JP2016121328A - Usage of far-infrared radiation material, and method for applying the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently irradiate a target substance with radiation light which is radiated from a far-infrared radiation substance.SOLUTION: The present invention is a far-infrared radiation substance-filled capsule in which a far-infrared radiation substance is filled in a capsule container constituted of a substance in which average transmissivity of far-infrared ray having a wavelength at 4 μm to 14 μm is 60% or more, and sealed. A space having no content substance containing the far-infrared radiation substance exists in the capsule container, and the specific gravity of the capsule is adjusted by changing a ratio of the space to an inner volume of the capsule container. Furthermore, in the case of inputting a plurality of the capsules into liquid, the specific gravity of a part of or all of the capsules is within the range of 5% of the specific gravity of the liquid, the space in the capsule container contains at least one type of nitrogen, oxygen, carbon dioxide and inert gas, and the capsule container is constituted of plastic such as acrylic resin.SELECTED DRAWING: Figure 1

Description

The present invention relates to a use, means, method, and the like for effectively applying radiated light from a far-infrared emitting material to water, a human body, a building, and the like.

Far-infrared rays are electromagnetic waves having a wavelength in the range of 4 μm to 1000 μm, and are put to practical use in the field of cooking, far-infrared heaters, far-infrared saunas, heating, and the like. Among far-infrared rays, an electromagnetic wave having a wavelength of 4 to 14 μm is said to be a growing ray because it is particularly important for the growth of living organisms, and has recently been attracting attention and various methods and uses thereof have been studied. In addition, several substances that emit nurturing rays have been discovered from natural stones and are in practical use. Such rocks have inconsistent performance and have the disadvantage that heavy rocks must be transported or crushed. On the other hand, a technique for artificially producing a growing light emitting material with stable performance and low cost has been developed. (Patent Document 1) Further, in recent years, far-infrared rays, particularly growing rays, have been attracting attention for improving water quality and promoting health.

Japanese Patent Fair 06-27202

When a far-infrared emitting material is put directly into water to improve water quality, the far-infrared emitting material has a higher specific gravity than water and sinks to the bottom of the water. There is. As a countermeasure, it is conceivable to disperse the far-infrared radiation substance in water by stirring water, but a special stirring device is required. There is also a problem that the far-infrared radiation material is lost or damaged during the stirring. When the far-infrared emitting material is chipped and becomes fine or when a powdered far-infrared emitting material is used, it is difficult to separate and remove the far-infrared emitting material from water. In addition, when a far-infrared emitting material is used as drinking water by acting on water, there are many people who do not like the far-infrared emitting material coming into direct contact with water. Furthermore, there is a risk that some of the far-infrared radiation material and impurities are dissolved in the drinking water, and there is a risk that sanitary problems may occur.

An object of the present invention is to solve the above-mentioned problems and to provide a method for easily irradiating a target substance with radiated light emitted from a far-infrared emitting substance and facilitating handling. In the present invention, the far-infrared emitting substance means a substance having an average emissivity of 60% or more in a growing light (electromagnetic wave having a wavelength of 4 μm to 14 μm) region. The present invention has the following features to solve the above problems.
(1) The present invention is a capsule with a built-in far-infrared emitting material in which a far-infrared emitting material is embedded in a capsule container, and the material of the capsule container has an average far-infrared transmittance of 60 μm to 4 μm. % Or more.
(2) In addition to (1), the present invention includes a space free of content substances including far-infrared radiation material in the capsule container, and changes the proportion of the space in the internal volume of the capsule container. The specific gravity of the capsule is adjusted, and when a plurality of the capsules are put in a liquid, a part or all of the plurality of capsules has a specific gravity in the range of 5% from the specific gravity of the liquid. It is characterized by being inside.

(3) In the present invention, in addition to (1) and (2), the space in the capsule container contains at least one gas of nitrogen, oxygen, carbon dioxide, and rare gas, and / or the capsule The pressure in the space in the container is less than 1 atmosphere or greater than 1 atmosphere.
(4) In addition to (1) to (3), the present invention is characterized in that the capsule container is made of plastic, and the plastic is acrylic, polyvinyl chloride, or polyester. The capsule container has a diameter equal to or smaller than the inside diameter of the drinking water drinking bottle, and has a depression on the outside of the capsule container, and is used by being put in a drinking water plastic bottle. It is characterized by putting the capsule with built-in far-infrared emitting material in water or liquid to purify water or liquid, or by putting the capsule with built-in far-infrared emitting material in bath water to improve the health of the body and bath It is characterized by preventing dirt such as mold.

(5) The present invention is a bath product characterized by integrating a substance having a specific gravity of less than 1 and a far-infrared emitting substance, such as polystyrene foam or a float, so that it floats on the surface of the water. It is characterized by having attached.
(6) The present invention is a far-infrared radiation-containing material-containing sheet characterized by being applied to the affected area for the purpose of preventing or preventing convulsions, convulsive pain, muscle pain, joint pain, or back pain. A sheet of cloth or a plastic film is attached to the surface of the sheet that comes into contact with the skin to prevent the far-infrared substance from directly contacting the skin, thereby reducing or preventing eczema and / or the sheet. A plurality of holes are provided in the eczema to reduce or prevent eczema.
(7) In addition to (6), the present invention has a shape adapted to the shape of a part of the body such as the face, has a heat retaining effect, further has a thickness of 3 mm or more, and has a large heat capacity. It is characterized by.
(8) The present invention is a far-infrared-radiating substance-containing building wall material characterized by mixing a powdery far-infrared-radiating substance and a wall material such as plaster.
(9) The present invention is a water treatment apparatus for purifying water by adding a mixture of a binder such as silicone resin and a far-infrared emitting substance, and sending air to water using a pump to circulate the water. The water treatment apparatus is characterized in that dirt and dust are prevented from adhering to the mixture.

In the present invention, the far-infrared emitting material is sealed in a sealed capsule container such as plastic, and the far-infrared emitting material does not directly contact liquids such as water, so the far-infrared emitting material is not damaged and missing. It is easy to separate and remove the far-infrared emitting substance-containing capsule after purifying the liquid such as water, and the far-infrared emitting substance does not contaminate the liquid such as water and is very easy to handle. Even when used for purification of drinking water, far-infrared radiation does not dissolve in drinking water, and since the capsule container is made of plastic such as acrylic, there is no risk of dissolution in water, etc. The occurrence is small. Since the material of the capsule container is easy to transmit far infrared rays, the emitted light (far infrared rays) from the far infrared radiation material is radiated to water or the like through the capsule container, so that the water can be sufficiently purified. Since it is easy to adjust the specific gravity of the capsule itself to the same level as the specific gravity of a liquid such as water, it is possible to float the capsule with a far-infrared emitting substance in a liquid such as water. As a result, the capsules can be uniformly distributed in a liquid such as water containing a large number of capsules, and the purification of water and the like can be performed efficiently. Furthermore, it is easy to separate and remove the capsule containing the far-infrared emitting material from water, etc., and the far-infrared emitting material is hardly altered, and the capsule is little altered, so the capsule containing the far-infrared emitting material is repeatedly used. There is also an advantage that the running cost is very small.

FIG. 1 is a diagram showing a capsule containing a far-infrared emitting material of the present invention. FIG. 2 is a graph showing the transmittance of various plastics in the far-infrared region (growth light wavelength region). FIG. 3 is a view showing a state of the capsule of the present invention placed in water. FIG. 4 is a diagram showing a far-infrared radiation floating body goods for a bath equipped with the far-infrared radiation material of the present invention. FIG. 5 is a view showing a sheet and a face mask containing the far-infrared emitting material of the present invention. FIG. 6 is a diagram showing the far-infrared radiation characteristics of various ceramics. FIG. 7 is a diagram showing another embodiment of the far-infrared emitting substance-containing capsule of the present invention. FIG. 8 is a table showing the effect of the far-infrared emitting material-containing sheet of the present invention by a clinical experiment in which the far-infrared emitting material-containing sheet of the present invention is applied to a patient. FIG. 9 is a graph showing the relationship between the skin surface temperature of the affected area of the patient wearing the far-infrared emitting substance-containing sheet of the present invention and the poultice time.

FIG. 1 is a diagram showing a capsule 11 containing a far-infrared emitting material of the present invention. A capsule container (wall) 12 contains a content substance 13 containing a far-infrared emitting substance. The far-infrared substance in the content substance 13 is a substance having an average emissivity of far-infrared rays of 60% or more. For example, ceramics such as silicon oxide, zinc oxide, aluminum oxide, magnesium oxide, natural and artificial minerals, metals and Metals and semiconductors such as oxides, nitrides, carbides, sulfides, hydroxides, carbonates and their salts (complex salts), charcoal, and other natural materials such as shells, Not only these inorganic substances but also organic substances may be used as long as the average emissivity of far infrared rays is 60% or more.
Thus, in the present invention, the far-infrared emitting substance refers to a substance having an average emissivity of 60% or more of far-infrared rays (also referred to as growth rays) when the wavelength of electromagnetic waves is 4 μm to 14 μm. Here, the emissivity is the ideal black body ratio obtained by measuring the amount of far-infrared rays emitted from the target substance and the ideal black body at the same temperature {the target when the radiation intensity of the ideal black body is 100%. The ratio of the radiation intensity of the substance (%)}. Moreover, an average emissivity is an average emissivity in the wavelength range of electromagnetic waves. FIG. 6 is a diagram showing the far-infrared radiation characteristics of various ceramics. Some ceramics have an emissivity of 60% or less in a part of the growing light wavelength region (4 μm to 14 μm), but all the ceramics shown here have an average emissivity of 60% or more in the growing light wavelength region (4 μm to 14 μm). Therefore, it is included in the far-infrared radiation material of the present invention. As the far-infrared emitting material of the present invention, the higher the average emissivity, the better. The average emissivity is preferably 80% or more, more preferably 90% or more.

Moreover, the form of a far-infrared radiation substance should just be the shape and magnitude | size (size) which enter the capsule container 12, for example, is a particle | grain, a powder, and a lump shape. However, the far-infrared emitting material is smaller in size and has a larger surface area per volume. Therefore, the far-infrared emitting material from the far-infrared emitting material has a larger amount of far-infrared radiation. Or a powder form is desirable. Even in the case of a bulk material, a porous material is desirable because of its large surface area. Even though the far-infrared emitting material is small, it is contained in the capsule and the capsule container is sealed, so that the far-infrared emitting material does not come out of the capsule and cause a problem.
Examples of contents other than the far-infrared emitting material include a binder (binding agent) for fixing the far-infrared emitting material, a coating agent for coating the far-infrared emitting material, and a stabilizer for stabilizing the far-infrared emitting material. In the present invention, if it is not necessary, it is not necessary to include a content substance other than the far infrared radiation substance. The far-infrared radiation amount increases as the proportion of far-infrared radiation material in the content material increases.

The capsule 11 incorporating the far-infrared emitting material of the present invention radiates far-infrared rays emitted from the far-infrared emitting material to the outside of the capsule container. Accordingly, the material of the capsule container 12 is preferably a material that easily transmits far-infrared rays (particularly, a growing light wavelength region having a wavelength of 4 μm to 14 μm), and transmits far infrared light (particularly, a growing light wavelength region having a wavelength of 4 μm to 14 μm). The rate is preferably 60% or more. Examples thereof include plastics such as acrylic, polyvinyl chloride, and polyester, silicon (Si), germanium, calcium fluoride, barium fluoride, zinc selenide, zinc sulfide, sapphire, chalcogenide glass, and the like. FIG. 2 is a graph showing the transmittance of various plastics in the far-infrared region (growth light wavelength region). 2A shows the transmittance in the far infrared region of the acrylic resin, FIG. 2B shows the polyvinyl chloride resin, and FIG. 2C shows the polyester resin. These three types of plastics have a wavelength band with low transmittance, but in the far infrared region (growth light wavelength region) of 4 μm to 14 μm, the average transmittance is 60% or more. Can be used as a container for capsules. Since these resins have a high transmittance even in the visible light region, the state of the far-infrared radiation substance incorporated therein can be confirmed even with the naked eye, and thus is more preferable.

Next, a method for using the capsule containing the far-infrared emitting material of the present invention will be described.
A far-infrared emitting substance can be put into water or liquid (water, etc.) that is contaminated with organic substances, etc., and the contaminated water can be purified by the far-infrared radiation emitted from the far-infrared emitting substance. In general, the specific gravity is heavier than water, so if you put far-infrared radiation into water as it is, it will sink to the bottom. Accordingly, although the bottom water is purified, it is difficult to purify the water surface and the intermediate water. In order to improve this, it is conceivable to stir water, but a special stirrer is required, and it is unclear whether the water is evenly distributed even if stirred. In addition, if the far-infrared emitting material is chipped to become a fine powder, it is difficult to remove or separate the far-infrared emitting material from water. When a far-infrared emitting material is allowed to act on water to make drinking water, a powdered far-infrared emitting material is mixed with a binder such as silicone, and a bulking agent is added and directly put into water. In that case, since the far-infrared emitting material directly contacts water, some people dislike it. In addition, since the far-infrared emitting material may react with or dissolve with water, it becomes more difficult to separate and remove the far-infrared emitting material from the water.

Therefore, the above-described problems can be solved by using the capsule containing the far-infrared emitting material of the present invention. FIG. 3 is a view showing a state of the far-infrared emitting substance-containing capsule of the present invention placed in water. In FIG. 3, water or liquid 24 to be purified is placed in a container 21 such as a purification bowl, and a large number of capsules 23 having various specific gravities containing a far-infrared emitting material are placed therein. The purification layer in this case also includes a human feces storage layer and the like. In addition, since it is possible to remove the sludge layer in the swamp, it also includes swamps, rivers, and the sea. Among the capsules 23 containing the far-infrared emitting material, the capsule 23-1 having a specific gravity smaller than the specific gravity of water or the like floats on the surface of water or the like, and the capsule 23-2 having the same specific gravity as water or the like floats in water. The capsule 23-3 heavier than the specific gravity of water or the like sinks to the bottom. As described above, the capsule containing the far-infrared emitting material of the present invention can be uniformly distributed evenly in the water or the like placed in the container 21 such as the purification layer, and the far-infrared rays can be efficiently applied to the water. it can. If necessary, stirring may be performed from time to time, and even when a stirring device is used, since it can be uniformly and uniformly dispersed in water or the like with slight stirring, a simple and small stirring device is sufficient. Therefore, the cost increase is small because a low-cost stirring device is sufficient.

In addition, since the capsule container is made of acrylic or the like, the size of the capsule 23 can be adjusted to a certain level, and the capsule container material and contents are not eluted into water. Is also easy. Furthermore, since the material of the capsule container is acrylic or the like that does not react with water or the like, the collected capsule can be used repeatedly, and the running cost is extremely low. Even when used as drinking water, the use of a capsule container such as acrylic can maintain cleanliness, and since the far-infrared radiation material, which is not known, does not come into direct contact with water, the water can be used comfortably. I can do things. Furthermore, even if scale or dust adheres to the capsule container surface, the capsule container surface can be easily washed with another container.

Next, a method for producing capsules having various specific gravity will be described with reference to FIG. In FIG. 1, a content substance 13 containing a far-infrared emitting substance is contained in a capsule 11. Strictly speaking, the capsule 11 has a capsule container wall 12, a contents substance 13 containing a far-infrared emitting substance, and a contents substance 13. Other spaces (that is, spaces in which no content substance exists) 14. This space 14 is a low-pressure space containing nitrogen, oxygen, rare gas, carbon dioxide, or a mixed gas thereof, or close to a vacuum (or less than 1 atm). When the gas (for example, oxygen) and the content substance 13 including the far-infrared emitting substance react to change properties, the space 14 may be a gas that does not react (for example, an inert gas such as a rare gas) or a gas. It should be a low-pressure space that does not include vacuum and is close to vacuum. When the above gas is contained in the space 14, the pressure of the space 14 can be set to 1 atm or more, and the capsule container wall 12 can be prevented from being deformed by the water pressure when the capsule is suspended in water.
FIG. 7 is a diagram showing another embodiment of the far-infrared emitting substance-containing capsule of the present invention. The capsule 51 shown in FIG. 7 has a cylindrical shape with a diameter of m and a length of n, and has a hemispherical curved surface on the top and bottom sides. Fig.7 (a) is a side view of a cylindrical capsule, FIG.7 (b) is capsule center part A1-A2 sectional drawing. As shown in FIG. 7 (b), dents and grooves 52 are formed on the outside of the capsule container 51 in the vertical direction (from the top surface to the bottom surface). The far-infrared emitting substance-containing capsule having such a shape is used, for example, in a plastic bottle for drinking water. The diameter m of the capsule is made smaller than the diameter of the plastic bottle (for example, the diameter is 18 mm or less), and the capsule is placed in the plastic bottle to improve the quality of the drinking water in the plastic bottle. Note that the length n of the capsule container 51 can be relatively long (for example, 30 mm to 200 mm).
Even if the capsule may be used at the entrance of the plastic bottle when drinking drinking water, the depression or groove 52 is attached to the outside of the capsule container. The water in the plastic bottle can be smoothly taken out of the plastic bottle. In addition, a hollow and a groove | channel may be formed not only in the vertical direction of a capsule but in the helical direction and the other shape and direction in the diagonal direction.

The total weight of the capsule 11 is Mc, the weight of the capsule container wall 12 is Mw, the weight of the far infrared radiation material is Ms1, the weight of the contents other than the far infrared radiation material is Ms2, the total volume of the container is Vc1, and the container content The product is Vc2, the container wall volume is Vc3, the volume of the content material 13 containing the far infrared radiation material is Vs, the volume of the far infrared radiation material is Vs1, the volume other than the far infrared radiation material is Vs2, and the volume of the space 14 is Vx. To do. The specific gravity Sc of the whole capsule is Sc = Mc / Vc1 = (Mw + Ms1 + Ms2) / (Vc2 + Vc3) = (Mw + Ms1 + Ms2) / (Vs + Vx + Vc3). (However, since the weight of the space 14 is small, it is ignored. Further, when the far-infrared emitting substance and the contents other than the far-infrared emitting substance are mixed, it is assumed that there is no change in weight or volume.) Sc = (Sc3Vc3 + SsVs) where the specific gravity of the wall 12 is Sc3, the specific gravity of the content material 13 containing the far-infrared emitting material is Ss, the specific gravity of the far-infrared emitting material is Ss1, and the specific gravity of the contents other than the far-infrared emitting material is Ss2. / Vc1 = {Sc3Vc3 + Ss (Vc2-Vx)} / Vc1 = {Sc3Vc3 + SsVc2-SsVx) / Vc1. Therefore, the specific gravity Sc of the capsule (whole) can be changed by changing the volume Vx of the space 14 other than the content substance 13.

For example, the material of the capsule container wall 12 is acrylic (Sc3 = 1.2), the volume Vc3 of the capsule container wall 12 is 2 cm ³ , the container internal volume Vc2 is 6 cm ³ , and the far infrared radiation material is alumina (Al ₂ O ₃ ). Assuming that (Ss1 = 4) and no substances other than the far-infrared emitting substance are included, the specific gravity Sc of the capsule (whole) is Sc = 3.3−0.5Vx. Therefore, if the volume Vx of the space 14 is larger than 4.6 cm ³ , it floats on the surface of the water, if the volume Vx of the space 14 is 4.6 cm ³ , it floats in water, and if the volume Vx of the space 14 is less than 4.6 cm ^3. Sink into the bottom of the water. If an appropriate number of these capsules 23 (23-1, 2, 3) are added to the water etc. 24, the capsules 23 can be uniformly distributed in the water etc. 24 of the container 21 such as the purification layer.

It should be noted that within the range of ± 5% with respect to the specific gravity of the liquid such as water, including the variation, the same degree as the specific gravity of the liquid such as water is included. Therefore, the specific gravity larger than the specific gravity of the liquid such as water is a specific gravity exceeding + 5% than the specific gravity of the liquid such as water, and the specific gravity smaller than the specific gravity of the liquid such as water is −5 than the specific gravity of the liquid such as water. % Is a small specific gravity. In addition, if there is no need to float on the surface of a liquid such as water and it is not necessary to sink it to the bottom of the liquid such as water, the specific gravity equivalent to the specific gravity of the liquid such as water, that is, the specific gravity of the capsule is the specific gravity of the liquid such as water. It should be within ± 5% of. Preferably, if the range is narrower, it can be suspended in the middle part of the liquid such as water. For example, the specific gravity of the capsule is within ± 3% of the specific gravity of the liquid such as water, more preferably within ± 1%. It should have become. Accordingly, since the capsules (preparation of capsule containers, input amounts of contents, etc.) can be processed by the same process, the manufacturing method is simple. Even in this case, the capsules containing the far-infrared emitting substance can be uniformly distributed in the liquid such as water. Further, since liquids such as water have convection, capsules having a specific gravity comparable to the specific gravity of water and other liquids move on the convection water and move more uniformly in the water. In addition, if the capsule is suspended in a liquid such as water, it is easy to separate and remove the capsule from a liquid such as water using a mesh or the like. In the case of a capsule sinking at the bottom of water or the like, it can be separated and removed by draining water or the like from the top or side of the container. Capsules floating on the surface of water or the like can be separated and removed using a net or the like.

The capsule containing the far-infrared emitting material of the present invention has a small size that can be swallowed by humans (for example, 5 mm to 2 cm in length and 3 mm to 1 cm in diameter). Far-infrared rays are emitted from the far-infrared emitting material built into the capsule, and far-infrared rays pass through the capsule container wall and come out of the capsule, so that the digestive system such as the esophagus, stomach, and intestines is good for the body. Infrared emitting material passes through the capsule and can irradiate many parts of the body with far infrared rays. Acrylic and vinyl chloride are excellent in acid resistance and alkali resistance, and far-infrared emitting materials do not come into direct contact with the built-in substance, and far-infrared rays can be safely applied to the body. Usually, it will be excreted outside in one day. In the case of such swallowable capsules, it is not necessary to consider the specific gravity, so it is possible to pack a lot of far-infrared emitting material, but it is more efficient to make the far-infrared emitting material move within the capsule. Therefore, the ratio of the space 14 is preferably about 10% to 30% of the capsule internal volume. In addition, the shape of the capsule container that is swallowed by humans is not limited to the above-described cylindrical (cylindrical) shape, but also an oval shape or an ellipsoidal shape as shown in FIG. It may be a polygonal column shape such as a rectangular parallelepiped shape or a cubic shape, or a polygonal column shape with rounded corners. Further, in order to increase the surface area and to apply light efficiently, it is more effective if the capsule is made in a counterbore shape.

The capsule containing the far-infrared emitting material of the present invention reduces the contamination of the bath water by putting it in the bath, and also plays a role of preventing mold in the bathroom by the water vapor irradiated with the far-infrared rays. Even in the case of a bath, a capsule having a specific gravity smaller than that of hot water (for example, more than -5% relative to the specific gravity of water) can be put in the bath and / or the specific gravity of hot water It can be floated in the bath water by putting a capsule having the same specific gravity (for example, within ± 5% of the specific gravity of water) and / or a specific gravity larger than the specific gravity of hot water (for example, , More than + 5% of the specific gravity of water) can be put in the bottom of the bath so that the capsules can be evenly distributed in the bath water and efficiently Can remove water stains. In addition, if a far-infrared emitting material such as tourmaline with negative ion effect is used, capsules exist in the immediate vicinity of the body, so that the balance of biocurrent in which positive ions are excessive can be adjusted to improve health and activate the body. You can also plan. For the capsules incorporating the far-infrared emitting material with the specific gravity appropriately changed, those having the same specific gravity or those having various specific gravity mixed may be used according to the purpose and effect. For example, when a capsule lighter than the specific gravity of water is used, the water quality near the surface is purified, which is effective for improving the health of the upper body, face and head. When a capsule having the same specific gravity as water is used, it is effective in purifying the water quality of the whole water and promoting the health of the body part (for example, foot to neck) used in hot water. When capsules larger than the specific gravity of water are used, the water quality of the bottom of the water is purified, which is effective for improving the health of the soles and feet.

The capsule containing the far-infrared emitting material of the present invention can be produced, for example, by the following process. When the capsule container is plastic, molten or gel-like plastic is poured into a half-shaped mold of the capsule container and solidified to prepare a half-shaped capsule container. A predetermined amount (amount in which a predetermined space is formed) of a far-infrared emitting substance in the form of powder, granules or lumps is put therein. If necessary, a mixture of a far-infrared emitting material and a binder, a bulking agent or a stabilizer can be added. Thereafter, the other half-divided capsule containers are joined together by heating up and down, and the far-infrared emitting material is sealed and sealed in the capsule container to produce a capsule containing the far-infrared emitting material. When the upper and lower halved capsule containers are combined, the space can be filled with the gas by being sealed in the same atmosphere as the gas sealed in the space. The pressure in the capsule container can be adjusted by the pressure at the time of sealing, and it can be higher than 1 atm, 1 atm, or lower than 1 atm. When sealed in a high vacuum state, the inside of the capsule container can be brought to a pressure close to vacuum. Also, depending on the shape and size of the molding die, spherical shape, oval shape, ellipsoidal shape, cylindrical shape, columnar shape, rectangular parallelepiped shape, cubic shape, polygonal prism shape, polygonal prism shape with rounded corners and bottom, bottom portion Capsules of various shapes and sizes such as a rounded cylindrical shape can be produced. Regarding the size, when used in a bath, water tank, pool, lake, etc., the size may be set according to the size. In consideration of collection, it is necessary to make the size larger than the mesh of the filter. Also, considering the efficiency of purification and the like, the smaller the capsule size, the larger the surface area per volume, so the smaller the capsule, the better the efficiency. For example, when used in a bath, water tank or pool, 5 mm to 50 mm is preferable, and when used in a lake, about 50 mm to 300 mm is preferable.

FIG. 4 is a diagram showing a far-infrared radiation floating body goods (bath utensils) for a bath equipped with the far-infrared radiation material of the present invention. A far-infrared radiation floating body goods 30 for bath shown in FIG. 4A is obtained by solidifying a far-infrared radiation material with a binder such as silicone or resin in a hollow portion of a floating body 31 produced in a donut shape (annular shape) 32. Is attached. The back side has the same shape and comes in contact with hot water when it is floated in the bath. If the far-infrared emitting material 32 comes into direct contact with water, e.g., elution or chipping becomes a problem, cover the surface of the far-infrared emitting material 32 with a plastic film such as polyethylene film or PET (polyethylene terephthalate). It ’s fine. The floating body 31 is made of a material that is lighter than water, such as polystyrene foam. Alternatively, it may be floated by inflating with air or the like like a floating ring. In other words, this far-infrared radiant floating body goods for bath is a combination of a material with a specific gravity less than 1, a far-infrared radiant material, and other incidentals. It was designed to float. For example, when the volume of a floating object having a specific gravity of less than 1 is Vf, the weight is Mf, and the specific gravity is Sf, Sf = Mf / Vf <1, and the weight of things other than the floating object (including far-infrared radiation materials) Is Ma, volume is Va, far infrared radiation floating body goods for bath integrating Mb, volume is Vb, and specific gravity is Sb, Sb = Mb / Vb = (Mf + Ma) / (Vf + Va) < 1. (However, when integrated, Mb = Mf + Ma and Vb = Vf + Va are established.)

Similarly to the capsule, this also purifies water and reduces dirt such as bath water, and also plays a role of preventing mold in the bathroom by water vapor irradiated with far-infrared rays emitted from far-infrared emitting materials. If a far-infrared emitting material such as tourmaline that also has a negative ion effect is used, it is possible to improve the health by adjusting the balance of the biocurrent in which positive ions are excessive. That is, health promotion and water purification can be realized simultaneously. The far-infrared radiating float goods 33 for bath shown in FIG. 4 (b) is obtained by adding artificial flowers 34 on the far-infrared radiating float goods 30 for bath shown in FIG. 4 (a). By using such a far-infrared radiation floating body goods 33 for bath, it is possible to enjoy a pleasant bath that is healthy and does not pollute the bathroom.

When the far-infrared emitting material is directly put into water, it is difficult to separate and remove the powdered far-infrared emitting material from the purified water if the powdered far-infrared emitting material is directly put into water. Therefore, a water treatment that improves the water quality by using a mixture of powdered far-infrared radiation material such as silicone resin mixed with powdered far-infrared radiation material and purifying the mixture by putting it in water. When the device is left in the water for a long time, water, dust, and dirt adhere to the mixture, and the far-infrared rays radiated are blocked to reduce the water purification ability. In order to prevent this, there is a method in which the mixture containing the far-infrared emitting material is appropriately removed from the water and washed to remove adhering dirt, dust, and dirt. However, it takes time and is taking out the mixture from the water. Since water is not purified during this period, efficiency is poor and impractical. Therefore, a pump for introducing air is attached to the water treatment apparatus, and air is sent to the water and the water is circulated by using this pump. As a result, it is possible to prevent dirt and dust from adhering to the mixture. In addition, as long as the mixture is added, the ability to purify water is maintained, and it becomes possible to cause far infrared rays to act on water efficiently.

FIG. 5 is a view showing a sheet containing the far-infrared emitting material of the present invention. The sheet 41 shown in FIG. 5A is a sheet-like material obtained by mixing a far-infrared emitting material such as powder with a binder such as silicone resin or epoxy resin. Alternatively, a far-infrared emitting substance may be applied or impregnated with a binder or an adhesive on a cloth or a cork sheet having good air permeability and heat retention. When this far-infrared emitting substance-containing sheet is brought into contact with the skin, it acts on the blood and the body temperature rises. According to a clinical experiment at a certain hospital, it is known that body temperature rises once in 2 minutes. Therefore, when this sheet is applied to the affected area during calf or other muscle spasms, the pain is released within a few minutes. When there is a risk of convulsions, for example, to prevent muscular spasms of the shin when driving for a long time, it is possible to prevent the convulsions by placing them under the socks in advance. In addition, the symptoms can be relieved and improved or eliminated by using the muscle pain, low back pain, forty shoulders, etc. on the affected area. A conventional commercially available poultice material used for the same purpose cannot be reused once it is used, but the sheet of the present invention can be used semi-permanently, so there is a great merit in total cost.

Furthermore, this far-infrared emitting substance-containing sheet has the effect of increasing body temperature. For example, it is said that immunity improves by 30% or more when body temperature rises once. Therefore, when the far-infrared emitting material-containing sheet is applied to the abdomen, the intestine is directly warmed, which is effective for constipation, intestinal tone and the like. In this case, by increasing the thickness of the sheet and increasing the heat capacity and applying it to the abdomen, it is possible to raise the body temperature and adjust the physical condition for a long time, so that the improvement of the symptoms is accelerated. The far-infrared emitting material-containing sheet of the present invention can also be applied to the stomach wrap, attach this sheet to the front side of the stomach wrap and apply it to the abdomen, and attach this sheet for back pain on the back side of the stomach wrap and apply it to the waist So you can make a stomach wrap that is good for both the intestines and the waist. If you put it under gloves, a hat, or shoes, you can use it as a winter-proof item in winter. If a far-infrared emitting material such as tourmaline that also has a negative ion effect is used, it is possible to improve the health by adjusting the balance of the biocurrent in which positive ions are excessive.

FIG. 8 is a table showing the effect of the far-infrared emitting material-containing sheet of the present invention by a clinical experiment in which the far-infrared emitting material-containing sheet of the present invention is applied to a patient. FIG. 8A shows symptom evaluation data (results of clinical experiments). By applying the far-infrared emitting substance-containing sheet of the present invention as a poultice to 5 patients with osteoporosis, 4 patients with back pain, 4 patients with knee arthritis, and 1 patient with cervical sprain, This is a look at the process. 50% (5) of patients with the combined effects of significant effects and effectiveness, 80% of patients improved when combined slightly (3), the far-infrared emitting material containing sheet of the present invention is Excellent improvement effect for back pain, knee arthropathy, and cervical sprain. Moreover, since the number of people who deteriorated was 0%, it was found that the far-infrared emitting substance-containing sheet of the present invention had no adverse effect on the patient's body. FIG. 8B shows the result of examining the temperature of the skin surface of the affected area to which the far-infrared emitting substance-containing sheet is applied. FIG. 9 is a graph showing the relationship between the skin surface temperature (average value) of the entire affected area and the poultice time. When the far-infrared emitting substance-containing sheet is applied, the temperature of the affected area increases in a short time, and the temperature can be maintained for 3 days or more. In addition, the temperature around the portion to which the far-infrared emitting material-containing sheet was applied increased with time. Furthermore, depending on the patient, the temperature may rise by 1 ° C or more in a short time of 120 seconds. By applying the far-infrared emitting substance-containing sheet of the present invention, it is considered that the affected area of the patient is kept at 1 ° C. or more and the therapeutic effect is improved.

Furthermore, since it has been found that the far-infrared emitting material-containing sheet of the present invention is effective in relieving constipation, for example, the far-infrared emitting material-containing sheet of the present invention is applied to the waist part on the back of the body and the abdominal part on the front of the body. If a belt (belt for lower back and abdomen wrapping) that hits is produced, it can have an effect on both intestinal tone and lowering back pain symptoms. The wearing part may be divided into at least two parts, the waist part on the back of the body and the belly part on the front of the body, and the waist part on the back of the body and the belly part on the front of the body are connected continuously. The far-infrared emitting substance-containing sheet may be applied to the entire circumference of the waist and abdomen, or may be divided and attached to other portions. If the waist part and the abdomen part of the waist belt belt are doubled in a bag shape and the far-infrared radiation-containing material-containing sheet of the present invention is inserted into the bag-like part, it is easy to put in and out and to wear it easily. . Alternatively, even if a waist fastener is used on the inside and the inside (body side) of the waist and abdomen portions of the belt for waist and abdomen, the far-infrared radiation-containing sheet can be attached to the surface fastener, and it is easy to wear and the affected part The far-infrared radiation-containing material-containing sheet can be directly applied to.

Furthermore, since the far-infrared emitting material-containing sheet has an effect of improving blood circulation, this sheet is formed into a mask shape as shown in FIG. 5B so as to fit the face, neck, head, etc. By producing the object 42 and applying it to the relevant part, it is possible to give the skin a warming effect and a beauty effect, such as increasing the gloss of the skin and stretching the wrinkles. If you sleep on your face when you go to bed, you can have a restful sleep due to negative ions. Other body parts such as ankles, knees, elbows, thighs, arms, shoulders, etc. You can also have it. If a 3D printer is used, an optimal mask for the person can be manufactured.

In addition, when the sheet | seat of this invention is directly applied to skin as mentioned above, it may become itchy by sweat etc. depending on a person, and eczema may be made. To prevent this, eczema can be prevented by attaching a thin cloth or thin plastic sheet to one side of the sheet that comes into contact with the skin, or by making multiple holes in the sheet.

As another embodiment of the present invention, there is an application in which a far-infrared emitting substance is mixed with a wall material. In Japanese architecture, it is said that plaster is good for the body, and if you live in a room with a plaster wall, allergies and other illnesses will be corrected. By using powdered, granular, or massive far-infrared radiation materials mixed with such plaster walls, the room will be filled with growing rays and negative ions to create a healthy home. I can do it. There is also an advantage that mold is less likely to occur.

Although various application methods of far-infrared emitting materials have been described in detail above, regarding other parts that have been described and described in a certain part of the specification, and can be applied without contradiction, the other parts will be described. Needless to say, the contents can be applied. Furthermore, the above-described embodiment is an example, and various modifications can be made without departing from the scope of the invention. Needless to say, the scope of rights of the present invention is not limited to the above-described embodiment.

In addition to the above, the present invention can also be used for purification of various waters and liquids, such as purification of domestic drainage tanks and sewers, and for the cultivation of marine products such as fish shrimp. Moreover, this invention can be used also in a hot spring and can further improve the effect of a hot spring. In addition, reverse osmosis membranes commonly used for water purification cause clogging when used for a long period of time. By adding far-infrared radiation that makes water fine, clogging is prevented and the life of the reverse osmosis membrane is extended. And cost can be reduced.

11 ... capsule, 12 ... capsule container wall, 13 ... content substance,
14 ... space, 21 ... purification bowl, 23 ... capsule, 24 ... liquid,
30 ... Far-infrared radiation floating goods for baths, 31 ... Floating objects,
32 ... Far-infrared emitting material, 33 ... Far-infrared emitting floating goods for baths,
34 ... artificial flower, 41 ... far-infrared emitting material-containing sheet, 42 ... mask,
51 ... capsule container, 52 ... depression,

Claims (26)

A capsule with a built-in far-infrared emitting material, wherein the capsule is sealed with a far-infrared emitting material. The far-infrared emitting substance-embedded capsule according to claim 1, wherein the substance of the capsule container has an average transmittance of 60% or more of far infrared rays having a wavelength of 4 µm to 14 µm. In the capsule container, there is a space without a content substance including a far-infrared emitting substance, and the specific gravity of the capsule is adjusted by changing a ratio of the space to the internal volume of the capsule container. The capsule with a built-in far-infrared emitting material according to claim 1 or 2. The remote capsule according to claim 3, wherein when a plurality of the capsules are put in a liquid, a specific gravity of a part or all of the plurality of capsules is within a range of 5% from a specific gravity of the liquid. Capsule with built-in infrared radiation material. The far-infrared emitting substance-embedded capsule according to claim 3 or 4, wherein the space in the capsule container contains at least one kind of gas selected from nitrogen, oxygen, carbon dioxide, and rare gas. The far-infrared emitting substance-embedded capsule according to any one of claims 3 to 5, wherein the pressure in the space in the capsule container is less than 1 atm. The far-infrared radiation substance-embedded capsule according to any one of claims 3 to 5, wherein the pressure in the space in the capsule container is greater than 1 atmosphere. The capsule with a far-infrared emitting material according to any one of claims 1 to 7, wherein the capsule container is made of plastic. The capsule with built-in far-infrared radiation material according to claim 8, wherein the plastic is acrylic, polyvinyl chloride, or polyester. The capsule container is characterized in that the diameter of the capsule container is equal to or smaller than the inner diameter of the drinking mouth of the drinking water bottle, and a depression is formed on the outside of the capsule container. The capsule with a built-in far-infrared emitting material according to any one of claims 1 to 9, wherein the capsule is used by being put in use. A liquid purifying method, wherein the far-infrared emitting substance-embedded capsule according to any one of claims 1 to 10 is placed in a liquid to purify the liquid. 12. The health promotion method according to claim 11, wherein the far-infrared radiation material is a material that also has a negative ion effect. A bath product characterized by integrating a substance having a specific gravity smaller than 1 and a far-infrared emitting substance so as to float on the surface of the water. The bath article according to claim 13, wherein the substance having a specific gravity of less than 1 is polystyrene foam or a floating ring. The bath product according to claim 13 or 14, further comprising artificial flowers. A far-infrared radiation-containing material-containing sheet characterized by being applied to an affected area for the purpose of reducing constipation, preventing convulsions, spasm pain, muscle pain, joint pain, or back pain. The cloth or plastic film is attached to the sheet surface on the side in contact with the skin to prevent the far-infrared substance from directly contacting the skin, thereby reducing or preventing eczema. Far-infrared emitting material-containing sheet. The far-infrared emitting substance-containing sheet according to claim 16 or 17, wherein a plurality of holes are provided in the sheet to reduce or prevent eczema. The far-infrared-radiating substance-containing sheet according to any one of claims 16 to 18, wherein the far-infrared emitting substance-containing sheet according to any one of claims 16 to 18, wherein the sheet has a shape adapted to a shape of a part of a body and has a heat retaining effect. The far-infrared emitting substance-containing sheet according to claim 18 or 19, wherein the sheet thickness is 3 mm or more and the heat capacity is increased. The far-infrared radiation-containing material-containing sheet according to claim 19 or 20, characterized in that the sheet is adapted to the shape of the face. An abdominal waist belt capable of simultaneously applying the far-infrared emitting substance-containing sheet according to any one of claims 16 to 20 to at least two affected areas of a waist part on the back of the body and an abdomen on the front of the body. A far-infrared radiation-containing material for building walls, characterized by mixing a powdery far-infrared radiation material and a wall material. The far-infrared-radiating substance-containing building wall material according to claim 23, wherein the wall material is plaster. A water treatment device for purifying water by adding a mixture of binder and far-infrared radiation material, and using a pump to send air to the water to circulate the water so that dirt is not attached to the mixture. Water treatment device characterized by. The water treatment apparatus according to claim 25, wherein the binder is a silicone resin.