KR20030079902A - Band for radiate far infrared ray - Google Patents

Abstract

PURPOSE: A medical band for radiating far-infrared ray and anions is provided to relieve pain of affected part due to muscular pain or arthritis without adverse effect by attaching the band to the affected part. CONSTITUTION: The band is produced by a process comprising coating surface of a film paper with a far-infrared ray radiation coating material while applying adhesive on the other side thereof. The far-infrared ray radiation coating material is prepared by combining 45-65wt.% of silicon oxide, 7-9wt.% of feldspar oxide, 10-20wt.% of borax, 4-6wt.% of boric acid, 2-4wt.% of potassium carbonate, 1-1.2wt.% of potassium nitrate, 3.3-6.8wt.% of alumina hydroxide, 1.4-1.8wt.% of limestone, 0.8-1wt.% of barium carbonate, 0.7-0.8wt.% of lithium, 1-1.3wt.% of zirconium, 0.2-0.4wt.% of phosphate, 3-3.5wt.% of carbon, 0.4-0.5wt.% of magnesium carbonate and 0.2-0.22wt.% of coloring agent and blending them under stirring for 0.5-1 hour; putting the admixture into a glass furnace at 1350-1550deg.C to fuse it for 19-21 hours to form the far-infrared ray radiation material in molten state; cooling the material in cold water then breaking it into fine powders; mixing 10-90wt.% of the powders and 10-90wt.% of molten resin to form the coating material.

Description

Band for radiate far infrared ray

The present invention relates to a band for far-infrared radiation, and more particularly, the anti-microbial activity and budding of the human body through far-infrared radiation emitted from the band by attaching a material of which far-infrared radiation is coated on a band of a predetermined size to the skin of a neuralgia or arthritis site It relates to a far-infrared radiation band for promoting metabolism to treat neuralgia or arthritis.

It is a well-known fact that the quality of life has been improved in general with the development of industry and economic richness. However, although economically and the quality of life is better than in the past, it will also be true that modern people are suffering from heavy work due to heavy work or stress.

In particular, most of the office workers who sit in office chairs and work, most of them are muscle pain diseases such as shoulder pain, fifty shoulders and low back pain due to structural or mechanical abnormalities such as lumbar spine or sacral spine. In the case of drivers or elderly people who perform a lot of repeated motions, most of them are diseases such as arthritis due to inflammation of joints caused by the infiltration of various bacteria such as Mycobacterium tuberculosis. In addition, the reality is that it is suffering from various diseases.

Therefore, muscle pain diseases such as shoulder pain, fibromyalgia, and lumbar spine or sacral pain such as lumbar pain, as described above, and joint inflammation caused by invasion of various bacteria such as Mycobacterium tuberculosis in the joint Diseases such as arthritis and other various diseases cause not only their grievances but also many problems in interpersonal relationships, social life and family life.

As the problems described above are raised, interest in diseases such as arthritis and arthritis such as shoulder pain, shoulder pain, low back pain, etc. is heightened, and these desires are erupted in various forms. That is, drugs or medical devices for preventing various diseases and therapeutic drugs or supplements for treating various diseases have been developed and can be purchased and used anywhere in a pharmacy.

On the other hand, humans will have a consistent mind in their desire to live a healthy life without disease. Accordingly, as described above, drugs and supplements for preventing or treating myalgia diseases such as shoulder pain, shoulder pain, low back pain, and arthritis have been diversified.

In particular, health band products using far infrared rays that generate and emit far infrared rays and anions have recently been introduced. Such a health band using far infrared rays can be treated with muscle pain or arthritis such as shoulder pain, fifty shoulders, low back pain through the action of far-infrared radiation by simply attaching to muscle pain areas such as shoulder pain, fifty shoulders, low back pain or arthritis.

However, since the above-mentioned conventional far-infrared health band has a small amount of far-infrared radiation, a health bed that can expect improved treatment effect is required because the pain relief effect of muscle pain and arthritis such as shoulder pain, fifty shoulders, low back pain is lowered. .

The present invention was devised to solve the above-mentioned problems, and a plurality of materials capable of emitting far infrared rays were mixed and stirred at a predetermined ratio, and then melted through a glass melting furnace to uniformly refine the far-infrared radiating material and the molten resin. The far-infrared radiation coating material mixed at a ratio is coated on the surface of the silver foil film of the synthetic resin material which is made of silver foil coating having elasticity to maintain its shape, thereby producing a band that can emit far infrared rays, thereby attaching to the affected part such as muscle pain or arthritis. It is an object of the present invention to provide a band for far-infrared radiation, in which far-infrared rays and negative ions generated and emitted from far-infrared radiation substances are acted directly or indirectly on the affected part to alleviate the pain of the affected part.

Another object of the present invention is to attach to the affected part, such as myalgia or arthritis as described above to provide a cheaper manufacture and supply of products that can alleviate the pain of the affected part without side effects through far-infrared and negative ions generated have.

Another object of the present invention is to produce a far-infrared radiation band that can alleviate the pain of the affected area without side effects through far-infrared rays and anions generated by attaching to the affected area such as myalgia or arthritis, such as pharmacies, convenience stores and supermarkets It's about making it easy to buy and use it.

In addition, the present invention can be used semi-permanently by manufacturing a band for far-infrared radiation to mitigate the pain of the affected part without side effects through the far-infrared and negative ions generated and radiated by attaching to the affected part, such as myalgia or arthritis, in addition to the purpose described It is in such a way.

1 is a perspective view showing a band for far infrared radiation according to the present invention.

Figure 2 is a cross-sectional view showing a band for far infrared radiation according to the present invention.

Figure 3 is a perspective view of the actual product of the far infrared radiation band according to the present invention.

** Description of symbols for the main parts of the drawing **

100. Far-infrared radiation band 110. Foil film

120. Far-infrared radiation coating layer 130. Adhesive

140. Protective paper

The present invention configured to achieve the above object is as follows. That is, the far-infrared radiation band according to the present invention is in close contact with or attached to the affected part of muscle pain or arthritis such as shoulder pain, fifty shoulders, low back pain, etc. to the far-infrared radiation band to alleviate the occurrence of antimicrobial power and pain through the generation and radiation of far infrared rays. In the far infrared radiation band is 45 to 65% by weight of silicon oxide, 7 to 9% by weight feldspar, 10 to 20% by weight borax, 4 to 6% by weight boric acid, 2 to 4% by weight potassium carbonate, 1 to 1.2% by weight %, Alumina Hydroxide 3.3 ~ 6.8%, Limestone 1.4 ~ 1.8%, Barium Carbonate 0.8 ~ 1%, Lithium 0.7 ~ 0.8%, Zircon 1 ~ 1.3%, Phosphoric Acid 0.2 ~ 0.4%, Carbon 3 ~ 3.5 Mix by weight ratio, 0.4 to 0.5% by weight of magnesium carbonate and 0.2 to 0.22% by weight of colorant, and mix by stirring for 0.5 to 1 hour, and then put into a glass melting furnace of 1350 ~ 1550 ℃ for 19 to 21 hours Far-infrared pulverized into a fine powder by cooling the molten far-infrared radiation substance in the molten state with cooling water The far-infrared radiation coating material containing 10 to 90% by weight of the pre-radiating material and 10 to 90% by weight of the molten resin is coated on the surface of the film of the synthetic resin material which maintains its shape through its elastic force. One side of the film film is made by bonding an adhesive that is harmless to the human body.

As described above, the film of the synthetic resin material in the configuration of the band for far-infrared radiation is formed of silver foil film made of silver foil coating. At this time, the far-infrared radiation coating agent is coated with the surface of the silver foil coating surface.

On the other hand, in addition to the above-described configuration, a protective paper for protecting the adhesive is attached to the adhesive surface to which the adhesive is attached so as to be detachable in use.

Hereinafter will be described in detail with respect to the far infrared radiation band according to an embodiment of the present invention.

1 is a perspective view showing a far infrared radiation band according to the present invention, Figure 2 is a cross-sectional view showing a far infrared radiation band according to the present invention, Figure 3 is a perspective view showing the actual product of the far infrared radiation band according to the present invention.

First, the theoretical background of the far infrared ray will be described before explaining the far infrared radiation band according to the present invention. That is, far infrared rays are infrared rays having a wavelength of 30 to 1,000 microns. When the infrared rays are absorbed by the human body, the far infrared rays penetrate into the subcutaneous depth 80 times deeper than normal heat and are radiated to the moisture and protein molecules that make up the cells in the human body. It activates the tissues by vibrating finely about 2,000 times a minute. By activating these tissues, the vital activity of the human body becomes more active. In addition, the process of cell activity as described above not only generates heat energy, but also has an effect of naturally discharging waste materials, which are harmful substances possessed by cells in the human body.

In addition to the effects described above, far infrared rays affect the cells, which are the most basic tissues of the human body, which promotes blood circulation and strengthens the body's self-defense ability to promote health recovery, as well as relieve pain, remove heavy metals in the body, promote sweating, and sleep. It is known to have effects such as deodorant effect, antibacterial effect, insect repellent effect, dehumidification effect, mold growth prevention, dehumidification and air purification.

Meanwhile, since the first discovery by FW Herchi of Germany, the far-infrared ray described above has been used industrially by the use of far-infrared rays by Germany's Schönk et al. It is known to emit far infrared rays having a predetermined wavelength although there is a difference in degree. Such far infrared rays are vibration waves of electromagnetic force lines caused by molecular motions inside the far infrared emitters, and the generation forms include cooling and heat radiation. In addition, since far infrared rays are a kind of electromagnetic waves in nature, they are reflected when they collide with an object.

The following is a description of the far-infrared radiation band 100 according to the present invention, the process according to the production of nuclear radiation material in the present invention is as follows. First, silicon oxide 45-65%, feldspar 7-9%, borax 10-20%, boric acid 4-6%, potassium carbonate 2-4%, saltpeter 1-1.2%, alumina hydroxide 3.3 ~ 6.8 wt%, limestone 1.4-1.8 wt%, barium carbonate 0.8-1 wt%, lithium 0.7-0.8 wt%, zircon 1-1.3 wt%, phosphoric acid 0.2-0.4 wt%, carbon 3-3.5 wt%, magnesium carbonate It mix | blends with the compounding ratio of 0.4-0.5 weight% and a coloring agent 0.2-0.22 weight%.

As described above, after mixing a plurality of far-infrared radiation materials at a predetermined mixing ratio, the mixture is stirred in a mixing vessel for 0.5 to 1 hour through a 33 rpm stirrer, and silicon oxide, feldspar, borax, boric acid, potassium carbonate, and saltpeter To facilitate the mixing of far-infrared radiation materials of alumina hydroxide, limestone, barium carbonate, lithium, zircon, phosphoric acid, carbon, magnesium carbonate and colorant.

On the other hand, after putting the far-infrared radiation material into the mixing vessel and mixing it by stirring through a 33 rpm stirrer for 0.5 to 1 hour, the far-infrared radiation material mixture is added to the glass melting furnace and 19-21 under the temperature condition of 1350-1550 ° C. The far-infrared radiant in the molten state is prepared by melting through heating for a time.

As described above, after cooling the molten far-infrared radiation produced by heat-melting for 19-21 hours under a temperature condition of 1350-1550 ° C. through a glass melting furnace with a cooling water, the ultra-far infrared radiation in the cooled state is very fine. It is pulverized into a far-infrared projectile on a fine powder in a state.

As described above, when the molten far-infrared radiating material is cooled through a glass melting furnace under a temperature condition of 1350 to 1550 ° C., it becomes a far-infrared radiating material that emits far infrared rays by itself. Therefore, all of the molten far infrared radiators melted through the glass melting furnace, the far infrared radiators in the cooled state, and the far infrared radiators in the micropowdered state may be referred to as far infrared radiators. In the present invention, however, the far-infrared radiating material in a finely powdered state is used.

Of course, the far-infrared radiating material of the molten state produced in the present invention can be manufactured into a product that emits far-infrared rays when injected into a molding machine that can be molded into a product of the shape to be manufactured to form a certain shape.

In the present invention, since it is not intended to use the far-infrared radiation product molded in a predetermined form by injecting the far-infrared radiation material in the molten state as described above, a separate description will be omitted. However, the far-infrared radiating material in the state of cooling the molten mixture as described above has various colors, emits far-infrared rays having a wavelength of 0.26 to 1,000 µm, and is prepared at a degree of 85 to 87%.

As described above, 10 to 90% by weight of the far-infrared radiating material prepared in the form of fine powder and 10 to 90% by weight of the molten resin are mixed to prepare a far-infrared radiating material coating agent as a coating agent. In this case, the molten resin refers to a thermoplastic resin (a resin capable of deforming the shape when it is heated again after being molded by applying heat, and uses plasticity to cause plastic deformation but reversibly hardens upon cooling. It consists of a polymer material of).

As described above, far-infrared radiation generating and emitting far infrared rays include silicon oxide, feldspar, borax, boric acid, potassium carbonate, saltpeter, alumina hydroxide, limestone, barium carbonate, lithium, zircon, phosphate, carbon, magnesium carbonate, and colorant. Blending and mixing of far-infrared radiating materials, heating and melting of mixed far-infrared radiating materials, cooling and micropowdering of molten far-infrared radiating materials, and far-infrared radiation by mixing finely powdered far-infrared radiating materials and thermoplastic molten resin It is prepared through the manufacturing process as a material coating agent.

On the other hand, the far-infrared radiation band 100 according to the present invention is a silver foil film paper 110 of a synthetic resin material to maintain its shape through its elastic force, as shown in Figures 1 to 3, through the process as described above The far-infrared radiant coating agent prepared as a coating agent is coated on the surface of the silver foil film 110, the far-infrared radiant coating layer 120, the far-infrared radiant coating agent is coated on the foil film 110, the far-infrared radiant coating layer 120 is formed It is made of a configuration of the protective paper 140 to protect the adhesive surface adhered to one side of the adhesive 130 and the adhesive 130, which is harmless to the human body attached to the affected part of the muscle pain or arthritis such as shoulder pain, fifty shoulders, low back pain.

In the above-described configuration, the foil film 110 is made of silver foil on the surface of the film of the synthetic resin material. The reason for the silver foil coating on the film paper surface of the synthetic resin material is to allow the far-infrared rays emitted and reflected in the human body to be reflected back into the human body by the silver foil coated surface.

That is, the far-infrared rays radiated from the far-infrared radiation coating layer 120 into the human body are a kind of electromagnetic waves, and are reflected when they collide with an object. Therefore, if the far infrared rays reflected from the human body is not reflected back into the human body by the foil film 110, it will be natural that the pain relief effect of the affected area is lowered. Therefore, the composition of the far-infrared rays reflected from the human body by silver foil coating on the film paper surface of the synthetic resin material may be very important to be reflected back into the human body by the silver foil coating surface on the silver foil film 110.

In the drawings of the present invention, the silver foil film is referred to collectively by reference numeral 110, and the silver foil coating layer is not indicated as a separate reference numeral. Therefore, the silver foil film 110 itself may be regarded as being made of a film paper made of silver foil coating.

In the configuration of the present invention as described above, the far-infrared radiation coating layer 120 is formed by coating the far-infrared radiation coating material on the flat surface of the silver foil film paper 110 made of silver foil coating on the film of the synthetic resin material is coated on the surface of the silver foil coating surface It can be seen that it is processed. In addition, the above-described far-infrared radiation coating layer 120 may be formed only on one surface of the silver foil film 110, the coating of the far-infrared radiation coating material and the preparation of the far-infrared radiation band 100 according to the present invention more easily. In order to do so, it is better to coat the entire surface of the silver foil film 110.

And, in the configuration of the far-infrared radiation band 100 according to the present invention, the foil film 110 is manufactured in a wide variety of sizes. That is, when the affected part is used in a small place to use a small far-infrared radiation band (100), if the affected part is used in a large place manufactured to a variety of sizes to use a large far-infrared radiation band (100) do.

Moreover, the far infrared radiation band 100 according to the present invention can be used semi-permanently as long as far infrared rays are generated and emitted. That is, the far-infrared radiation coating layer 120 from the silver foil film 110 can be used semi-permanently as long as far-infrared rays are generated and radiated without being peeled or damaged. Of course, if the function of the adhesive 130 is lost, it may be inconvenient to use, but if there is a tape or the like that can fix the far-infrared radiation band 100 to the affected area as far infrared is generated and radiated, the function of the adhesive 130 is It can be used even if it is lost.

The far-infrared radiation band 100 of the present invention configured as described above, after removing the foil film 110 from the protective paper 140, the adhesive 130 is adhered to the affected area of muscle pain or arthritis such as shoulder pain, shoulder pain, back pain It is used by sticking the adhesive surface.

As described above, the far-infrared radiation coating material is coated and the silver foil film 110 having the far-infrared radiation coating layer 120 is attached to the affected part of muscle pain or arthritis such as shoulder pain, shoulder pain, low back pain, etc. Far-infrared rays are generated and radiated from the far-infrared radiating material of the material coating layer 120 to act directly or intermittently on the affected part where the silver foil film 110 is attached. As time goes by in this state, the pain of a affected part is alleviated by far-infrared rays which generate | occur | produce and radiate.

Of course, the phenomenon in which the pain of the affected part is alleviated by attaching the far infrared radiation band 100 of the present invention to the affected part is, as described above, the far infrared rays generated and radiated from the far infrared radiating material of the far infrared radiating material coating layer 120 are absorbed by the human body. When it penetrates into the subcutaneous depth 80 times deeper than normal heat, it is radiated to the moisture and protein molecules that make up the cells in the human body, and activates the tissue by vibrating finely shaking the cells about 2,000 times a minute. .

Therefore, as described above, the vital activity of the human body becomes more active by the activation of cellular tissues. In addition, the process of cell activity as described above not only generates heat energy, but also has an effect of naturally discharging waste materials, which are harmful substances possessed by cells in the human body.

As described above, the far-infrared radiation band 100 according to the present invention not only has an advantage of being manufactured and supplied at a low manufacturing cost, but also shows an excellent effect in the effect compared to the manufacturing cost.

The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the technical idea of the present invention.

As described above, according to the present invention, a plurality of materials capable of emitting far-infrared rays are mixed and stirred at a predetermined ratio, and then melted through a glass melting furnace to make fine-powdered far-infrared radiation materials and molten resin in a predetermined ratio. The coating material is coated on the surface of the silver foil film of the synthetic resin material, which is made of silver foil coating to maintain its shape due to its elasticity, to produce a band capable of emitting far infrared rays.It is attached to the affected area such as myalgia or arthritis. Far-infrared rays and negative ions are emitted to the affected area directly or indirectly to reduce the pain of the affected area.

As another effect of the present invention, as described above, by attaching to the affected part such as myalgia or arthritis, it is possible to manufacture and supply a product which can alleviate the pain of the affected part without side effects through far-infrared rays and negative ions generated. .

Another effect of the present invention is to produce a far-infrared radiation band to alleviate the pain of the affected part through side effects, such as muscle pain or arthritis, generated and radiated far infrared and anion without side effects, such as pharmacies, convenience stores and supermarkets It's easy to buy and use anywhere.

In addition, the present invention can be used semi-permanently by manufacturing a band for far-infrared radiation to mitigate the pain of the affected part without side effects through the far-infrared and negative ions generated and radiated by attaching to the affected part, such as myalgia or arthritis, in addition to the effects described above. It has an effect.

Claims (3)

In the band for far-infrared radiation, which adheres to or adheres to the affected areas of muscle pain or arthritis such as shoulder pain, fifty shoulders, low back pain, etc. The far-infrared radiation band is 45 to 65% by weight of silicon oxide, 7 to 9% by weight of feldspar, borax 10 to 20% by weight, boric acid 4 to 6% by weight, potassium carbonate 2 to 4% by weight, saltpeter 1 to 1.2% by weight , Alumina Hydroxide 3.3-6.8%, Limestone 1.4-1.8%, Barium Carbonate 0.8-1%, Lithium 0.7-0.8%, Zircon 1-1.3%, Phosphoric Acid 0.2-0.4%, Carbon 3-3.5% %, Magnesium carbonate 0.4 ~ 0.5% by weight and colorant 0.2 ~ 0.22% by weight of the mixture by mixing for 0.5 to 1 hour by stirring, and then added to the glass melting furnace of 1350 ~ 1550 ℃ melted for 19 to 21 hours The far-infrared radiant coating material, which mixes 10 to 90% by weight of the far-infrared radiant material and 10-90% by weight of the melted resin, which is pulverized into fine powder by cooling the molten far-infrared radiant material in the state of being cooled, is formed through its elastic force. Film paper coated on the surface of the film of synthetic resin material to be maintained but coated with far-infrared radiation coating Far-infrared radiation band, characterized in that the adhesive is harmless to the human body made of one side. According to claim 1, wherein the film of the synthetic resin material is formed of a silver foil film made of a silver foil coating far infrared radiation band, characterized in that the far-infrared radiation coating material is coated on the surface of the silver foil coating. The band for far-infrared radiation according to claim 1 or 2, wherein a protective paper for protecting the adhesive is detachably attached to the adhesive surface to which the adhesive is attached.