KR20030065917A - Far-infrared ray reflective - Google Patents

Abstract

PURPOSE: A composition emitting anions and far infrared rays constantly, applied to mattress, cushion, pillow and medicines, is provided to give beneficial effects on the human body like disease treatment and health promotion. CONSTITUTION: The far infrared emitting composition comprises 20wt.% of fluorite, 20wt.% of elvan, 15wt.% of zeolite,10wt.% of silica, 15wt.% of rare earth elements and 5wt.% of titanium. The far infrared emitting products are produced by mixing the components, heating to more than1300deg.C for melting, and forming to a capsule shape(50x10mm).

Description

Far infrared ray radiation composition {Far-infrared ray reflective}

The present invention relates to a composition for far-infrared radiation, and in particular, to produce a far-infrared rays, anions, and a large amount of minerals by preparing fluorspar, elvan, feldspar, zeolite, silica, rare earth, and titanium, By allowing to continuously radiate for a long period of time, as well as the therapeutic effect of various diseases, as well as a far infrared radiation composition having a great effect on the health of the user.

When the light emitted from sunlight or an incandescent object is scattered in the spectrum, it is called infrared because it is farther than the end of the red spectrum. Infrared rays having a wavelength of 0.75 to 3 µm are called near infrared rays, and those having 3 to 25 µm are simply called infrared rays, and those having 25 µm or more are called far infrared rays. It is characterized by having a stronger heat action than visible light or ultraviolet light, which is why it is also called a heat ray. Radiant heat transmitted from the sun or the heating element to the space is mainly caused by infrared rays. Intended for industrial or medical use, there are infrared bulbs that emit strong infrared rays.

Recently, various attempts have been made to stably generate far infrared rays having a certain period and use them industrially based on such a theory.

Accordingly, the present invention is to provide a far-infrared radiation composition that can be used more effectively by continuously and stably radiating far-infrared rays and anions, fluorspar, ganbanite, feldspar, zeolite, silica, rare earth, titanium as a material It is formed and applied to medical supplies such as mattresses, cushions, pillows, tableware or tablets for taking human body or dialysis agents for treating wounds, thereby providing a composition for far-infrared radiation which has an excellent effect in treating various diseases and promoting health. The purpose is.

In order to achieve the above object, the composition of the present invention is mixed with 20% by weight of fluorite, 20% by weight of ganelite, 15% by weight of feldspar, 15% by weight of zeolite, 10% by weight of silica, 15% by weight of rare earth, and 5% by weight of titanium. It is characterized in that the plastic processing to form a crystal of a certain shape.

In addition, the preparation method of the composition as described above, 20% by weight of fluorite, 20% by weight of ganbanite, 15% by weight of feldspar, 15% by weight of zeolite, 10% by weight of quartzite, 15% by weight of rare earth, 5% by weight of titanium are mixed It is heated to a temperature of 1300 ℃ or more and melted and mixed and then molded into a predetermined shape and cooled.

Hereinafter, the operation of the present invention.

Far-infrared radiation product manufactured using the composition for the far-infrared radiation of the present invention can be produced in a variety of colors, 0.4 to 1,000㎛ wavelength far infrared rays are emitted when attached to a mattress, cushion, pillow, etc., thereby promoting the circulation of blood flow In addition, the therapeutic effect of the affected area is promoted, and if it is attached to the foot where the athlete's foot or athlete's foot odor develops for a long time, the circulation of blood flow is accelerated by the far-infrared rays emitted from the far-infrared radiation composition. The therapeutic effect is excellent.

In addition, a large amount of negative ions and minerals are released at the same time to emit far infrared to the affected part of the body when taking it is a great effect in the treatment of various diseases by purifying and sterilizing.

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

Example 1

Fluorite 20 g

Ganguerite 20 g

Feldspar 15 g

Zeolite 15 g

10 g of silica

15 g of rare earths

5 g of titanium

These components were pulverized into powder form, mixed in a stirrer, and heated and dissolved at a temperature of 1300 ° C. to prepare a capsule-type far-infrared radiation product having a diameter of 5 cm and a length of 10 mm.

As a result of measuring the far-infrared radiation product prepared in this way, it was found that a large amount of far-infrared rays, anions and minerals were emitted.

Hereinafter, each component which comprises this invention is demonstrated in detail.

Fluorite is composed of CaF2, a hexahedral crystal, and sometimes octahedral, but also crystalline lumps or granular aggregates. Hardness 4 and specific gravity 3.1 to 3.2. The cleavage is complete and soft on the octahedron. Many are turquoise or purple, and many other colors are colorless, white, green, blue, yellow, red, brown, and black. In addition, a mixture of two colors appears in the solid, especially in the case of crystals, which may present a silkworm. Transparent or translucent and streaky white. Dark ones are blue with reflected light and green with passing light. When heated, it emits blue phosphorescence and bounces, and the bounced shape at this time is named fluorite, which is like a firefly shape.

Some of the white or colorless ones do not emit light, and some of the calcite emits light, so it is easy to be confused with this. It can be easily distinguished by examining the presence or absence of foaming due to firmness, cleavage and hydrochloric acid. It also emits light with ultraviolet rays and radiation. It is mostly produced in China, Russia (Ural), the United Kingdom (Cornwall), Germany (Saxony), Czech Republic (Bohemia), and the United States (Illinois). It is widely used for manufacturing steel and aluminum, corrosion of glass, enamel, lead electrolysis and optical equipment. In particular, the blue john, a variant produced in Derbyshire, England, was once used for many purposes other than decorative containers.

Elvanite is a rock belonging to quartz rock in igneous rocks. Its main components are silicic anhydride (SiO2) and aluminum oxide (Al2O3), and it contains ferric oxide (Fe2O3) which is essential for human body and living cells. Its mineral composition regulates the growth and physiology of living organisms to maintain the vitality of cells, and it has 30,000 to 150,000 pores (porous) per 1 cm3, which is a powerful adsorption, mineral elution, ion exchange, and far infrared rays. It is a bio stone that emits radiation, which is effective in preventing and treating various diseases of living organisms, detoxifying the body, promoting growth, and increasing yields. It absorbs and decomposes harmful substances and heavy metals, removes sources of corruption, and maintains freshness.

Its appearance is totally embedded with red and white spots in yellowish-white, light yellowish-brown or light-colored stone, and its shape looks like "barley grain" and is called ganbanseok.

Alkali feldspar is a natural stone produced by mixing the white spots of feldspar and quartz crystals evenly, melted and melted by volcanic activity from mesozoic to neonatal (70 million years to 50 million years ago) and weathered for many years. And quartz as main components.

The important functions of elvan are excellent in removing harmful substances, decomposing heavy metals, eluting minerals, regulating water quality and purifying water, rich oxygen content, and far-infrared radiation.

Feldspar is composed of (K, Na, Ca, Ba) (Al, Si) 408, which is a major component of granite found in the earth's crust, moon and meteorites. Most feldspars produced naturally belong to the family of three single components: potassium feldspar KAlSi3O8, sodium feldspar NaAlSi3O8, and calcium feldspar CaAl2Si2O8. Potassium feldspar and calcium feldspar hardly form a solid solution, but potassium feldspar, sodium feldspar, sodium feldspar and calcium feldspar form a continuous solid solution, and each series is collectively referred to as alkali feldspar and plagioclase. Alkali feldspar is represented by siltstone (three crystal system) and feldspar (single crystal system) and is a main mineral of acidic igneous rock.

The colored mineral of pink granite is feldspar. The plagioclase is the main constituent mineral of neutral and basic igneous rocks. The ratio of sodium and calcium changes continuously, and as acidic rocks become basic rocks, calcium-rich plagioclase richer than sodium increases. The plagioclase, which contains sodium and calcium as its main components, is called jangjang and feldspar, respectively. The plagioclase, which contains almost the same amount of sodium and calcium, is called medium growth stone. These three varieties of feldspar and solid solutions are so wide that, when totaled, the quantity surpasses quartz and is considered to be the largest of the minerals that make up the crust. Pottery, the raw material of ceramics, is weathered by feldspar.

Zeolites, also called zeolites, have many kinds, but have high water content, common properties, and crystallization. Hardness does not exceed 6, specific gravity is about 2.2. Generally it is colorless transparent or white translucent. It is named because it boils and expands when it is heated by duct.

Most varieties are dissolved in hydrochloric acid, often glued, but few are not dissolved in hydrochloric acid. The main types are the monument, fisheye, caberite, soda-stone, hallandite, steel bite, lomontite, and insite. It is produced in the cavities of the basic igneous rocks such as basalt and tuff, and in the hot pole, and sometimes exists as a secondary mineral in granite and gneiss.

It may also be produced in gold or other veins. The bonds of the atoms are loose in crystal structure, and even though the moisture filling the spaces is released at high heat, the skeleton remains the same, so that other fine particles can be adsorbed. This property is used as an adsorbent and used as a molecular sieve to separate particulates of different sizes.

Silica (silica stone) is a chemical component of silicic anhydride SiO2. White with high purity and called white quartz is produced from pegmatite, quartz veins, quartzite and chert. The silicic acid content is 95 to 97% or more. Particularly contained in pegmatite is mined with feldspar, so it is called Jang Gyu-seok. Baek Gyu Seok is mainly a raw material of glass, ceramics, silicon and ferrosilicon.

Yeongyuseok (軟 硅石) is a clay that is weathered by quartz rock and is mixed with clay. It is used as a mixture of refractory mortar or cement and contains about 90% silicic acid. Furnace ash is a kind of chert. It contains iron, so it has red angular force and is the main raw material of refractory brick. Built-in stone (內 張 石) is a small piece of silica, 5-15cm in diameter, is used for the interior of the ball mill for grinding pottery raw materials.

Rare earth elements (稀土 類 元素, rare earth elements) of the lanthanide-based elements 14 elements less than cerium except lanthanum are collectively referred to as lanthanides. In addition, the eleventh element in which six elements from lanthanum to samarium are combined with a cerium group element and europium to ruthetium with yttrium and scandium is called a yttrium group element. They all belong to rare elements, and promethium is a radioactive element, and there is no stable isotope. Odd numbers of atoms are less present than even numbers. Generally it is silver white or gray metal. Slowly oxidizes in air, soluble in acids and hot water but insoluble in alkalis. The chemistry is very similar, usually all of which produce + trivalent compounds, including +4 in cerium, terbium, praseodymium, and +2 in ytterbium, europium, and samarium. In addition to alkali metals and alkaline earth metals, the positive properties are remarkable, and the hydroxide is a base. From element 89 actinium to element 103 lawrencium are very similar to rare earth elements.

Titanium, also known as titanium, was extracted in 1789 by W. Gregor, England, from a sandstone produced in the Cornwall region. Later, in 1995, Germany's M.H.Klaprote discovered a new metal element in the Hungarian rutile, and called it Titan after the Greek god Titanes. Pure metals were first isolated in 1910 by M.A. Hunter.

It was once thought to be a rare element, but its high presence in the earth's crust makes it the ninth with a Clark number of 0.46, followed by magnesium. It is very widely distributed and usually contains about 0.6% titanium oxide in the soil. It is also contained in igneous rocks of the earth's crust. The main ores are rutile, rutile iron, titanite, anatase stone and ash titanite. In addition, iron iron is contained in the iron sand.

Silver-white metals are pure metals that are malleable and ductile, can be annealed by heating, and are industrially important because of their corrosion resistance. There are two types of crystals, α type and β type, which are stable at room temperature. The α type belongs to the hexagonal system, and at 882 ° C. or more, the α type is β type, which is an equiaxed system.

Hardness 4.0 is extremely fragile when cold, so it can be made into powder, and in red, it can be made into lines. The strength is about the same as that of carbon steel, and the strength-to-weight ratio is about two times iron and about six times aluminum. Moreover, thermal conductivity and thermal expansion coefficient are small, and the change of strength is small at 400 degrees C or less. It is stable in air, but when heated in oxygen, it becomes titanium oxide. When reacted with halogen, it reacts and is less soluble in iron than iron.

In sea water, corrosion resistance is strong after platinum. Makes many metals and alloys

Its strength and corrosion resistance is large and light, so it is used for many structural materials including aircraft and ships, and it is also used as corrosion resistant container material in chemical industry.

As described above, when the product for far-infrared radiation according to the present invention is used as a mattress, cushion, pillow or medical treatment agent and an adjuvant, vibration is generated by the wavelength of far-infrared radiation continuously emitted from the product to promote circulation of blood flow. Or, there is an excellent effect in the treatment of various diseases such as pain, as well as to remove the odor.

In the above description, the present invention has been described with reference to a representative example of manufacturing a capsule-like far-infrared radiation product having a diameter of 5 cm and a length of 10 mm. However, the present invention is not limited thereto, and for example, a rod for convenience of carrying. Of course, you may manufacture in various shapes, such as a shape, a round tube, a ring, or a button shape.

As mentioned above, although the specific Example was described about the present invention, this invention is not limited to this, A various deformation | transformation is not carried out within the range which does not deviate from the concept of this invention by those skilled in the art. You can also carry out.

As described above, the present invention is to provide a far-infrared radiation composition which can be used more effectively by continuously and stably radiating far-infrared rays and anions, and is composed of fluorite, ganbanite, feldspar, zeolite, silica, rare earth, and titanium. It is used to apply it to medical supplies, such as mattresses, cushions, pillows, tableware or human taking tablets or dialysis agents for wound treatment, it is excellent in the treatment of various diseases and health promotion.

Claims (1)

Far-infrared radiation composition comprising 20% by weight of fluorspar, 20% by weight of ganbanite, 15% by weight of feldspar, 15% by weight of zeolite, 10% by weight of quartzite, 15% by weight of rare earths, and 5% by weight of titanium.