KR20060110662A - A composition of bioceramic emitting far infrarel rays and the manufacturing method thereof - Google Patents

Abstract

A method for fabricating far-infrared ray emission type of bioceramic is provided to produce the bioceramic material with glass-like polishing effect even without applying additional glaze, and increase amount of far-infrared ray emission by polishing surface of the ceramic material used in manufacturing medical matt or electric matt. The method comprises the steps of: pulverizing different ceramic materials into powder with 325-100 meshes after washing the materials with water; pressure-forming the ceramic powder in a press with pressure of 300kg/cm^2; heat-calcining the ceramic molded body in a tunnel furnace at 1,500-2,000deg.C for 2hours 20minutes, and then naturally cooling the heated ceramic body; introducing the cold ceramic molded body into a container together with water and rotating the mixture for 48 hours to polish the ceramic body; and packaging the polished ceramic body. The polishing process is performed by entering 60% of the calcined bioceramic, 30% of polishing stones and 10% of polishing oil in a polisher, and rotating the mixture for 48 hours.

Description

Far infrared ray ceramic manufacturing method and composition {A composition of Bioceramic emitting far infrarel rays and the manufacturing method

The present invention relates to a bioceramic manufacturing method in which far infrared rays are emitted, and more specifically, by coating a surface of a far-infrared bio ceramic member used as a medical mat, an electric mat, a cushion, a bracelet, a necklace, etc., a separate coating agent (glaze) is used. The present invention relates to a far-infrared bioceramic manufacturing method and composition for improving the radiation of far-infrared rays so as to generate gloss on the surface to help the user's health even if not coated.

Conventionally, there are many members of household goods or personal care products that can help health by using far infrared rays, but when looking at their raw materials, jade, ganban stone, ruby, etc. are processed by using gemstone, jade powder, alum stone powder And a mixed ceramic powder were formed into a uniform shape, and a product having a glaze of far-infrared radiation substance applied to its outer surface was provided. Therefore, when the raw stone is processed, it is an expensive product, and the supply of the quantity is limited, and it takes a long time to process, and there is a problem in mass production. By applying, far-infrared rays are radiated from the glaze applied to the outer surface without seeing the effects on the far-infrared rays generated from the original raw materials.

In addition, the application examples of the ceramic manufacturing method using the far-infrared rays, such as the "ceramic coating method of the new decorative article" of the patent publication No. 1994-0011282 is 21-24% by weight of the organic filler (acrylic, melamine and epoxy resin 7 ~ 8% by weight), 65-73% by weight of the metal oxide binder (63-67% by weight of zirconia, 1-5% by weight of silica, 1-3% by weight of alumina) and cyclohexanone 5-9 as a solvent Inject the weight percent into a stirrer and mix thoroughly to form a mature ceramic coating, and the article to be coated is subjected to neutral degreasing and discoloration treatment, washed with distilled water to remove foreign substances, and then immersed in a ceramic coating and then rotated. As a ceramic coating method of a new disguise food which is dried and heat-treated in the first and second steps, the first application publication No. 1994-0011282 describes the appearance of the new disguise food plated with a unique color. By providing a ceramic coating layer on the cotton to maintain semi-permanent color unique to the disguise food, and to provide a ceramic coating method of the disguise food to extend the service life by providing abrasion resistance, corrosion resistance and weather resistance products of different materials It is to prevent the discoloration of the original color by coating the ceramic on the outer surface of the new disguise food and to emit far infrared rays by the ceramic coating, such a coating has a problem that the radiation amount of the far infrared rays emitted from the far infrared radiation member itself is limited,

Looking at the method of manufacturing the far-infrared radiation ceramics and the new decorative articles produced by the other prior application Patent Publication No. 1998-073480, in the method of coating the ceramics with ceramics, acrylic, melamine and epoxy resin, respectively 65-73 21-24% by weight of organic filler uniformly mixed at 7-8% by weight and 63-67% by weight of zirconia, 1-5% by weight of silica and 1-3% by weight of alumina After preparing a ceramic coating solution by mixing the wt% and 5-9% by weight of cyclohexanone as a solvent, 1L of cyclohexanone is mixed with 1L of the ceramic coating solution to prepare a ceramic coating agent, and the coating object is subjected to neutral degreasing and distilled water. Prepare a coating object to remove foreign matters by washing, dehydrating and drying, and after immersing the coating object in the ceramic coating for about 10 seconds and take it out, respectively, in the forward and reverse directions. It provides a ceramic coating method of the new disguise food, characterized in that after rotating at a constant rotational speed for a minute, and then heat-treated at 150-200 ℃ for 20 minutes each one or two, the first application patent publication No. 1998-073480 The arc also forms a ceramic solution, precipitates the coating object in the coating solution, removes it, and heats it again so that the coating is melted and polished. In this case, the far-infrared radiation member itself is coated with a glaze on the outer surface of the infrared radiation member. There was a problem in that the amount of far-infrared radiation emitted by X-rays was limited.

The present invention has been invented in view of the above problems, 23 to 40% by weight of Geumgang stone, 15 to 18% by weight of gangue stone, 12 to 15% by weight of zirconium (ZrO ₂ ), 8 to 10% by weight of germanium, alumina ( Al ₂ O ₃₎ 3 to 5% by weight, 5 to 7% by weight tourmaline, 2 to 4% by weight anion, 5 to 7% by weight silica (SiO 2), 5 to 7% by weight Kaoring, 5 to 7% by weight biotite After molding the model by pressing, it is calcined at a high temperature in a tunnel-type furnace, and the surface is processed with an abrasive to improve the quality by applying the coating (glaze) on the surface of the bio-ceramic to produce gloss like glass. It is to provide a far-infrared bioceramic manufacturing method and composition for the purpose of providing.

Hereinafter, an embodiment of the present invention will be described in detail.

Geumgang pebble 23 to 40% by weight, ganban stone 15 to 18% by weight, zirconium (ZrO ₂ ) 12 to 15% by weight, germanium 8 to 10% by weight, alumina (Al ₂ O ₃₎ 3 to 5% by weight, tourmaline 5 to 7% by weight, 2-4% by weight of anions, 5-7% by weight of silica (SiO2), 5-7% by weight of kaoring, 5-7% by weight of biotite, and then ceramic powder grinding step of grinding to 325-1000 mesh. and;

Press-molding the spray-dry tablet-dried ceramic powder with a pressing force of 300 kg / cm 2 with a mold;

A step of naturally calcining the press-formed ceramic model body in a tunnel furnace at 1,150 to 2000 ° C. for 2 hours and 20 minutes;

Grinding the naturally cooled model body by putting the abrasive (polishing stone, abrasive powder) and water together in a container and rotating for 48 hours;

It consists of a process of packaging a polished model product.

In order to explain the present invention prepared in more detail described for each process as follows.

First step: grinding process

First, the far-infrared emissivity of more than 90%

Geumgang pebble 23 to 40% by weight, ganban stone 15 to 18% by weight, zirconium (ZrO ₂ ) 12 to 15% by weight, germanium 8 to 10% by weight, alumina (Al ₂ O ₃₎ 3 to 5% by weight, tourmaline 5 to 7% by weight, 2-4% by weight of anions, 5-7% by weight of silica (SiO 2), 5-7% by weight of kaoring and 5-7% by weight of biotite are prepared and blended to purify with water.

At this time, the reason for purifying with water is to prevent the generation of dust during the means of washing and grinding.

The purified mixture with water is pulverized to 325 to 1000 mesh through a grinder to form a ceramic powder.

Second Process: Model Body Forming Process

The model is press-molded by a press equipped with a mold of a shape to make a mixed bio-ceramic powder by pulverizing chalcopyrite, zirconia, germanium, elvan, alumina, tourmaline, anion, silica, kaoring, and biotite.

At this time, the powdered bio-ceramic is dried in a spray dry method and then pressurized at a press pressure of 300 kg / cm 2 using a dry spray to form a model to be made.

The model to be made in this process is press-molded by installing a mold having a shape of the model in a press. That is, the model refers to accessories such as beads, bracelets, necklaces, and far-infrared radiation members installed in medical mats, electric mats, and electric cushions, and the shapes thereof are ball, circle, hexagon, rectangle, square, oval, etc. It can be molded into the shape of

Third Process: Firing Process

The model molded by dry press is calcined in a tunnel furnace at firing temperature 1,150∼2,000 ℃ for 2 hours 20 minutes and then naturally cooled.

At this time, the heated and fired model is hardly baked like porcelain, so it is not easily damaged even when an external impact is applied.

Thus, in this process, the model is made in a solid state, but the surface is not processed, so no gloss such as glaze occurs.

The composition of the far-infrared bio-ceramic used in the present invention has a temperature that is fired in the furnace according to the model to be molded. That is, the model forming beads, beads, necklaces, bracelets, etc. is small in size, and the amount of far-infrared bio-ceramic composition is small, so that the firing temperature is also baked at 1,150 ° C. for 2 hours and 20 minutes, and used for medical mats or electric mats. The far-infrared radiation member and the model used as the decorative device are fired for 2 hours and 20 minutes at a temperature of 2,000 ° C., and the firing temperature is controlled within 1,150 to 2,000 ° C. according to the size of the model of the far-infrared bio ceramics. In addition, 2 hours and 20 minutes is the time when the model body hangs from the entrance to the exit of the furnace by forming a furnace tunnel for firing the model body. The mock-up of the far-infrared bio-ceramic of the present invention fired in this way is not as polished as melted in the process of firing at high heat and the surface is smooth or the glaze is applied to the outer surface.

4th step: polishing process

After firing in the above process is processed to be polished on the surface in order to increase the marketability, in which the present invention is a model of a far-infrared bio-ceramic and abrasives, water molded into a model in a conventional grinder or polishing device without applying glaze Polish the bioceramic surface of the model by vibration and left and right shaking.

At this time, the polishing is rotated for 48 hours to polish the model of the far-infrared bio-ceramic to generate gloss on the surface.

The model surface of the far-infrared bioceramic polished as described above is polished like glass grains.

In another embodiment of the present invention, when the bioceramic is polished, 60% of the calcined bioceramic, 30% of the abrasive powder or abrasive stone, and 10% of the abrasive oil are put into the polishing machine and rotated for 48 hours to polish the surface to generate gloss. have.

In this process, the ratio of bioceramic, water, and abrasive stones that are suspended and polished in the grinder may vary depending on the capacity of the grinder.

5th Process: Product Packaging

The finished product through the first step and the fourth step is packaged in a separate packaging container or wrapping paper. In this case, the packaged product may package a finished product consisting of personal goods or accessories, and may be sold to a manufacturing company that manufactures a finished product by being packed with materials for making personal products or accessories.

The far-infrared bioceramic of the present invention made as described above is a far-infrared radiation member used in medical equipment mats and electric mats, a far-infrared radiation member used in vehicle seats, a button for clothes, a far-infrared radiation member to be placed when cooking soup, a necklace, It can be used as a far-infrared radiation member used for bracelets, belts, key rings, etc., especially in the case of far-infrared radiation member used as a means to improve the taste when cooking rice or as a means to improve the taste when boiling soup. One far-infrared radiating member was not used, but jade made of gemstone, etc., but in the present invention, the surface of the calcined bioceramic without glaze is polished to be freely used for food.

In addition, looking at the characteristics of the composition of the far-infrared bio-ceramic used in the present invention,

Geumgang pebble contains various rare elements such as silicon oxide, lithium, selenium, and niobium, and is known to be effective for preventing aging, fatigue, and treating diseases. It is generally molded like walnut eggs and widely used for palm acupressure. .

The main component of the elvan is silicic anhydride and aluminum oxide, and a small amount of ferric oxide is contained. Known as a weak stone is a yellowish white ganban stone was previously used as a filter for refining pills, as an anti-inflammatory to treat skin diseases such as boils or boils on the back. According to the agreement, it is sweet, warm and nonpoisonous.

Germanium is known to act to increase the vitality of germanium ions (outer electrons) due to its semiconducting properties, and when it enters the body, it is discharged out of the body within 20 to 30 hours with various harmful substances. none.

In addition, germanium that enters the capillaries in the subcutaneous tissue moves electrons in the blood vessels through the blood vessel wall, normalizes the blood by blood purification, and discharges the excess electron flow to relieve pain.

In addition, germanium has an amazing role in all diseases of lung cancer, neurosis, asthma, diabetes, hypertension, heart failure and neuralgia.

Germanium is one of the carbon group elements belonging to group 4B of the periodic table. The elemental symbol Ge, atomic number 32, and atomic weight 72.59 are widely distributed in the state of substituting silicon in a silicate. It is also contained in trace amounts in coal and sulfides and may be absorbed by plants. Germanium tetrachloride is purified by distillation, hydrolyzed to germanium dioxide, and then substituted with hydrogen to obtain a monomer. Purification by zone melting yields 99.9999% purity.

It is a hard white silver metal with melting point of 937.4 ℃, boiling point of 2830 ℃ and specific gravity of 5.35. Diamond-shaped structure, typical intrinsic semiconductor, resistivity at room temperature is about 60Ωcm, but decreases to about 1/100 at 200 ℃. When a small amount of gallium or arsenic is added, each becomes a p-type or n-type semiconductor. Chemically, the oxides II and IV are produced. In air, it is stable at room temperature and begins to oxidize above red. Insoluble in hydrochloric or dilute sulfuric acid. Hot and concentrated sulfuric acid melts with sulfur dioxide. It is insoluble in alkaline solution but eroded by aqua regia or sodium peroxide, and powder becomes germanium dioxide hydrate by concentrated nitric acid. When heated with chlorine, it becomes germanium tetrachloride and can be distilled from concentrated hydrochloric acid solution.

In addition, germanium has become a leader in the electronics industry today, including in the manufacture of transistors. As a special application, glass is added to ordinary glass, and infrared rays are transmitted through large refraction and dispersion. An alloy containing about 12% germanium in gold is used for dental purposes. In addition, it is also used in thermocouples, resistance materials, and network materials.

Zirconium (Zirconia) is a material that can be obtained from zircon (ZrSiO4) and Baddelyite (ZrO2) minerals and is used in various fields because of its excellent properties.

Zirconium (ZrO ₂ ) is the element symbol Zr. As one of the titanium group elements which belong to group 4A of a periodic table, atomic number 40, atomic weight 91.22, melting | fusing point 1850 degreeC, boiling point 4400 degreeC. The specific gravity is 6.506 (measurement temperature 20 ℃), and it is a hexagonal crystal system. When the potential temperature reaches 862 ℃, it becomes a cubic crystal system. Elemental abundance is 30 atoms per 10 silicon Si in space, 165 ppm in the earth's crust, and 30 × 10 g / dm in sea water.

Zirconium metal is similar in appearance to stainless steel and is used as a material of nuclear reactor because the area of thermal neutron absorption is the smallest among metals. In general, metals are stable at room temperature but increase in reactivity at high temperatures. Powders are dangerous because they spontaneously ignite and explode in air. Alloy zircaloys containing a small amount of tin, iron, chromium, and the like have strong corrosion resistance, and other alloys containing zirconium also have corrosion resistance.

Alumina (Al ₂ O ₃ ) is the most stable and common form of aluminum present in the earth's crust, after the industrial and mineral name of aluminum oxide, oxygen and silicon.

After the industrial and mineral names of aluminum oxide, oxygen and silicon, it is the most stable and common form of aluminum in the earth's crust.

Formula AlO. Molecular weight 101.96. Deformed by heating. When bauxite, aluminum hydroxide and the like are heated at 500 ° C, they are dehydrated first to form alumina, and when heated to 1000 ° C or more again, alumina is obtained.

Alumina is easily soluble in acids and bases because of its rough crystal structure, water absorption and amphoteric compounds. Activated alumina is also λ type. It is amorphous porous and its surface area is very large, so it has strong adsorption power. Corundum naturally produced is α-alumina, which contains about 0.2% of chromium oxide CrO to ruby, and 0.1 to 0.2% of titanium oxide of TiO₂ and iron (III) FeO, respectively. All sapphire, impure and transparent. These are the hardest minerals after diamond. α-alumina is hard and has a melting point of 2050 ° C and a density of 4.0, because it has a dense crystal structure. Melting at high temperatures significantly increases heat resistance.

In addition, the most widely used in the industry is to use alumina produced by the via method as a raw material for aluminum smelting. Activated alumina having a high adsorption capacity is used for a dehydrating agent, a decoloring agent, a chromatography adsorbent, and the like. Natural corundum, also known as Geumgangsa, is used for grinding and polishing along with impure artificials. Ruby and sapphire are artificially manufactured in addition to their use as jewelry, and are used as bearings and drawing dies for watches, and for lasers. Alumina is also widely used as a refractory and heat resistant industrial material in addition to being used as a heat resistant container and tool material as one of heat resistant ceramics. Other advances in processing technology have made it possible to produce alumina fibers, alumina bites and transparent aluminas. Furthermore, the anodized film is used for various functional purposes such as filling various materials by using the porosity and controlling electric, optical, magnetic, lubricating, catalyst, printing, and moisture.

Silica (SiO ₂ ) is a term used to refer to silicon dioxide, a substance in which two atoms of oxygen are bonded to silicon. Acidic solids such as quartz, crystal, stone, and agate, which meet with alkali to form silicates, and are mainly used as raw materials for lenses and ornaments.

The other tourmaline, anion, kaoring, biotite, etc. are compositions for constructing far-infrared bioceramic, which are also materials that emit far-infrared rays.

In addition, the anion is a mixture of common anion powders which are circulating in the market as substances which generate anions.

The present invention has the effect of heating the body body temperature in contact with the skin having a temperature of 35.5 degrees to 36.5 degrees when using as an accessory such as bracelets, necklaces using the far-infrared bio-ceramic to emit a large amount of far infrared rays from the bioceramic of the accessory To keep the body healthy.

In addition, far-infrared rays also help to prevent aging and smoothes the metabolism and blood circulation, the present invention is a widely known fact that the present invention does not apply the glaze to the bio-ceramic, which is a far-infrared radiation member of the accessory bioceramic It can emit its own far infrared rays.

The present invention has the advantage that the far-infrared radiation member of the bio-ceramic used for medical mats, electrical mats, etc. by using the polishing itself on the outer surface to emit a large amount of far infrared rays, in particular, without applying a glaze to the existing bio-ceramic outer surface The surface is polished to generate gloss, so that a large amount of far-infrared radiation is emitted when used as a medical mat far-infrared radiation member, and at the same time, it is possible to achieve high quality medical products.

As described above, the present invention processes the surface using an abrasive after firing and molding a far-infrared bioceramic used as a medical mat, an electric mat, a personal care product, or an accessory material, thereby generating a gloss like glass grains to increase product value and a coating agent. By not using it, the bioceramic itself causes the far-emissions and has the effect of producing a large amount of far-infrared radiation member.

Claims (3)

Fine powder, elvan, zirconium (ZrO ₂ ), germanium, alumina (Al ₂ O ₃₎ , tourmaline, anion, silica (SiO 2), kaoring, biotite and ceramic crushing to 325 ~ 1000 mesh and; Press-molding the spray-dry tablet-dried ceramic powder with a pressing force of 300 kg / cm 2 with a mold; A step of naturally calcining the press-formed ceramic model body in a tunnel furnace at 1,500 to 2,000 ° C. for 2 hours and 20 minutes; Grinding the naturally cooled model body by putting the abrasive and water together in a container and rotating for 48 hours; Far-infrared bioceramic manufacturing method characterized in that the manufacturing of the bioceramic by the process of packaging the product of the polished model body. The method of claim 1, The polishing process is a method of manufacturing a far-infrared bioceramic, characterized in that the baked bioceramic 60% abrasive stone 30%, abrasive oil 10% is put in the polishing machine and rotated for 48 hours to polish the surface. Bio-ceramic, a far-infrared radiation member Geumgang pebble 23 to 40% by weight, ganban stone 15 to 18% by weight, zirconium (ZrO ₂ ) 12 to 15% by weight, germanium 8 to 10% by weight, alumina (Al ₂ O ₃₎ 3 to 5% by weight, tourmaline 5 to A far-infrared bioceramic composition comprising 7 wt%, anion 2-4 wt%, silica (SiO 2) 5-7 wt%, kaoring 5-7 wt%, biotite 5-7 wt%.