrahedrons in a simple manufacturing process, the functional material is bonded to the high- It is a completed invention in the process of ascertaining the possibility of manufacturing a body-sensitive far-infrared ceramics that secure radiation effect, water resistance and weather resistance.

The body-sensitive far infrared ray ceramic body provided herein is a substrate raw material for emitting far-infrared rays, which is obtained by calcining a raw material of loess, elvan, tourmaline, germanium-containing sericite and fly ash powder at a high temperature of 1,000 to 1,050 ° C., A first step of screening and purifying at a particle size of 0.25 mm to 0.1 탆 through a first step and a raw material for supplying silicate as a starting material in order to produce a geopolymer which is a three dimensional network macromolecule of Si- (NaOH), potassium hydroxide (KOH), and calcium oxide (CaO) to provide a binder activator during the production of the geopolymer. And a third step in which an alkaline component selected from among the alkali components is prepared.

The present invention relates to a method for producing a cement mortar composition, which comprises mixing 100 ± 15 parts by weight of loess, 60 ± 5 of elvan, 35 ± 3.5, 5 ± 0.5 parts by weight of tourmaline and 100 ± 10 parts by weight of fly ash prepared through the first step, And 100 ± 10 parts by weight of sodium silicate prepared in the third step and 10 ± 1 parts by weight of the alkaline component prepared in the third step are added and mixed, and the process mixture is added to the raw material mixture prepared in the fourth step, And a fifth step of filling the slurry with a molding frame of a desired standard and pressing it with a press to obtain a board in the shape of a plate and drying it in an oven maintained at 35 5 C to obtain a ceramic body, It was confirmed that a ceramic body could be obtained.

In addition, the slurry water may be used as a ceramic ball having a circular shape having a size of 5 mm to 10 mm according to the use of the slurry.

The present invention relates to a body-sensitive far infrared ray ceramic body, which is a base material for emitting far-infrared rays, which is obtained by calcining a raw material of fly ash powder containing alum, elvan, tourmaline, germanium and alumina at a high temperature of 1,000 to 1050 ° C., The raw material for supplying silicate is selected to have a particle size of 0.1 탆 to 0.25 mm in order to produce a geopolymer which is a three-dimensional network macromolecule of Si-O- And an alkali component selected from sodium hydroxide (NaOH), potassium hydroxide (KOH) and calcium oxide (CaO) is prepared in order to provide a role as a binder and an alkali activator during the production process of the geopolymer. / 100 ± 15 parts by weight of refined loess, 60 ± 5 of elvanite, 35 ± 3.5 of sericite and 5 ± 0.5 part of tourmaline, and the fly ash of 100 ± 10 100 ± 10 parts by weight of sodium silicate and 10 ± 1 parts by weight of the prepared alkali component are added to form a raw material mixture and process water is added to the raw material mixture to be uniformly mixed to obtain a slurry, To prepare a ceramic body, which is then dried in a drying furnace maintained at 100 占 폚 to obtain a body-sensitive far infrared ceramics body.

As a method of using the body-sensitive far infrared ray ceramic body provided by the technical idea of the present invention, 100 ± 15 parts by weight of the yellow earth selected / refined as described above, 60 ± 5 of elvan, 35 ± 3.5 of sericite, and 5 ± 0.5 part of tourmaline were weighed 100 ± 10 parts by weight of the fly ash and 100 ± 10 parts by weight of sodium silicate are added and the prepared alkali component is added in a proportion of 10 ± 1 part by weight to form a raw material mixture, The slurry is processed into a circular ceramic ball and the front surface is provided with bast fibers such as flax, jute, hemp, and hemp, which enhance the effect of generating far-infrared rays, and the back surface is made of a fabric or a synthetic resin sheet, And a circular ceramic ball is embedded between the outer sheaths and can be applied to be used as a sheet material for a floor or a sheet material for a bed Also includes spirit.

Hereinafter, embodiments in which the technical idea of the present invention is specifically embodied will be described in detail with reference to embodiments in the following detailed description for carrying out the invention.

The far infrared ray ceramic body disclosed in the present application provides an effect of causing self heat generation in a state where the far infrared ray is infiltrated while being in contact with the human body in a state where the body is once heated to the body temperature range of the human body.

The far infrared ray ceramic body provided in the present invention has an effect of providing environment friendly working environment such as no risk of human body or fire and pollution of work environment because there is no use of organic solvent or harmful substance in the providing process or work environment.

1: Manufacturing process diagram for obtaining the ceramic body of the present invention
2: Far infrared ray radiation characteristic report obtained from the Korean Institute of Living Environment Test on the ceramic body provided by the technology of the present invention
Fig. 3: Thermogram comparative photograph of the ceramic body and the ocher sheet provided herein. Fig.
Fig. 4 is an application example of a far infrared ray bag provided with the technique of the present invention. Fig.

Hereinafter, the embodiments of the present invention will be described with reference to the accompanying drawings, in which the terms and words used in the specification and claims are not to be construed as limited to ordinary or dictionary terms. , The scope of protection of the present invention should be construed in the meaning and concept consistent with the technical idea of the invention and the contents presented in the embodiments of the present application are merely one application example for attaining the purpose of the present invention, It is to be understood that various equivalents and modifications may be substituted for them at the time of filing of the present application.

The present invention solves the problem of difficulty in securing a high bonding force due to heterogeneity of raw materials when using loam, elvan, tourmaline and germanium-containing sericite powders, which are raw materials for emitting far-infrared rays, and does not attenuate far- Oxygen atoms are alternately shared in the SiO ₄ and AlO ₄ tetrahedrons in a simple state of manufacture. By using a geopolymer, which is a three-dimensional network macromolecule of Si-O-Al bond type, as a binder, , A method for providing a body-sensitive far infrared ray ceramic body which secures weatherability, is a means of providing a material for a body-sensitive far infrared ray ceramics, which comprises calcining a material of a sericite powder containing loess, lozenges and germanium as a substrate material at a high temperature of 1000 to 1,050 ° C, pulverizing it, For the first stage raw material preparation process to be screened and purified with a particle size of 0.25 mm to 0.1 μm It will not require a separate description.

1 is a view showing a manufacturing process of a far infrared ray ceramic body to which the present invention is applied, wherein the substrate raw material used in the production examples to which the present technology is applied is a mixture of yellow loess, elvan, tourmaline, germanium Fly ash or blast furnace slag, which is a raw material for forming sericite powder and geopolymer, is sintered for 3 hours or more in a high-temperature sintering furnace at a temperature of 1000 to 1,050 ° C. in case of containing impurities in the raw material components, The raw materials were selected to have a particle size of 0.25 mm to 0.1 μm.

Also, the physical properties of the substrate materials used in the present invention are not mixed with other materials and are difficult to maintain long-term bonding force even if a binder is used. In this case, the inorganic geopolymer was used as a bonding means of the substrate material. ₄ and AlO ₄ In order to construct the geopolymer, which is a three-dimensional network macromolecule of Si-O-Al bond in alternation of oxygen atoms in the tetrahedron, the starting material aluminosilicate and silicate supply step and the role of the binder activator during the formation of the geopolymer The present invention provides a starting material supply step for providing a geopolymerization for the purpose of improving durability and water resistance of a far infrared ray ceramic body, The alumina-silicate oxide is fused ash so that an amorphous aluminosilicate gel (Gel) can be formed by providing a molecular formula of (Si ₂ O ₅ , Al ₂ O ₂ ) n by binding of Si-O- Or blast furnace slag. Fly ash and blast furnace slag are also used in the size range of 0.25 mm ~ 0.1 ㎛. If fly ash or blast furnace slag powder has a particle size of 0.1 mu m or less, the specific surface area is large and the reactivity with salts of alkali metals, which are alkali activators, may be lowered. When the particle size is 0.25 mm, it is difficult to form geopolymerization because the specific surface area is low. Therefore, the use of the powder of the above-mentioned size is desired.

Therefore, the present invention provides a method of preparing a ceramic material raw material composition by pulverizing and sieving a mixture of loam, elvan, tourmaline and germanium as a substrate raw material, wherein the ceramic raw material composition is a fly ash or a blast furnace slag and a silicate And alkaline raw materials are supplied. In the present invention, the alkali supply raw material is selected from among sodium hydroxide (NaOH), potassium hydroxide (KOH) and calcium oxide (CaO) as an activator for enhancing the bonding force by promoting the generation of the geopolymer in the far infrared ray ceramic body And the silicate supplying step may be selected from among 1 to 4 kinds of sodium silicate in liquid or powder form.

A manufacturing example for obtaining a ceramic body practically based on the manufacturing process diagram of Fig. 1 will be described.

Example 1

In order to realize a nonflammable far infrared ray ceramic body which is provided with water resistance and durability using a binder of the present geopolymer, 100 g of fly ash purchased from NIKON CO., LTD. 100 g, 60 g of elvan (purchased from Celite KK), 5 g of tourmaline purchased from LSE Co., Ltd. and 35 g of germanium-containing sericite powder purchased from Geumcheon Resources Development Co., Ltd. ) 100 g of water glass (aqueous solution of three kinds of sodium silicate) purchased from Young Il Chemical Co., Ltd. and 5 g of sodium hydroxide of pale yellow powder were weighed and mixed uniformly.

The process water (water) was supplied to the powders of the uniformly mixed ceramic body composition and uniformly mixed to prepare slurry water. Then, the slurry was put into a mold having a size of 10 cm × 10 cm × 1 cm, To form a ceramic plate, and dried in a drying furnace maintained at 35 ± 5 ° C for 2 days or more to prepare a ceramic body.

Example 2

Except that 100 g of the blast furnace slag purchased from NIKON CO., Ltd. was used in place of the 100 g fly ash used in Example 1, the other steps were carried out in the same manner.

Example 3

Except that 10 g of potassium hydroxide (KOH) was used instead of 5 g of sodium hydroxide in Example 1, the other steps were carried out in the same manner.

Example 4

Other steps were carried out in the same manner except that 10 g of calcium oxide (CaO) was used instead of 5 g of sodium hydroxide in Example 1.

Comparative Examples 1 to 2

The same procedure as in Examples 1 and 2 was carried out except that fly ash and blast furnace slag were not used.

Comparative Example 3

The other steps were carried out in the same manner as in Example 1, except that 5 g of sodium hydroxide was not used.

Comparative Examples 4 to 5

Except that potassium hydroxide (KOH) and calcium oxide (CaO) were not supplied.

The results of Examples 1 to 2 and Comparative Examples 1 to 3 are shown in Table 2. The specific gravity of the ceramic items provided in the examples and comparative examples of the present invention was measured by KS L 3114 and the compressive strength was measured by KS F 2405 , Tensile strength was measured by KS F 2423, and water resistance was measured after the ceramic body was dipped in water immediately after the ceramic body was manufactured, and then the molded body was disassembled in the water state.

 division importance
(g / cm3) Compressive strength
(kgf / cm2) The tensile strength
(kgf / cm2) Water resistance (days)  Example 1  0.525  20.4  3.34  133  Example 2  0.520  19.8  3.07  92  Comparative Example 1  0.64  8.24  2.96  One  Comparative Example 2  0.68  8.43  2.88  One  Comparative Example 3  0.523  3.62  3.02  Less than a day

As shown in Table 2, Comparative Examples 1 and 2 were formed into a very weak ceramic body having a low compressive strength, especially, a low water resistance due to the absence of fly ash or blast furnace slag containing alumina silicate, In Examples 1 and 2, a geopolymer was provided to increase the compressive strength and tensile strength to a large extent, and water resistance was greatly improved.

The results of Examples 3 to 4 and Comparative Examples 4 to 5 are shown in Table 3. The measurement method was the same as described above.

 division importance
(g / cm3) Compressive strength
(kgf / cm2) The tensile strength
(kgf / cm2)  Water resistance (days)  Example 3  0.523  20.4  3.34  121  Example 4  0.522  20.2  3.07  112  Comparative Example 4  0.53  8.24  2.96  One  Comparative Example 5  0.53  8.43  2.88  One

As shown in Table 3, in Comparative Examples 4 to 5, when the alkali component is not used as the activator of the binder during the production of the geopolymer, the compressive strength is significantly lowered, which is an inability to achieve the object of the invention.

As shown in Tables 2 and 3, when the fly ash or blast furnace slag component is missing as a raw material component for supplying aluminum and silicate that provide a geopolymer, or an alkali component for enhancing the activation of the binder during the production of the geopolymer When not used in an appropriate range, the tensile strength and the compressive strength are very weak. On the other hand, as in the case of Examples 1 to 4, aluminum and silicate providing the geopolymer are supplied in an appropriate range and the production process of the geopolymer It was confirmed that the compressive strength was greatly improved when an alkaline component for increasing the activation of the binder was supplied in an appropriate range.

In order to confirm the radiation characteristics of the far-infrared ceramic emitter obtained through Example 1, the inventor of the present invention commissioned a radioactive property evaluation experiment to the Korean Living Environment Test Laboratory to measure the far-infrared radiation characteristic, and the results are shown in Table 4 Its test report is shown in Fig.

 Name of sample Emissivity
(Ranging from 5 to 20 μm) Radiant energy
(w / m < 2 > .mu.m, 40 DEG C)  Test Methods  Remarks Example 1
(Ceramic body)  0.923 3.72 x 10 ² KICM-FIR-1005 Measured wavelength:
5 탆 to 20 탆

In order to confirm the antimicrobial properties of the far-infrared ceramic emitter through the manufacturing examples of the present invention, the fungal experiment was carried out. The results are shown in Table 5, which shows the antibacterial properties.

Test Items
 Antifungal test  Culture test period Test result
 After 1 week  after 2 weeks  After 3 weeks  After 4 weeks  0  0  0  0  Test Methods  ASTM G-21

The inventor of the present invention confirmed that the sample product of the far-infrared ray radiator obtained through the above manufacturing examples exhibited the characteristics shown in Tables 2, 4 and 5, and in the same manner as in Example 1, 10 kg of fly ash 10 kg of loess, 6 kg of elvan, 500 g of tourmaline and 3.5 kg of sericite powder containing germanium were weighed and then weighed 10 kg of water glass (aqueous solution of three kinds of sodium silicate) and 500 g of sodium hydroxide, And the mixture was kneaded to prepare a slurry. The mixture was placed in a mold having dimensions of 24 cm × 24 cm × 2.0 cm in width, length and thickness, and a 500-ton high-pressure press (A, b, c, d) samples were prepared by pressing for 3 days in an oven maintained at 40 ± 1 ℃ to confirm the functionality of the body sensitive ceramic plate.

The inventor of the present invention has provided a far infrared ray radiator of a size of 24 cm x 24 cm x 2.0 cm in width, length, and thickness obtained by the above method and provided with a length of 42.5 cm and a width of 35 cm and a thickness of 2.0 cm, Domestic CW Industry Co., Ltd. When making the ceramic plate of the present invention as a means to confirm the reaction result to the human body between the loess plate products, the loess plate products of CW Industry Co., Ltd. are also used in the drying furnace maintaining the temperature of 40 ± 1 ℃ After drying for 3 days together, the photograph of the thermogram of the back region was photographed with the top of the comparative product of the loess material for 30 minutes while lying on the top of the product, and the left photograph shown in FIG. 3 was obtained. The thermogram measurement photos of the back region with the sample product obtained by the manufacturing process of the present invention lying for 30 minutes can be photographed to confirm the result of the right photograph shown in FIG. The.

The result of the thermograph measurement shown in FIG. 3 shows that the far infrared ray wavelength region emitted from the ceramic body provided in the present invention penetrates into the inside of the human body, inducing self-heating characteristic unique to far-infrared rays, The ceramic plate which is provided as a technical idea of the present invention through the experiment of various bars and the various trial errors is heated in the range of 37 ~ 38 ° C, which is similar to the human body temperature, in the drying furnace maintaining the temperature of 40 ± 1 ℃ It is understood that even after lapse of about 1 hour, it does not fall below the human body temperature of 36 ± 0.5 ° C. and the self-heating process is repeated with the characteristics of far-infrared ray continuously with the human body to maintain the constant temperature characteristic , The ceramic plate which was kept in the temperature range of 15 ~ 20 ℃ from the beginning to the normal temperature condition, Optionally up) or the like lying on the laying area confirmed the result that the effect does not appear.

FIG. 4 is a cross-sectional view of a ceramic body according to the present invention. The ceramic body is not limited to a ceramic plate. For example, a ceramic body having a diameter of 10 mm may be used to cover the abdomen of a person, 4, a ceramic ball 20 having a size of 10 mm in diameter is inserted between the front end plate member 11 and the outer covering member 12, The end fabric 11 may be provided with a bast fiber fabric 30 having a far infrared ray generating effect or a cotton fabric for softening a human touch, The mesh ball 31 is used to transmit the far infrared rays remaining from the ceramic ball 20 to the human body without interrupting the medium, The outer end of the abdomen 10 of the human body having the outer edge portion 32 of the ceramic ball 20 and the outer edge of which is subjected to the finishing treatment is provided with the structure provided with the velcro portions 13 and 14 for mutual connection .

The application of the netting 31 forming the human body contact portion as the infiltrated fiber yarn in this application means that when the endothelial material is used as a woven fabric or a synthetic resin sheet made of dense woven fabric, the far infrared ray transmitting effect from the far- A structure for applying a ceramic mesh having a diameter of about 10 mm, which is embedded in a bast fiber mesh having a far-infrared radiation effect itself, so as not to reduce the effect of far-infrared radiation on the body part of the user, And the application technique in which a ceramic ball is embedded between the inner skin material 11 and the outer skin material 12 with a proper thickness is divided into a process such as sewing or fusing as required by the user, And can be applied to the abdominal structure in the above-described manner, It will be understood by those skilled in the art that a Velcro tape may be provided on both ends of the abdomen when wrapped or wrapped around the abdomen, or in a form of a hook to cover the abdomen, waist, etc. FIG. 4 shows only a human's bell 10 for covering the abdomen of a human being. However, in addition to the bag, the front surface of a portion contacting the human body in a sheet material for a floor or a sheet material for a bed may be flax, A jute, a hemp, a hemp, and the like form a mesh structure to form a human body contact portion, and a rear surface of the fabric or the synthetic resin sheet forms a sheath state, and a ceramic ball provided by the present invention is embedded between the infill fiber material and the sheath material. It can be applied at any time.

When the far infrared ray ceramic plate or the far-infrared radiation ceramic ball according to the present invention as described above is warmed to a temperature range of 36 to 39 ° C which is the temperature range of the human body and then warmed to the abdomen region or the back region of the user, The area penetrates into the inside of the human body, inducing self-heating characteristic of far-infrared rays, penetrating every corner of the human body, expanding micro-pores, promoting decomposition of harmful microorganisms, and evolving into a technology capable of achieving self-heating effect It is expected to be possible.

10: human body bag 11: endothelial material
12: sheath material 13: Velcro part
20: ceramic ball 30: bast fiber fabric
31: bast fiber mesh 32: outer rim

Claims (3)

A method of manufacturing a body-sensitive far infrared ray ceramic body,
Raw materials of loam, elvan, tourmaline and germanium containing sericite powder are fired at a high temperature of 1000 ~ 1,050 ℃, pulverized, sieved and sorted to a size of 0.25 ~ 0.1 ㎛ A first step of purifying;
Si-O-Al bond-type three-dimensional network macromolecules
A second step of preparing a raw material for supplying fly ash and sodium silicate as starting materials in the form of powder having a size of 0.1 탆 to 0.25 mm;
As a binder and an alkali activator, sodium hydroxide
A third step of preparing an alkaline compound selected from sodium hydroxide (NaOH), potassium hydroxide (KOH) and calcium oxide (CaO);
100 ± 15 parts by weight of loess, 60 ± 5 parts by weight of elvan, 35 ± 3.5 parts by weight of sericite and 5 ± 0.5 parts by weight of tourmaline prepared in the first step are mixed and mixed with 100 ± 10 weight parts of fly ash prepared in the second step And 100 ± 10 parts by weight of sodium silicate are added, respectively, and 10 ± 1 parts by weight of the alkali compound prepared in the third step is added and mixed;
The process water is added to the raw material mixture prepared in the fourth step and mixed uniformly
After obtaining the slurry water, it is filled in a molding frame of a desired standard and pressed by a press,
Shaped board is obtained and dried in an oven maintained at 35 짹 5 째 C to obtain a ceramic body.
step; Wherein the body-sensitive far infrared ray ceramics
Method of manufacturing a mix. delete A method of using a body-sensitive far infrared ray ceramic material,
Raw materials of loam, elvan, tourmaline and germanium containing sericite powder are fired at high temperature of 1000 ~ 1,050 ℃, pulverized, sieved and sorted by particle size of 0.25 mm ~ 0.1 ㎛ And purified,
Si-O-Al bond-type three-dimensional network macromolecules
A raw material for supplying fly ash and sodium silicate as starting materials is prepared in a size of 0.1 탆 to 0.25 mm,
To provide the role of binder and alkaline activator during the production of geopolymers
An alkaline compound selected from sodium hydroxide (NaOH), potassium hydroxide (KOH) and calcium oxide (CaO) is prepared,
100 ± 15 parts by weight of the selected and purified yellow clay, 60 ± 5 parts by weight of elvan, 35 ± 3.5 parts by weight of sericite, and 5 ± 0.5 parts by weight of tourmaline were mixed together and mixed with 100 ± 10 parts by weight of the fly ash and 100 parts by weight of sodium silicate 100 ± 10 parts by weight of the alkali compound is added at a ratio of 10 ± 1 parts by weight of the prepared alkali compound to form a raw material mixture and the raw material mixture is added with process water to obtain a slurry water,
The slurry water is processed into a circular ball and embedded in a bast fiber to form a bottom sheet member
Wherein the body-sensitive type far infrared rays is applied to be used as a sheet material for a bed.
Usage of Raw Material.

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