KR200413378Y1 - Fabrics spreaded by mineral radiating far infrared ray - Google Patents

Abstract

The present invention is a fabric coated with far-infrared radiation mineral, woven fabric; Far-infrared radiation minerals pulverized to fine size; And a natural adhesive for adhering and applying a far-infrared radiation mineral to the fabric fabric; The pulverized far-infrared radiant material is bonded to the fabric fabric, it is characterized in that the crimped, dried in a state in which the adhesive is applied.

The fabric coated with the far-infrared radiation mineral according to the present invention has a fabric fabric, a finely pulverized far-infrared radiation mineral, and a pollution-free natural adhesive, thereby maximizing the radiation efficiency of far-infrared rays along with the smooth surface characteristics, thereby restoring the physiology and fatigue of the human body. To activate the action.

Textile, Mineral, Far Infrared Ray, Natural Adhesive, Crimping

Description

Fabrics spreaded by mineral radiating far infrared ray

1 is a plan view of a fabric coated with a mineral that emits far infrared rays on one surface according to a preferred embodiment of the present invention.

Figure 2 is a process chart showing a process for producing a fabric coated with a mineral that emits far infrared rays according to the present invention.

Figure 3 is a schematic diagram showing a process of applying a mixture of far-infrared ray mineral and natural adhesive to the fabric fabric.

4 is a schematic diagram showing a process in which a fabric coated with far-infrared radiation mineral material is inserted and passed through a pressing roller after the process of FIG. 3 is finished.

Figure 5 is a schematic diagram showing a process after the process of Figure 4, the fabric passed through the pressing roller is dried through a drying apparatus.

<Description of Symbols for Main Parts of Drawings>

10: fabric coated with far-infrared radiation mineral

11 fabric fabric 12 mixture of mineral and natural adhesive

16: pressing roller 17: drying device

18: heat generating device

The present invention relates to a fabric coated with far-infrared radiation minerals, and more particularly, to a fabric in which the finely pulverized far-infrared radiation mineral is applied to a fabric fabric and then compressed and dried to maximize the far-field radiation efficiency.

In general, modern people have poor blood circulation and metabolism due to mental and psychological stress, and waste products accumulate in blood and cells, and thus are not free from various diseases. When far-infrared rays are radiated at wavelengths suitable for human body and organic materials, they are harmless to human body and organic materials and reach and absorb deep into the skin to activate biological activities.

To date, various products using such far infrared rays include bowls, bedding, clothing, and medical devices, and even far infrared rays are applied to walls and floors of apartments. However, until now, products using far-infrared radiation materials have had many limitations in terms of efficacy due to limitations in processing technology.

In order to solve the above problems, the present invention is to provide a fabric that can significantly increase the amount of far-infrared emission by heat-drying the finely pulverized far-infrared radioactive material to the fabric fabric.

Fabrics coated with the far-infrared radiation mineral of the present invention for achieving the above object, the fabric fabric; Far-infrared radiation minerals pulverized to fine size; And a natural adhesive for adhering and applying a far-infrared radiant material to the fabric fabric, wherein the pulverized far-infrared radiant material is adhered and applied by the natural adhesive to the fabric fabric, and is compressed and dried. .

In addition, the mineral material is pulverized to a size of 200 mesh (mesh) or less.

In addition, the mineral material may be composed of one of volcanic rock material, pojoran stone, ganban stone, jade, germanium, white clay, or a mixture of two or more of the minerals.

In addition, the fabric is coated with the far-infrared radiation mineral is characterized in that the pressing by the pressing means.

In addition, the fabric coated with the far-infrared radiation mineral material is dried by a drying device having a heat generating device.

Hereinafter, the configuration and operation of the present invention will be described in detail with reference to the accompanying drawings together with a manufacturing method. Like reference numerals in the drawings denote components that perform the same function.

1 is a plan view of a fabric coated with a far infrared ray emitting mineral according to a preferred embodiment of the present invention.

1 shows that a mixture 12 of far-infrared radiant minerals and a natural adhesive is applied to all of one side of a fabric fabric. Far-infrared radiation minerals can be applied to one or both sides of textile fabrics, as well as some or all of the two sides, such as bedding, care, cushions, pillows, curtains, electric mats, functional clothing, sporting goods, partitions, seat covers Or the like.

The far-infrared radiation mineral may be, for example, a mineral of one of materials emitting electromagnetic waves having a fundamental wavelength of 25 μm or more, such as volcanic rock, pozzoranite, elvan, jade, germanium, and clay, or a mixture of two or more thereof.

Particularly, volcanic rock is a kind of volcanic eruption produced by calcination of lava (magma) by high temperature and high pressure gas of 1600 ° C or more and is smaller than volcanic coal and larger than volcanic sand. Among volcanic rocks, volcanic rocks produced on Jeju Island (also called 'Song') are known to have excellent far-infrared emissivity, and Jeju's volcanic rocks (also called 'Song') are preferably used in the fabric of the present invention. Do.

Far-infrared rays, when applied to daily life, help to eliminate bacteria that cause various diseases, and expand the capillaries to help blood circulation and cell tissue generation. In addition, when far-infrared rays touch the water and protein molecules that make up the cells, the cells are shaken finely 2,000 times per minute to activate cell tissue, which is effective in preventing various adult diseases such as aging, promoting metabolism, and chronic fatigue. In addition, it promotes sweating, pain relief, heavy metal removal, sleep, deodorization, antibacterial, mold growth prevention, dehumidification, air purification and other effects.

Figure 2 is a process chart showing a process for producing a fabric coated with far-infrared radiation mineral according to the present invention.

As shown, the fabric coated with the far-infrared radiation mineral of the present invention, a washing step (S100) for removing foreign matter from the far-infrared radiation mineral, a grinding step (S102) for pulverizing the minerals from which the foreign matter is removed by a crushing device, pulverization Spraying and bonding process of mixing the natural adhesive to the far-infrared radiation mineral material and spraying it onto the fabric fabric (S104), the crimping process (S106) of pressing the fabric sprayed with the mineral material through a pressing device such as a pressing roller, and the compressed fabric It is completed through a drying step (S108) to heat-dry by the drying apparatus.

In the washing process (S100) to remove various dirt and soil buried in minerals such as volcanic rock. In the crushing process (S100) using a crusher to grind the minerals in the form of fine powder. A crusher may be used as the crusher. The particle size of the pulverized mineral material may be pulverized into various sizes depending on the purpose of the fabric, but is preferably pulverized to about 200 mesh or less, and is generally pulverized to about 200 to 300 mesh. Maintaining the pulverized particle size below 200 mesh increases the total surface area of the pulverized particles, thereby increasing the far-infrared emissivity and improving adhesion to the fabric through the adhesive.

The size of the particles to be pulverized may be variously pulverized to a size suitable for the surface properties of the fabric according to the purpose of the fabric.

3 is a schematic diagram showing a spraying and bonding process (S104) for spraying a mixture 12 of a far infrared ray emitting mineral and a natural adhesive onto the fabric fabric 11.

The fabric fabric 11 is hanged on the cotton fabric fabric hanger 14, and uniformly sprays the mixture 12 of the pulverized far-infrared radioactive material and the natural adhesive on one surface of the fabric fabric 11. After spraying, the coating surface is polished so that the mineral material can be evenly applied to the fabric fabric 11 at a predetermined thickness. The sprayed and bonded fabric is moved from A to A 'in the direction of the arrow by a moving device such as a roller. The application of far-infrared radiation minerals may be applied to not only one side of the fabric but also to both sides of the drawings, so that it is easy to process various products according to a specific use.

4 is a schematic diagram showing an example of the pressing process (S106) of inserting and passing the fabric 10 coated with the far-infrared radiation mineral material to the pressing roller 16 after the process of FIG. 3 is finished.

As shown, by passing the fabric 10 coated with the far-infrared radiation mineral through the compression roller 16, the mixture 12 of the mineral and the natural adhesive that emits the far-infrared rays on the fabric fabric 11 can be firmly compressed. Make sure The crimping process also keeps the surface of the applied fabric smooth. The process may be performed by a crimping device that performs the same function as well as the crimping roller 16 as a means for crimping.

The pressing process (S106) may be made continuously after the spraying and bonding process (S104), or may be performed after a slight drying process after the spraying and bonding process (S104).

5 is a schematic diagram showing an example of a drying step (S108) for drying the fabric 10 coated with the far-infrared radiation mineral material using the drying device 17.

The drying device is preferably a drying device provided with a heat generating device 18. That is, the drying method of the present invention is preferably a thermal drying method, because the surface is smoother due to the plastic action of the adhesive by heat during the drying process. In addition, the thermally elevated adhesive force makes the surface of the applied fabric more uniform.

The heat generating device 18 of the drying device 17 needs to generate heat of 100 degrees Celsius or more, and for efficient drying, it is preferable to generate heat of 150 degrees or more, and generates heat of 150 degrees to 160 degrees Celsius. It is more preferable to use a drying apparatus.

As the heat generating device of the drying device 17, a device for emitting a hot wire such as a hot wire device, a coil device, and a device for emitting hot air may be used. Any heat generating device that performs the same function may be used. Do.

The best embodiments have been disclosed in the drawings and specification above. Although specific terms have been used herein, they are used only for the purpose of describing the present invention and are not used to limit the scope of the present invention as defined in the meaning or the utility model registration claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be defined by the technical spirit of the attached utility model registration claims.

As described above, according to the fabric coated with the far-infrared radiation mineral material of the present invention, the harmful elements of the human body are removed by adhesively applying a mineral material using a natural adhesive, and also by applying a mineral powder in a fine powder form, pressing and drying the far infrared ray To maximize the radiation efficiency and to improve the surface properties of the fabric, to prevent the loss of far-infrared radiation from the fabric and to maintain the radiation effect even if used for a long time. On the other hand, by allowing the far-infrared ray to be applied to one part or both sides of the fabric, a variety of articles desired by the consumer, such as bedding, care, cushions, pillows, gutens, electric mats, functional clothing, sporting goods, partitions, seat covers, etc. It can be applied.

Therefore, when the fabric coated with the far-infrared radiation mineral of the present invention is used in various clothes and other household goods, it has excellent effect on preventing various adult diseases such as anti-aging, promoting metabolism and chronic fatigue by radiating a large amount of far-infrared rays which is beneficial to the human body. do.

Claims (5)

Woven fabrics; Far-infrared radiation minerals pulverized to fine size; And a natural adhesive for adhering and applying a far infrared ray radiant material to the fabric fabric, wherein the pulverized far infrared ray mineral material is adhered and dried in a state where the pulverized far infrared ray mineral material is adhered and applied by the natural adhesive to the fabric fabric. Fabric coated with far-infrared radiation minerals. The method of claim 1, The mineral is a fabric coated with far-infrared radiation mineral, characterized in that crushed to a size of 200 mesh or less.  The method of claim 1, The mineral is composed of volcanic rock, pozzoran stone, ganban stone, jade, germanium, clay, or a far-infrared radiation mineral coated fabric, characterized in that composed of two or more of the minerals. The method of claim 1, The fabric coated with the far-infrared radiation mineral is characterized in that the fabric is pressed by the pressing means.  The method of claim 1, The fabric coated with the far-infrared radiation mineral material is a fabric coated with the far-infrared radiation mineral material, characterized in that the drying by a drying device having a heat generating device.

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